The EFSUMB Guidelines and Recommendations for the Clinical Practice of Contrast-Enhanced Ultrasound (CEUS) in Non-Hepatic Applications: Update 2017 (Long Version)

• Abstract
• Zusammenfassung
• Introduction and general considerations
• Investigator training
• Terminology
• Equipment
• Terminology
• Safety
• Genitourinary
• Bladder
• Background
• Study procedure
• Image interpretation
• Characterization of mural lesions
• Bladder tumor staging
• Limitations
• Kidney
• Background
• Study procedure
• Renal Ischemia
• Renal Focal Lesions
• Differential diagnosis between solid renal masses and pseudotumors
• Characterization of complex cystic renal masses
• Characterization of indeterminate renal masses
• Renal infections
• Evaluation of solid renal lesions
• Vesicoureteral Reflux (VUR)
• Background
• Study procedure
• Diagnosis of vesicoureteral reflux
• Scrotum
• Background
• Study procedure
• Patterns of disease
• Torsion of the spermatic cord
• Segmental Infarction
• Trauma
• Inflammation
• Tumors and complex cysts
• Evaluation of solid testicular lesions
• Spontaneous intratesticular hematoma
• Prostate Cancer
• Background
• Study procedure
• Image interpretation and limitations
• Transplanted Kidney
• Adrenal Glands
• Obstetrics and Gynecology
• Obstetrics
• Gynecology
• Uterus
• Adnexa
• Pancreas
• Background
• Study Procedure
• Pancreatic Masses
• Adenocarcinoma
• Neuroendocrine tumors
• Mucin-producing cystic tumors
• Serous cystadenoma
• Pseudocysts
• Pancreatitis
• Pancreatic Transplant
• The Gastrointestinal Tract
• Background
• Study procedure
• Inflammatory Bowel Disease (IBD)
• Disease activity
• Distinguishing between fibrous and inflammatory strictures
• Abscesses
• Fistulas
• Intestinal Tumors
• Transplanted bowel
• Limitations
• Spleen
• Background
• Study procedure
• Indications and image interpretation
• Abnormal splenic size
• Lesion identification
• Ectopic splenic tissue
• Splenic infarction
• Characterization of focal splenic lesions (FSL)
• Cystic lesions
• Solid lesions
• Triage of patients with FSL
• Peripheral Vascular System and Aorta
• Background
• Study Procedures
• Carotid Artery
• Stenosis
• Follow-up after carotid stenting
• Dissection
• Complications after vascular intervention
• Plaque characterization
• Large vessel vasculitides
• Vertebral artery
• Abdominal aortic
• Aortic dissections
• Inflammatory Abdominal Aortic Aneurysm
• Endovascular Aortic Graft Endoleak
• Peripheral Vascular Disease
• Limitations
• Cerebral Vessels
• Background
• Study procedures
• Main intracerebral vessel imaging: interpretation and evaluation
• Vascular imaging
• Examination of the anterior circulation
• Examination of the posterior circulation
• Internal carotid artery stenosis
• Stroke patients
• Perfusion imaging
• Sono-thrombolysis
• Limitations
• Endoscopic
• Contrast-Enhanced Endoscopic US (CE-EUS)
• Background
• Study procedures
• Contrast-enhanced high mechanical index EUS
• Contrast-enhanced low mechanical index EUS
• Applications in pancreatic lesions
• Differential diagnosis of solid pancreatic lesions
• Staging in pancreatic ductal adenocarcinoma
• Characterization of cystic pancreatic lesions
• Applications in non-pancreatic lesions
• Gallbladder lesions
• Characterization of lymph nodes
• Gastrointestinal wall lesions
• Visceral vascular diseases
• Abdominal Trauma
• Background
• Study procedure
• Image interpretation of abdominal injuries
• Limitations
• Superficial Structures
• Thyroid
• Background
• Study procedure
• Thyroid nodule assessment
• Qualitative parameters
• Quantitative parameters
• Size
• Image interpretation
• Limitations
• Lymph Nodes
• Background
• Study procedure
• Image interpretation
• Salivary Glands
• Background
• Study procedure
• Image interpretation
• Qualitative approach
• Quantitative approach
• Breast
• Background
• Sentinel lymph nodes
• Inflammatory joint diseases
• Background
• Study procedure
• Image interpretation
• Arthritis and synovitis
• Differentiation between synovial pannus and fluid
• Bursae and tendon
• Therapeutic follow-up
• Gallbladder diseases
• Background
• Study Procedure
• Cholecystitis
• Tumors of the gallbladder wall
• Polypoid lesions
• Adenomyomatosis
• Adenocarcinoma of the wall
• Gallbladder metastasis
• Neurosurgery
• Background
• Study procedure
• Ultrasound equipment
• Examination technique
• Intraoperative applications
• Intraoperative evaluation of cerebral and spinal neoplastic lesions
• Neoplastic lesion identification
• Tumor characterization
• Tumor vascularization and surgical strategy
• Tumor resection control
• Intraoperative angio-sonography for cerebral and spinal vascular lesions
• Intraoperative contrast-enhanced ultrasound in traumatic brain surgery
• Limitations
• Interventional CEUS
• Background
• Avoiding biopsy of necrotic tissue
• Biopsy of poorly visualized or “invisible” lesions
• Further benefits from CEUS in interventional US
• Interstitial Ablation Therapy
• Background
• Kidney
• Study procedure
• Pretreatment evaluation
• Intraprocedural evaluation
• Follow-up
• Prostate
• Uterus
• Miscellaneous
• Intracavitary uses
• Background
• Study procedure
• Injection into physiological cavities
• Imaging of tubal patency
• Detection of peritoneal-pleural communication
• CEUS-guided percutaneous transhepatic cholangiography
• Intracavitary CEUS for guiding percutaneous nephrostomy
• Salivary glands
• Injection into non-physiological cavities
• CEUS for the imaging of fistula
• CEUS for the imaging of abscesses
• Free Tissue Transplants
• Background
• Study procedure
• Image Interpretation
• Preoperative planning
• Intraoperative imaging
• Postoperative monitoring
• Critical microvascularization
• Limitations
• Lung
• Background
• Study Procedure
• Clinical applications
• Pneumonia
• Pulmonary embolism
• Atelectasis
• Lung cancer
• Tumor Response Assessment
• Background
• Study procedure
• Bolus injection of a UCA with TIC analysis
• Intravenous infusion of a UCA with disruption-replenishment analysis
• Clinical application
• References

Abstract

The updated version of the EFSUMB guidelines on the application of non-hepatic contrast-enhanced ultrasound (CEUS) deals with the use of microbubble ultrasound contrast outside the liver in the many established and emerging applications.

Zusammenfassung

Die aktualisierte Version der EFSUMB-Leitlinien für die Anwendung von nicht-hepatischem kontrastverstärktem Ultraschall (CEUS) befasst sich mit der Verwendung von Mikrobläschen Ultraschall-Kontrastmitteln außerhalb der Leber in zahlreichen etablierten und neu entstehenden Einsatzbereichen.

Introduction and general considerations

Previous contrast-enhanced ultrasound (CEUS) documents from the European Federation of Societies for Ultrasound in Medicine and Biology (EFSUMB) encompassing hepatic [1] [2] [3] and non-hepatic applications [4] have been published with a statement on CEUS use in pediatric applications [5]. The present document reflects the current applications in non-hepatic CEUS and updates the previous EFSUMB guidelines published in 2012 [4]. The EFSUMB guidelines on CEUS are intended to inform clinical practice rather than to report on research projects. Thus, they are a digest of current findings formulated by a group of experts and are primarily based on surveys of the published peer-reviewed literature (so that abstracts and conference proceedings are excluded). Levels of evidence (LoE) and grade of recommendation (GoR) are formulated and presented to the reader to enable comprehensive understanding of the current clinical status of each CEUS application and based on the criteria used as in previous EFSUMB guidelines; levels of evidence and grades of recommendations are assigned according to the Oxford Centre for Evidence-based Medicine criteria (http://www.cebm.net/oxford-centre-evidence-based-medicine-levels-evidence-march-2009/). A consensus opinion was established by vote as follows: strong consensus (> 95 %), broad consensus (75 – 95 %), with approval, disapproval or abstaining from each participant. It is important to consider that nearly all applications contained in the current guidelines are “off-label” and are likely to remain so for some time. This does not present an impediment to the use of ultrasound contrast agents (UCAs) when applied outside licensing, a topic detailed in an accompanying article to previous guidelines [6]. Indeed the EFSUMB guidelines provide the evidence to incorporate UCAs into clinical practice despite being “off-label”, influencing regulatory authorities to sanction use as recently demonstrated by the Food and Drug Administration of the United States of America approval of UCAs in pediatric practice [7] [8] [9].

In general, CEUS is most useful where an abnormality can be displayed on B-mode ultrasound (US), and the better the quality of the B-mode imaging, the better the quality of the CEUS images. Importantly, CEUS is always used as an extension of conventional US (B-mode and color Doppler). Contrast studies should always be interpreted in the context of the overall clinical picture, other imaging and laboratory tests.

Overall, UCAs are mainly used as vascular agents following intravenous injection and they highlight the macro- and microvascular systems. However, they can also be instilled into body cavities, both normal and pathological. Instillation into the urinary bladder for vesicoureteral reflux is a classic example. Other examples include instillation into drainage catheters to define their position, the extent of the cavity and its continuity. Intradermal injection is used as a form of lymphangiography, with the UCA being spontaneously taken up into the lymphatics as an extension of their normal particle trapping activity. It is used to highlight sentinel lymph nodes, chiefly in breast cancer.

Investigator training

One of the central strategies of EFSUMB is to ensure high-quality US education and sustain excellent professional standards in CEUS training and practice. Previously, EFSUMB defined three levels of training requirements in a minimal training standards document [10], with specific reference to CEUS in Appendix 14 [11]. EFSUMB recommends that CEUS should be performed by operators that have achieved competence Level 1, as it has been recognized that the diagnostic performance of CEUS is dependent on the observer’s level of experience [12]. Accordingly, appropriate training and education is strongly advised for every investigator who performs CEUS examinations [13]. Furthermore, investigators should ensure that their US scanning machine is optimized for CEUS acquisition and the post-processing of data. The operator must gain sufficient knowledge of indications and contraindications of CEUS and training in ultrasound contrast agent administration and perform CEUS within the medico-legal framework of each individual country.

Terminology

Equipment

Ultrasound equipment based on contrast-specific ultrasound modes is needed for CEUS examinations, based on the separation between non-linear response induced by microbubble UCA oscillations and linear US signal reflected by tissues [4]. In order to decrease the non-linear harmonic US signals generated by the tissues themselves, a low acoustic pressure is generally used, based on a low mechanical index (MI). Generally, a low MI examination is typically considered below 0.3 in order to minimize microbubble disruption, but also reduce tissue harmonics and artifacts. Nevertheless, most of the US systems are able to perform CEUS examinations with lower values of the MI, even 0.08 or 0.05, and MI values vary with the different US manufacturers.

Terminology

Ultrasound contrast agents are used for enhancement of the US signal from flowing blood as they are limited to the blood vessels (blood pool UCA) [3] [4]. They were initially developed to enhance the Doppler US signals, based on higher MI techniques as opposed to the currently widely applied low MI specific modes. During high MI Doppler modes, injection of a UCA as a bolus produces “blooming”, due to flash or movement artifacts, which are not visible using specific harmonic imaging modes. The CEUS acronym has been introduced by EFSUMB and is generally accepted as the official term describing contrast enhanced ultrasonography techniques [3] [4]. Low MI techniques are preferred to the high MI techniques based on Doppler or power Doppler modes [14] [15] [16]. Most of the ultrasound systems have a dual split-screen display setting, with the low MI CEUS image shown alongside a conventional B-mode image. In the CEUS window, only a few signals from intensely reflective structures (e. g. calcifications or interfaces that produce large differences in acoustic impedance) should be seen, dependent on the settings of the MI and gain. Modes with a single screen display can also be used, where the CEUS image is displayed as a color overlay on the conventional B-mode image.

Each examined lesion should be described in terms of enhancement, taking into account the temporal behavior, degree of enhancement as compared with the surrounding tissues (non-enhanced, hypo-enhanced, iso-enhanced or hyper-enhanced), as well as the contrast distribution (homogeneity or heterogeneity). Two phases are described for most organs that have a single arterial blood supply (except the liver and lungs) [3] [4]:

• the arterial phase starts from around 10 – 20 seconds until around 35 – 40 seconds after contrast injection, showing a progressive degree of enhancement;

• the venous phase starts from around 30 to 45 seconds after contrast injection, showing a plateau and then a progressive decrease.

Safety

UCAs are administered safely in various applications with minimal risk to patients [4] [17] [18] [19] [20]. They are not excreted through the kidneys, and can be safely administered to patients with renal insufficiency with no risk of contrast-related nephropathy or nephrogenic systemic fibrosis. There is no need for blood tests prior to UCA injection, and there is no evidence of any effect on thyroid function, as UCAs do not contain iodine. UCAs have a very low rate of anaphylactoid reactions (1:7000 patients, 0.014 %) [17] [21] [22], [20] significantly lower than the rate with iodinated state-of-the–art CT agents (35 – 95:100 000 patients, 0.035 – 0.095 %) [23], comparable to the rate of severe anaphylactoid reactions associated with gadolinium-based contrast agents at 0.001 – 0.01 % [24]. Serious anaphylactoid reactions to UCAs are observed in approximately 1:10 000 exposures [4] [20].

Data from 75 completed studies (pooled data from 6307 patients) in North America, Europe, and Asia showed that the most frequent adverse events were headache (2.1 %), nausea (0.9 %), chest pain (0.8 %) and chest discomfort (0.5 %). All other adverse events occurred at a frequency of < 0.5 %. Most adverse events were mild and resolved spontaneously within a short time without sequelae. In most cases allergy-like events and hypotension occurred within a few minutes following the injection of the UCA. The overall reported rate of fatalities attributed to one UCA, SonoVue™ (Bracco, Milan), is low (14/2447 083 exposed patients; 0.0006 %) and compares favorably with the risk for fatal events reported for iodinated contrast agents (approximately 0.001 %). In all reported fatalities after use of a UCA, in both cardiac and non-cardiac cases, an underlying patient medical circumstance played a major role in the fatal outcome [25]. The intravesical administration of UCAs has been evaluated in a total of 7082 children described in 15 studies and in a European survey of 4131 children with 0.8 % reported adverse events, mostly related to bladder catheterization [26].

Contrast-enhanced ultrasound is also used off-label in the pediatric population [5], and in renal assessment [27] [28], and in numerous other documented areas [4]. The Food and Drug Administration (FDA) in the United States of America (USA) recently approved the use of Lumason™ (marketed as SonoVue™ Bracco, Milan, outside the USA) for pediatric liver imaging [7] [8], which is an important development in pediatric imaging. A significant reduction of ionizing radiation exposure can be achieved in many areas by using CEUS in pediatric patients [5] [29] [30].

Genitourinary

Bladder

Background

Noninvasive diagnostic imaging may play a role in urinary bladder tumors, but cannot replace cystoscopy and pathologic staging. The depth of wall invasion, the histological grade and the extension outside the bladder are main factors determining prognosis and therapeutic approach.

Study procedure

Optimal bladder filling (approximately 2/3 of the total bladder volume) is critical [31]. Insufficient filling prevents lesion detection, while excessive distension results in bladder wall thinning and reduced conspicuity of the wall layer, making it difficult to differentiate a superficial from an infiltrating lesion [32]. The layers of the bladder wall can be differentiated after UCA administration; the mucosa, and particularly the submucosal layer, exhibit early and intense enhancement that persists for 1 – 2 minutes [31], whereas the muscular layer has lesser and delayed enhancement.

Image interpretation

Characterization of mural lesions

CEUS improves the differential diagnosis of intraluminal lesions, allowing the detection of tumors, which are vascularized and enhance [33] [34], in contrast to non-enhancing hematomas [34]. In 35 patients with cystoscopy and biopsy as the reference standard, CEUS correctly assessed tumor presence or absence in 88 % of cases [35].

Bladder tumor staging

CEUS is superior to conventional B-mode US for identifying infiltration of the muscle layer [31], but magnetic resonance (MR) and computed tomography (CT) imaging are essential for the local staging of bladder tumors. The ability to predict tumor grading based on the pattern of CEUS enhancement remains under evaluation [32] [36].

Limitations

In patients with anatomical circumstances leading to poor urinary bladder visualization, CEUS cannot always provide the desired information. Similar to MR and CT imaging of bladder tumor detection, an important limitation of CEUS is the difficulty in identifying both small (< 1 cm) lesions and large flat, plaque-like tumors. Tumor position can affect the quality of CEUS depiction and the accuracy of staging. Tumors in the anterior portion of the bladder dome are sometimes difficult to visualize. Columnar hypertrophy of the bladder wall and prostatic hypertrophy can hide or mimic urothelial polypoid projections [31]. Benign tumors and focal cystitis are other uncommon conditions that present with focal bladder wall enhancement and can mimic a malignant lesion. CEUS is unable to provide a panoramic bladder view, as in the case of CT and MR imaging.

Kidney

Background

Ultrasound is the preferred imaging modality in patients with known or suspected renal disease for assessing renal size, detecting focal lesions and obstruction of the collecting system and for identifying vascular disorders but it cannot definitively distinguish between benign and malignant lesions. Doppler US helps to characterize renal blood flow, with limitations of attenuation, low sensitivity for very slow blood flow, and angle dependency.

Study procedure

The kidneys enhance rapidly and intensely after UCA administration, with potential to assess both the macro- and the microvasculature, the former immediately after UCA arrival. The arterial pedicle and main branches enhance first, followed rapidly by the segmental, interlobar, arcuate and interlobular arteries and then complete cortical enhancement. Medullary enhancement follows, with the outer medulla enhancing first, followed by gradual fill-in of the pyramids [37]. As UCAs are not excreted by the kidneys, there is no UCA in the renal collecting system. With CEUS only two enhancement phases occur: a cortical phase, 15 – 30 s after UCA administration with cortical enhancement seen, and a parenchymal phase, where both cortex enhancement and medulla enhancement occur 25s – 4mins after UCA administration. There is normally excellent depiction of renal perfusion throughout the kidney, superior to Doppler US. Contrast enhancement is reported to be less intense and fades earlier in patients with chronic renal disease [38] [39].

Renal Ischemia

Excellent diagnostic performance of CEUS in the detection of renal parenchymal ischemia, similar to that of CT imaging and superior to color Doppler US, has been reported. Infarcts appear as wedge-shaped non-enhancing areas within an otherwise enhanced kidney [40]. The excellent spatial resolution of CEUS allows clear differentiation between renal infarction and cortical necrosis, which appears as non-enhancing cortical areas with preserved hilar vascularity [37] [40] [41]. Differentiation between hypoperfused and non-perfused areas is clear following UCA administration; only infarcted areas completely lack contrast enhancement.

Renal Focal Lesions

Differential diagnosis between solid renal masses and pseudotumors

CEUS is used to differentiate between renal tumors and mimicking anatomical variations not characterized with B-mode and conventional Doppler US. Pseudotumors have the same enhancing characteristics as the surrounding parenchyma in all phases [37] [42], while the enhancement in renal tumors in the majority of cases differs from the surrounding parenchyma, with a difference in the degree or distribution of enhancement in at least one vascular phase. Renal tumors, however, do not show specific perfusion patterns. Virtually iso-enhancing tumors in all vascular phases are encountered in up to 5 % of solid renal lesions. A normal perfusion pattern on CEUS is a major criterion for the differential diagnosis between an iso-enhancing renal lesion and a pseudotumor. A pseudotumor demonstrates the vascular architecture of normal renal parenchyma, displayed during the early arterial phase, with branching from the hilum to the periphery without disruption of vessels or aberrant vessels.

Characterization of complex cystic renal masses

CEUS is appropriate in the Bosniak classification of renal cysts and is suggested to be superior to CT imaging for detecting additional septa, thickening of the wall or septa, and solid components [28] [43] [44] [45] [46]. CEUS allows the characterization of renal cystic lesions as benign or malignant with at least the same accuracy as CT imaging, but CT remains the reference method for staging patients with malignant cystic lesions. CEUS is well suited for the follow-up of non-surgical complex cystic lesions and has potential to replace CT. The absence of ionizing radiation is advantageous. The presence of lesion calcification hampers CEUS evaluation of complex cysts masses [28] [43] [44] [45] [46].

Characterization of indeterminate renal masses

In clinical practice, most abdominal CT imaging studies are not performed with a specific renal protocol to characterize renal lesions, frequently indeterminate renal lesions are identified. Follow-up US assessment should be comprehensive, including CEUS, to obviate an unnecessary correctly protocoled repeat CT study. B-mode US can determine the presence of a simple benign cyst. CEUS is more sensitive than CT for detecting blood flow in hypovascularized lesions and can be used to distinguish between complex cysts and solid lesions, particularly those which remain unresolved after CT imaging, B-mode and color Doppler US [28] [47].

Renal infections

The diagnosis of acute uncomplicated pyelonephritis is based on clinical examination and laboratory findings. Conventional B-mode US is used to exclude urinary obstruction and renal calculi. Additional investigations should be considered if the patient remains febrile following 72 hours of treatment. In these patients, with complicated pyelonephritis, CEUS is effective in identifying inflammatory involvement, characterized by round or wedge-shaped hypovascular parenchymal areas, most conspicuous during the parenchymal late phase. An abscess is manifested as a non-enhancing area, with or without rim or septal enhancement, solitary or within areas of pyelonephritis. CEUS can be used to monitor the resolution of abscesses, which can be prolonged, even with clinical improvement [48].

Evaluation of solid renal lesions

A number of studies have attempted to evaluate the differentiation of renal tumors, particularly angiomyolipoma and renal cell carcinoma, by means of different features of time-intensity curves after UCA administration. The majority of angiomyolipomas are reliably differentiated with CT or MR imaging and although results are promising with CEUS, overlap with both qualitative and quantitative analyses with different tumors is evident. In expert hands, CEUS may help identify renal vein invasion by cancer, as the arterial vascularization of the thrombus may differentiate bland thrombus (non-enhancing) from tumor invasion (enhancing thrombus) [49].

Vesicoureteral Reflux (VUR)

Background

Conventional voiding cystourethrography remains the gold standard for the detection of VUR, notwithstanding ionizing radiation concerns, despite contrast-enhanced voiding urosonography (ceVUS) being the superior option. Many early comparative studies between ceVUS and cystourethrography were obtained with Levovist™ (Schering AG, Berlin), now no longer available UCA. SonoVue™ (Bracco SpA, Milan), recently licensed for this purpose, performs comparatively well, and has a favorable safety profile in children [50] with high diagnostic performance for the detection of reflux and for assessment of the urethra [51] [52] [53] [54] [55] [56] [57] [58] [59].

Study procedure

The basic steps of ceVUS are [50]:

• B-mode US evaluation of the kidneys and bladder

• Intravesical administration of UCA diluted in normal sterile saline

• Repeated imaging of the bladder and kidneys with CEUS during and after bladder filling and while voiding

• During voiding urethrosonography (transpubic and/or transperineal) may be added [60].

UCA can be administered via a transurethral bladder catheter or via suprapubic puncture (0.1 – 0.5 mL SonoVue™ in 500 mL 0.9 % saline), by slow instillation during CEUS monitoring, until adequate enhancement of the bladder content is achieved; dose adjustment with excessive shadowing or insufficient signal. A full bladder is necessary for suprapubic puncture.

Diagnosis of vesicoureteral reflux

Reflux is diagnosed when the UCA appears in one or both ureters and/or the pelvicalyceal system. Vesicoureteral reflux is graded I–V depending on severity, analogous to the international reflux grading system of voiding cystourethrography [61]. US imaging is continued during and after voiding with the child supine, prone, sitting, or standing, always imaging the kidneys and bladder alternately as the position allows [51].

Contrast-enhanced voiding urosonography has a higher rate of vesicoureteral reflux detection compared to voiding cystourethrography, as ceVUS is more sensitive to the detection of small amounts of refluxed UCA [56] [57] [62]. Moreover, ceVUS imaging is continuous, while fluoroscopy is intermittent with cystourethrography, allowing better detection of intermittent reflux on CEUS. Notably, reflux episodes missed on voiding cystourethrography but detected with ceVUS tend to be higher grade, and of greater clinical concern [56] [57] [62]. The ability to detect clinically important reflux and the lack of ionizing radiation support the use of ceVUS for initial diagnostic and follow-up evaluation of VUR in boys and girls, as well as screening of high-risk patients. A limitation of ceVUS is the inability to image the entire urinary tract simultaneously. Furthermore, ceVUS is not recommended as the primary imaging modality for reflux, if the bladder or one of the kidneys is not depicted on US, for specific urethral and/or bladder functional and anatomical evaluation and when imaging is required for detailed anatomical assessment, e. g. in the evaluation of recto-urethral fistulas in neonates with anorectal malformation [52]. The urethra may also be evaluated effectively both in girls and in boys. Although evidence is limited, the technique is promising [55] [60] [62] [63] [64].

Contrast-enhanced voiding urosonography has been used for vesicoureteral reflux in renal transplant recipients with recurrent urinary tract infections [65] [66] [67], both in adults and children. In 23 adult renal transplant recipients, ceVUS was compared with radionuclide cystography [65], in 37 adult patients ceVUS was compared with conventional voiding cystourethrography [66] and in 27 patients (8 children or adolescents, 19 adults) cycling ceVUS (i. e., obtained by filling the bladder and having the patient void around the urinary bladder catheter two times) was compared with ceVUS in the first cycle [67]. Results indicated that ceVUS was highly effective in detecting vesicoureteral reflux in adult renal transplant recipients. Compared to techniques involving exposure to ionizing radiation, the sensitivity and specificity ranged between 75 % – 93 % and 71 % – 95 %, respectively [66]. Compared with the first cycle, cyclic ceVUS did not improve detection sensitivity for vesicoureteral reflux, but revealed higher grades of reflux [67].

Scrotum

Background

Despite US being the imaging modality of choice for examination of the scrotum, findings may be equivocal and misinterpretation can result in an unnecessary orchiectomy. A challenge is the unequivocal differentiation between hypovascular and avascular lesions, presuming that an avascular lesion implies benign disease, which may be impossible on color Doppler US. CEUS provides a practical solution by increasing the confidence of the interpretation of lesion vascularity and of scrotal and cord vessels, allowing for appropriate clinical management.

Study procedure

A B-mode and color Doppler US examination of the lesion with linear high-frequency transducers should be performed to relate to the subsequent CEUS findings. A higher UCA concentration is required to examine the scrotal contents; typically 4.8 mL of SonoVue™ (Bracco SpA, Milan) [68]. The arterial phase in CEUS is the most important aspect of the examination. The testis and epididymis enhance rapidly but the arrival time varies between individuals. The arteries enhance first, followed within seconds by complete parenchymal enhancement. The scrotal wall tends to enhance to a lesser degree than the contents. There is no accumulation of UCA in the parenchyma of the testis and the enhancement declines over a variable period of time such that there is minimal residual enhancement by three minutes.

Patterns of disease

Torsion of the spermatic cord

The sensitivity of color Doppler US with current equipment for the identification and diagnosis of spermatic cord testicular torsion is adequate, even in the small volume testes of children [69]. In a small series of men with spermatic cord torsion, CEUS confirmed the absence of vascularization, but failed to add any clinically significant information to unenhanced color Doppler US [70]. There is no data to recommend the use of CEUS in spermatic cord torsion, although the absence of global vascularity can be clearly depicted [71].

Segmental Infarction

The appearance of acute segmental testicular infarction on conventional B-mode and color Doppler US is variable [72] [73]. Often the benign nature of the lesion is established by its wedge shape with markedly diminished or absent color Doppler flow [72]. The main concern is the differentiation of a segmental infarction with a rounded configuration from a poorly vascularized tumor [74]. CEUS improves the characterization of segmental infarction by demonstrating one or more ischemic parenchymal lobules separated by normal testicular vessels [75] [76]. Subacute segmental infarction characteristically exhibits a perilesional rim of enhancement, which diminishes over time and is eventually lost with changes in lesion shape and shrinkage [75] [77].

Trauma

Conventional B-mode and color Doppler assessment of the testis in trauma is well established but underestimates the extent of injury [78]. Besides integrity or interruption of the tunica albuginea, the most important information for the surgeon is the extent of viable testicular tissue, an evaluation which is often difficult with conventional Doppler US because the injured testis is often hypovascular even in viable regions, as a consequence of testicular edema compromising vascular flow. CEUS allows delineation between the non-enhancing devascularized tissue and the enhancing viable parenchyma, enabling organ-sparing treatment. Moreover, CEUS offers a clear delineation of fracture lines and intratesticular hematomas [79] [80] [81] [82].

Inflammation

Epididymo-orchitis is a clinical diagnosis and is usually easily confirmed on color Doppler US. Abscess formation is relatively common in cases of severe epididymo-orchitis, whereas venous infarction is exceedingly rare, thought to be a consequence of local swelling occluding the venous drainage of portions of the testis or of the entire testis [71] [76]. CEUS may be used in selected cases of severe epididymo-orchitis. It allows unequivocal assessment of the presence or absence of vascular supply within focal testicular lesions. However, since both infarction and intratesticular abscess lack internal vessels, absolute differentiation remains difficult. CEUS may be able to determine the development of an abscess at an earlier stage, or the complete extent of a large abscess, and allow for prompt treatment [70] [71] [76] [83].

Tumors and complex cysts

The current understanding is that testicular tumors with a diameter of less than 1.5 cm may not show flow on color Doppler US and thus may be misinterpreted as a benign lesion, the purported hallmark of malignancy being an increase in vascularity [84]. Simple testicular cysts are usually benign, but any wall irregularity or echogenic debris may be suggestive of a (rare) cystic testicular tumor [85] [86]. CEUS is able to confirm the absence of vascularity in benign complex cysts and epidermoid cysts [87] [88]. It is thought that virtually all testicular tumors display vascularization on CEUS, with the exception of any cystic component and regions of necrosis. Very rare exceptions may be represented by extensively necrotic lesions, and by the so-called “burned out” testicular tumor [89] [90] [91].

Evaluation of solid testicular lesions

Several investigators have discussed the possibility of differentiating testicular tumors with CEUS, particularly between a malignant seminoma and a benign Leydig cell tumor. Using time-intensity curves, evaluating the wash-in and washout curves may help distinguish malignant from benign tumors, with a prolonged washout observed in Leydig cell tumors [90], and reported rapid wash-in and raised enhancement for Leydig cell tumors in comparison seminoma [92] [93]. Although these results are promising, both qualitative and quantitative CEUS analyses overlap between different histological types. Quantification of CEUS of testicular tumors remains a research tool. There is limited use of CEUS in intrascrotal extratesticular focal lesions, with no evidence regarding the usefulness for the differentiation of solid lesions [83].

Spontaneous intratesticular hematoma

Testicular hematoma can rarely present with acute scrotal pain in a patient with no history of trauma. US demonstrates an intratesticular mass suggesting malignancy, but the lack of enhancement is a good marker for the absence of vascularity and for a benign lesion, leading to a presumptive diagnosis and conservative management [82] [94] [95].

Prostate Cancer

Background

Conventional B-mode and Doppler transrectal US imaging have a limited role in the detection of prostate cancer because of poor sensitivity and specificity (approximately 50 – 60 %) and B-mode US is only used to guide prostate biopsies. There is a correlation between angiogenesis, as represented by microvascular density, and the presence of prostate cancer, its stage and survival [96]. Therefore, attempts have been made with contrast-enhanced color Doppler US to improve the detection and diagnosis of prostate cancer, with a reported increase in the detection rate of targeted biopsies of nearly 50 % compared to systematic biopsies [97]. Low MI transrectal CEUS became available during the last decade when contrast-specific modalities were also implemented on endocavitary transducers, with further studies forthcoming [98] [99] [100].

Study procedure

Diagnostic CEUS is performed using transrectal US and typically a bolus of 2.4 mL of SonoVue™ (Bracco SpA, Milan) is administered to image particularly the inflow of UCA in a single plane. The most useful characteristics for an area suspicious for prostate cancer are a rapid inflow and/or an increased maximal enhancement compared to the surrounding tissue. Multiple UCA injections (typically four) are needed to image several planes [101]. CEUS has been used for follow-up of ablative treatments, with either a bolus injection or an infusion of UCA used to visualize perfusion defects resulting from the ablative therapy [102].

Image interpretation and limitations

Preliminary CEUS results appear to confirm the findings of contrast-enhanced Doppler US, with the lack of specificity of enhancing areas and of any other pattern suggesting cancer [98] [99] [100]. The evidence for the use of CEUS in the prostate remains limited and the role of CEUS in prostate cancer should still be considered a research subject. New improvements and new techniques are becoming available with the potential to increase the role of CEUS in prostate cancer detection and diagnosis. 4 D contrast-enhanced transrectal US imaging has now been introduced [103] and objective quantification techniques are being developed [103] [104]. The first use of targeted UCA in humans was reported for prostate cancer; these VEGF-R2 targeted microbubbles were tested in a phase 0 trial in 24 patients (https://www.clinicaltrials.gov/ct2/show/NCT01253213?term=BR55&rank=2?). The combination of CEUS and other US modalities such as elastography, in multi-parametric US could pave the way to a future clinically significant role for CEUS in prostate cancer detection and diagnosis [105].

Transplanted Kidney

All of the applications of CEUS in native kidneys also apply to renal transplants. B-mode and Doppler US are the modalities of choice for imaging transplanted kidneys but are limited in the assessment of microcirculation and the characterization of focal masses, inflammatory changes and complex cysts [27] [106] [107]. CEUS has a role in assessing vascular complications including arterial and venous thrombosis [106] [108] [109]. CEUS can image the microcirculation which is essential for assessing acute and chronic graft dysfunction, and is sensitive in the diagnosis of infarction, seen as a defect in all phases [110] [111]. The defect on CEUS is smaller than on Doppler US, a manifestation of the imaging of smaller vessels on CEUS. Cortical infarction and ischemia (absent flow compared to hypoperfusion respectively) can be reliably differentiated on CEUS, a feature not possible by conventional Doppler US [112]. Different quantitative functional data have been assessed on time-intensity curves, all related to impaired parenchymal perfusion (e. g. longer time to peak, lower wash-in slopes, longer mean-transit time) and associated with a worse prognosis of graft function and survival [113] [114] [115] [116]. Although these preliminary results are promising, further studies are needed to assess whether the detection of hemodynamic changes in renal grafts affects the management of patients with poorly functioning transplants. Consequently the quantification of CEUS is still considered a research field in transplant assessment.

Adrenal Glands

Conventional US is able to detect adrenal gland tumors [117], usually readily on the right side, but characterization is more difficult [118]. Size, irregular contours, inhomogeneity, loss of normal adrenal gland anatomy, and infiltration into adjacent organs, or the diaphragm, and vessels are criteria for malignancy. Malignant adrenal tumors may infiltrate and occlude the adrenal vein; the vascularity of a tumor thrombus may be demonstrated on CEUS. No CEUS criteria can reliably differentiate between benign and malignant adrenal gland tumors, with conflicting reports [119] [120] [121]. Dynamic CEUS using time-intensity curve analysis has been deployed in the investigation of adrenal gland tumors without clear differentiation [120] [122]. CEUS may demonstrate characteristic hypervascularity of some adrenal gland tumors, e. g., pheochromocytoma, which typically also have necrotic regions with no contrast enhancement [121] [123] [124].

Obstetrics and Gynecology

Obstetrics

The use of UCA in obstetrics is not indicated as there has been limited research related to the uncertainty of a possible underlying harmful effect. No recent human or animal studies have been performed. It is unknown whether the UCA passes through the placenta, though this seems unlikely as previously suggested [125] [126]. CEUS to assess a pregnant mother should be balanced against the risk of other imaging modalities.

Gynecology

Uterus

Both endometrial and cervical tumors have been assessed with CEUS [127] [128]. Perfusion differences between endometrial polyps and cancer have been documented [129], and CEUS during uterine artery embolization to treat leiomyomas might be useful [130] [131]. Currently there is some benefit to the CEUS diagnosis of endometrial carcinoma [127]. No prospective trials have confirmed the value of CEUS for assessing uterine tumors and there is no proven clinical indication for CEUS use in the examination of the endometrium or the myometrium.

Adnexa

Differentiation of benign from malignant adnexal masses was attempted by visual assessment of UCA distribution and by quantification of enhanced Doppler signals, but, despite some difference in average values for some variables, no feature with sufficient clinical potential was obtained [132]. By using CEUS, it was demonstrated that adnexal masses without internal enhancement are invariably benign [133], but the presence of enhancement is not a specific sign of malignancy [128]. CEUS does not greatly improve the accuracy of color Doppler US for the diagnosis of malignancy in adnexal masses [134]. A multicenter study on the diagnosis of malignancy in adnexal masses, including quantitative CEUS features, confirmed that CEUS was not superior to conventional color Doppler US [135]. Although CEUS findings differed between benign and malignant ovarian masses, there was substantial overlap between benign and borderline tumors, although CEUS was able to differentiate invasive malignancies from other tumors [135].

Pancreas

Background

CEUS is not indicated for the detection of focal solid or cystic pancreatic lesions, but CEUS improves the characterization of lesions seen on US [136] [137] [138] [139] [140] [141] [142].

Study Procedure

CEUS is superior to Doppler US techniques for the visualization of intrapancreatic vessels [142]. Enhancement begins immediately after aortic enhancement, with an arterial phase (10 to 30 s), a venous phase (30 to approximately 120 s) [2] [4]. With a pancreatic mass, the CEUS examination also aims to characterize and confirm peripancreatic vascular associations [137] [138] [139] [143] [144]. The late venous phase begins about 120 seconds after the contrast injection and lasts for about 4 minutes. A late phase liver evaluation may identify possible metastatic lesions [3].

Pancreatic Masses

The enhancement pattern of focal pancreatic lesions is compared with the adjacent pancreatic tissue. The field of view should include both. This is mandatory with an isovascular mass but not essential with a hypovascular (hypoenhanced with few internal microbubbles) or hypervascular (hyperenhanced) mass [137]. CEUS provides clear distinction between vascularized solid lesions and cysts and provides information on lesions indeterminate on CT, and may aid targeting areas following a first negative biopsy.

Adenocarcinoma

Ductal adenocarcinoma, the most common primary malignancy, is typically hypo-enhancing in all phases, because of the desmoplastic reaction with low vascular density that is present in 90 % of cases [141] [145] [146] [147] [148] [149] [150]. Lesion size, margins and the relationship with peripancreatic vessels are better visualized with CEUS [143] [144]. However, for assessing resectability, B-mode and color Doppler US are also adequate [137] [144]. CEUS is essential for lesion characterization [140] [151] and accurate liver staging [3] [137] [152]. CEUS can help with US-guided pancreatic biopsy [153] [154]. Changes in pancreatic tumor vascularization during chemotherapy have been documented with CEUS [155] [156].

Neuroendocrine tumors

Neuroendocrine tumors typically present as hyper-enhancing lesions in the arterial phase of CEUS examinations, owing to their abundant arterialization, often not seen on color Doppler US [138] [157]. Necrotic avascular areas result in inhomogeneous enhancement in larger tumors [157] [158]. Based on the ENETs Consensus Guidelines, CEUS is reported as an imaging method for the diagnosis of neuroendocrine neoplasms [159].

Mucin-producing cystic tumors

CEUS improves the differentiation between pseudocysts and cystic tumors of the pancreas by accurately demonstrating vascularization of lesion septa or nodularity [139] [160] [161]. Mucinous cystadenoma is potentially malignant (may transform into cystadenocarcinoma), and it is usually depicted as an unilocular round cystic lesion, with particulate content, irregular thick walls, internal septa and parietal nodules which enhance on CEUS [139] [148] [160] [161] [162] [163] [164]. Intraductal papillary mucinous neoplasms (IPMN) are divided into main duct and side branch duct types. CEUS is helpful for differentiating between perfused (nodules) and non-perfused (mucin plugs) areas [137] [163]. CEUS can be employed in the follow-up of borderline cystic lesions of the pancreas, if well visualized on US, in order to reduce the use of MR imaging [165].

Serous cystadenoma

Serous cystadenoma is a benign cystic lesion, typically with a lobulated microcystic appearance with thin and centrally oriented septa, which are vascularized on CEUS [139]. When the cysts are minute, microcystic serous cystadenomas may mimic a solid lesion, both on conventional US and CEUS, being hyperenhanced on CEUS [166]. Definitive differential diagnosis with respect to IPMN side branch duct types is not possible on CEUS. Exclusion of the presence of communication between the cystic lesion and the main pancreatic duct is required.

Pseudocysts

Pseudocysts typically contain non-vascularized debris, typically found in the early stages. Pseudocysts do not enhance at any phase with CEUS, even when heterogeneous on B-mode US [148] [162]. The reported sensitivity and specificity of CEUS in characterizing pseudocysts is up to 100 % [160].

Pancreatitis

With acute pancreatitis, CEUS may delineate necrotic areas, which do not enhance [167] [168]. If the pancreatic region is clearly visible on US, CEUS can be used in the follow-up of acute pancreatitis following CT staging, to reduce further CT examinations [167]. Good accuracy of CEUS for detecting necrotic lesions in acute pancreatitis (97.4 %) has been reported [168]. Significant correlation between CEUS and CT was found for the pancreatitis CT severity index, extent of necrosis and Balthazar grade, and as a predictor of severity in an episode of acute pancreatitis [167]. CEUS can be used as a follow-up imaging method in patients with initial CT staging at admission [167]. Focal mass-forming pancreatitis and autoimmune pancreatitis have been reported to have similar enhancement to that of the normal pancreatic parenchyma [145] and may be useful for the differentiation of pancreatic cancer [140] [169] [170].

Pancreatic Transplant

As with renal allografts, US is the modality of choice for imaging pancreatic transplants. CEUS can add extra value and diagnostic confidence when assessing graft perfusion and vascular complications such as arterial and venous thrombosis, particularly in complicated situations. CEUS can image the microcirculation to allow evaluation of viability and may provide prognostic information [171] [172] [173]. Early quantitative functional data shows promise in the diagnosis and management of rejection and represents a research field in transplant assessment [146] [174].

The Gastrointestinal Tract

Background

Ultrasound imaging of the gastrointestinal (GI) tract using ≥ 7.5 MHz transducers usually reveals 5 wall layers and can identify a thickened bowel wall and focal lesions [175]. The imaging of the bowel wall with CEUS requires a higher UCA dose, typically 4.8 mL of SonoVue™, a consequence of fewer microbubbles of the appropriate size to resonate at higher frequencies [176]. The time of arrival of the UCA in the intestinal capillaries is usually 10 – 20 s after injection, predominantly in the submucosal layer, with maximum concentration (peak intensity) reached after 30 – 40 s. The arterial phase (0 – 30 s) is followed by a venous phase that lasts from 30 – 120 s [177].

Study procedure

The bowel should be examined in B-mode and Doppler US modes to detect the distribution of the relevant pathology, allowing the area of interest to be targeted for CEUS examination. A difference in perfusion between healthy and diseased bowel can be recognized by CEUS [178]. CEUS examination allows arterial and venous phases to be examined for two minutes and the possibility for a late phase liver examination for metastasis, if relevant.

Inflammatory Bowel Disease (IBD)

CEUS enables quantification of bowel wall vascularity in patients with Crohn’s disease [179] [180] and is used to evaluate adult [181] [182] [183] and pediatric IBD patients [184]. CEUS correlates well with MR imaging of intestinal wall enhancement [185] [186] [187].

Disease activity

CEUS can add to B-mode and Doppler US in the evaluation of disease activity in IBD [188]. CEUS performs more reliably than power Doppler in estimating disease activity in Crohn’s [180] [189]. Enhancement in different wall layers can be evaluated and quantified in Crohn’s disease and correlates to a clinical activity index (CDAI) with good sensitivity and specificity [190] [191]. In ulcerative colitis, CEUS parameters correlate well with histological markers of inflammation [192]. Quantitative measurements of bowel enhancement obtained by CEUS also correlate with a severity grade determined at endoscopy [193]. Furthermore, histological markers of inflammation correlate well with CEUS perfusion [192] [194] [195]. Moreover, US evaluation of the changes of bowel wall enhancement during anti-inflammatory therapy may be useful for the clinical monitoring of Crohn’s disease activity [195] [196] [197] [198]. CEUS can also be used to assess postoperative recurrence of Crohn’s disease [199]. Two meta-analyses concluded that CEUS in the assessment of IBD activity is accurate and a highly sensitive and specific method [200] [201].

Distinguishing between fibrous and inflammatory strictures

In patients with a stricture of the bowel and resultant bowel obstruction, it is important to determine if there is active inflammation at the site of stricture or if this segment is fibrotic. Preliminary studies indicate that the use of UCA appears to be effective in the recognition of predominantly cicatricial stenosis in patients with Crohn’s disease [202], although data is conflicting [203]. Using CEUS, the active inflammatory components will enhance, whereas the fibrotic stricture will not [21]. Absolute values for blood volume, flow and mean transit time of the bowel confirm that it is possible to distinguish between fibrous and inflammatory strictures in Crohn’s disease [204].

Abscesses

Distinguishing abscesses from inflammatory infiltrates is an important clinical task in the management of Crohn’s disease [205]. If areas of a significant size close to an affected bowel loop are completely devoid of UCA signals, this lesion represents an avascular abscess rather than inflammatory infiltrates [206] [207].

Fistulas

By injecting a UCA mixed with saline into one of the orifices of a fistula, it is possible to improve visualization of fistula routes in Crohn’s disease, defining endocavitary and intraluminary locations [208] [209] [210]. Fistulas from blood vessels to intestines can also be detected using conventional intravenous CEUS [211].

Intestinal Tumors

US is not the imaging modality of choice for detecting intestinal polyps or tumors. Tumor vascularity can be evaluated by CEUS [212] and contrast enhancement of rectal cancer has been shown to correlate with histological vessel density [213]. Neuroendocrine tumors and gastrointestinal stromal tumors (GIST) of the stomach and small bowel are highly vascularized and CEUS can be applied for perfusion analysis and planning of US-guided biopsies to avoid punctures of necrotic tumor parts [214]. Furthermore, the hypervascular (95 %) metastasis from neuroendocrine tumors to lymph nodes and the liver can be detected and characterized by CEUS [215].

Transplanted bowel

CEUS allows the detection of hypoperfusion of a bowel transplant graft [216]. As in other bowel diseases, CEUS can be used to evaluate the bowel wall perfusion as well as the patency of visceral vessels with the advantage of bedside examination. CEUS can also diagnose other organ complications after bowel transplantation, e. g. pancreatitis, when other imaging techniques cannot be performed. CEUS also allows diagnosis and monitoring of treatment response of intestinal acute graft versus host disease (I-aGVHD) after allografting. The detection of transmural penetration of the UCA into the bowel lumen indicates I-aGVHD [217] [218].

Limitations

It is difficult to visualize all bowel segments using transabdominal US. Intestinal peristalsis and luminal air will impair image quality and reduce the repeatability of the quantitative measurement of bowel enhancement patterns. Improved detection of intestinal inflammation may be enabled with targeted specific ligands attached to the UCA [219]. However, more studies are needed to establish the exact role of CEUS in the imaging of gastrointestinal pathology, and when performing multicenter studies, it is mandatory to standardize acquisition and software for quantification [220].

Spleen

Background

Splenic abnormalities are uncommon [221] and frequently difficult to detect and characterize with conventional US. The spleen is ideally suited for CEUS due to its superficial location, homogeneous parenchyma, high vascularity, small size and long-lasting enhancement profile [222]. CEUS is a well-established technique for increasing diagnostic confidence and accuracy in splenic US.

Study procedure

Although UCAs remain entirely intravascular, they are sequestrated by the spleen [223], resulting in persistent late phase enhancement. Enhancement is inhomogeneous in the arterial phase (“zebra striped” pattern, similar to contrast-enhanced CT and MR imaging) [224] [225] but becomes homogeneous within 60 seconds and usually persists for longer than 5 minutes. The arterial (10 – 35 s) and late parenchymal phases (3 – 5 min) are most valuable diagnostically. Scanning should be continuous during the arterial phase but then intermittent to avoid UCA destruction [226]. Enhancement of focal lesions is compared to adjacent (enhanced) splenic parenchyma. Deeper lesions can be obscured if a large volume of UCA is administered [222] [227] [228] [229]. 1.2 – 2.4 mL of SonoVue™ is usually the optimal dose.

Indications and image interpretation

Abnormal splenic size

CEUS is not helpful in identifying the etiology of diffuse splenomegaly [224] [227]. Reduced or absent enhancement in a small spleen may indicate functional hypo/asplenia [230].

Lesion identification

Where the splenic parenchyma is inhomogeneous on B-mode US, the addition of CEUS will frequently demonstrate focal lesions [221] [222] [224] [230] [231].

Ectopic splenic tissue

Ectopic splenic tissue will enhance with the same pattern as the normal spleen. Late parenchymal enhancement will differentiate splenunculi [227] [230] [232] [233] and splenosis [234] from pathological masses.

Splenic infarction

Infarction may be difficult to detect on conventional US, particularly when isoechoic in the acute stage. CEUS improves detection and characterization by demonstrating avascular, usually wedge-shaped, lesions [222] [224] [225] [230] [231] [235] [236]. Enhancement will be absent in patients with total splenic infarction [230]. CEUS can identify asymptomatic splenic infarction in patients with pancreatitis [237] and infective endocarditis [238].

Characterization of focal splenic lesions (FSL)

Cystic lesions

CEUS can be used in selected cases to show that complex cysts are avascular and therefore likely to be benign [225] [236]. Rim or septal enhancement may be a feature of splenic abscess formation [230] [236].

Solid lesions

B-mode and color Doppler US have low accuracy for the diagnosis of solid lesions. Small echogenic lesions are usually, but not always, benign, while echo-poor lesions are more likely to be malignant [222]. Correlation with the clinical history and laboratory tests is essential [221] [239] [240] [241] [242]. Benign vascular tumors (BVT: hemangioma and hamartoma) are the most common benign lesions and secondary tumors (lymphoma and metastases) are the most common malignant lesions. No enhancement (in any phase) or persistent late phase enhancement is characteristic of benign lesions. Late phase washout is a feature of malignant lesions, but less pronounced washout is also seen in many benign lesions [221] [228] [229] [235] [236] [241]. Arterial phase hyper-/isoenhancement is an independent predictor of a BVT, more commonly seen in hemangiomas with an atypical appearance on conventional US [241] [242]. Nodular peripheral enhancement with progressive centripetal filling is unusual in splenic hemangiomas [222] [229] [241] [243]. Intralesional vessels, heterogeneous enhancement, necrotic regions and a dotted enhancement pattern favor a diagnosis of malignancy [227] [229] [244] [245].

Triage of patients with FSL

Lesions showing low-level arterial enhancement and progressive late-phase contrast washout usually require further imaging or biopsy, particularly in high-risk groups. FSL with benign enhancement characteristics will usually be suitable for interval imaging [229] [239] [242] [243].

Peripheral Vascular System and Aorta

Background

The extracerebral vascular systems with indications for CEUS include the cervical carotid artery and the abdominal aorta, with less emphasis on peripheral arterial disease. Conventional US techniques are limited with respect to the demonstration of slow flow, especially in small vessels such as the vasa vasorum or collaterals and flow in critical stenosis, and the addition of a UCA may be useful.

Study Procedures

CEUS of the carotid and peripheral arteries is carried out with linear transducers (5 – 10 MHz) and the abdominal aorta is visualized with convex transducers (2.5 – 9 MHz). For diagnostic views of the vessels, 1.0 to 2.4 mL of SonoVue™ is intravenously administered as a bolus injection, followed by 10 mL of 0.9 % normal saline solution.

Carotid Artery

Stenosis

Color and spectral Doppler US is the established imaging modality for suspected carotid artery disease. CEUS improves the sensitivity of Doppler US and can distinguish occlusion from tight subocclusive stenosis, comparable to contrast-enhanced CT angiography [246] [247]. CEUS improves the delineation of the endovascular border, characterizing the geometry of pre-stenotic, intra-stenotic and post-stenotic segments without the aliasing and blooming artifacts or angle dependence issues of Doppler US [248]. CEUS does not provide flow information [249].

Follow-up after carotid stenting

CEUS is a reliable method for evaluating re-stenosis after internal carotid artery stenting [250]. CEUS has fewer intrastenotic flow artifacts compared to Doppler US, resulting in improved visualization and depiction of the complete length and morphology of the stenosis [250].

Dissection

CEUS has been used to identify carotid dissection [251]. MR imaging remains the reference standard in the diagnosis of cervical vessel dissections. When it is contraindicated, the diagnostic accuracy of US examinations can be improved by the use of CEUS [248].

Complications after vascular intervention

Post-surgical fistula track visualization can be difficult using Doppler US but is improved with CEUS without artifacts [252]. Additionally, CEUS may help to image flow in false aneurysms with greater precision than Doppler US [248].

Plaque characterization

The accepted predictor of stroke risk is the degree of carotid stenosis, with contributing imaging features recognized [253] [254]. Plaque ulceration, which is a reliable marker of plaque vulnerability, can be clearly imaged using CEUS [255], which has superior sensitivity and diagnostic accuracy for the assessment of ulceration compared with conventional Doppler US [256]. Plaque neovascularization demonstrated by CEUS correlates well with histological findings [257] [258] [259] [260] [261], depicts inflammation as a marker of plaque vulnerability [262] [263], and may be used to predict cerebral ischemic events [255] [264] [265] [266] [267] [268] [269] and stratify risk for coronary artery disease [270] [271]. The role of CEUS in routine clinical practice remains to be confirmed, particularly as objective assessment with quantification tools remains to be standardized [246].

Large vessel vasculitides

CEUS can also be used for the evaluation of large-vessel vasculitides, particularly to assess vascularization within the vessel wall. It improves the visualization of the lumen border, and allows dynamic assessment of carotid wall vascularization, which is a potential marker of disease activity [272] [273].

Vertebral artery

A hypoplastic vertebral artery is more frequently a risk factor for vertebrobasilar ischemia [274] [275]. A narrowed restricted artery (in the paired arteries) is more prone to closure, especially when other risk factors are present. Under difficult examining conditions, detection of low blood flow velocities in cases of hypoplasia can be difficult using conventional Doppler US. CEUS may differentiate between a hypoplastic vertebral artery and an occlusion at the origin.

Abdominal aortic

CEUS can overcome some limitations of conventional US by improving the delineation of the aortic lumen and the detection of the main branching arteries. CEUS also improves the diagnosis of aortic rupture by detecting contrast extravasation [276].

Aortic dissections

A dissection of the abdominal aorta is usually an extension of a thoracic aortic dissection. In most cases, the true and false lumen can be discriminated with CEUS, because both early (true lumen) and late (false lumen) contrast enhancement can be detected, provided the false lumen is not thrombosed [277].

Inflammatory Abdominal Aortic Aneurysm

Inflammatory aneurysm of the abdominal aorta is a variant of atherosclerotic aneurysm that is characterized by inflammatory and/or fibrotic changes in the peri-aortic region of the retroperitoneum [278]. CEUS of the inflammatory aneurysm improves differentiation between covered rupture and inflammatory aortic aneurysm [279].

Endovascular Aortic Graft Endoleak

An endoleak, classified into subtypes depending on the site of the leak, represents blood flow outside the stent graft lumen but within the aneurysm sac and conventionally detected by CT angiography, although CT angiography is limited in the detection of some endoleak subtypes [280]. CEUS is able to identify and characterize an endoleak more accurately than CT angiography, with analysis of velocity and flow direction [281] [282] [283] [284] [285]. CEUS is particularly useful in the management of “endotension” often finding an occult endoleak, not seen on CT angiography [286]. CEUS enhancement quantification by time-intensity curves provides additional accuracy [287]. CEUS for the follow-up of patients with endoleak is possible [288] [289].

Peripheral Vascular Disease

CEUS has been used to improve the diagnostic capabilities of peripheral vascular US but has not demonstrated superiority [290]. Doppler US is the imaging modality of choice for the detection of complications after puncture of the femoral artery, with CEUS potentially improving diagnosis. The detection and localization of small lower leg arteries in patient with PVD requiring peripheral bypass graft surgery is improved with CEUS [291] [292].

Limitations

Limitations of CEUS exploration of the carotid artery and abdominal aorta relate to any conditions that prevent adequate US penetration and also limit conventional B-mode US exploration. Of particular regard are extensive wall calcification and subcutaneous emphysema after intervention or limited examination windows.

Cerebral Vessels

Background

The major indication for CEUS in the examination of cerebral arteries is a poor signal with spectral Doppler US, preventing assessment of flow characteristics [293]. Contrast-enhanced transcranial color-coded duplex sonography (CE-TCCS) is best for simultaneously depicting B-mode brain anatomy as well as vessel detection and flow spectral Doppler tracing.

Study procedures

Transducers for CE-TCCS are identical to those for TCCS (sector 1.5 – 5.0 MHz). There are two applications using UCAs: main vessel, i. e. vascular imaging, and “perfusion imaging”. For vascular imaging, UCAs are utilized to enhance Doppler signals in trans-temporal or trans-nuchal transverse axial planes and coronal trans-temporal planes. Technical artifacts may cause inaccuracies: 1) bolus injection results in a blooming artifact preventing accurate Doppler spectral measurements. 2) UCA injection leads to an artificial increase (1 – 36 %) in maximum blood flow velocity, affecting stratification of a stenosis [294]. In perfusion imaging, either low or high MI CEUS is performed with trans-temporal insonation in the axial plane, but other insonation planes may also be used.

Main intracerebral vessel imaging: interpretation and evaluation

Vascular imaging

Most importantly, CE-TCCS is used to differentiate vessel occlusion in poor insonation conditions, and to detect very slow blood flow velocities and low flow volumes (small vessels, vessel pseudo-occlusion). The Doppler spectrum adds hemodynamic information to the anatomical information provided by color Doppler US.

Examination of the anterior circulation

A poor temporal bone window (45 % in the elderly) can usually be overcome with CE-TCCS; over 85 % of the basal arteries of the circle of Willis can be depicted satisfactorily after UCA administration [295]. CEUS infusion can be used in patients with poor acoustic windows for transcranial Doppler monitoring to test cerebral autoregulation as well as language lateralization for surgical planning.

Examination of the posterior circulation

CE-TCCS through the foramen magnum can increase the depth at which the intracranial vertebral arteries, the basilar artery, and the cerebellar artery segments can be identified and thus improve diagnostic confidence [294].

Internal carotid artery stenosis

Characterization of flow in the circle of Willis in patients with internal carotid artery stenosis and poor bone windows is important for estimating the risk of ipsilateral border zone infarction. Patients without collateral flow are particularly vulnerable to cross-clamping during carotid endarterectomy. The use of UCAs in these patients can provide valuable information for patient management [296].

Stroke patients

In acute stroke, the basal cerebral arteries can only be detected in 55 – 80 % of cases with unenhanced TCCS. Reliable diagnoses can be obtained in > 85 % with CE-TCCS with correlative findings on angiography in over 95 % of cases [293].

Perfusion imaging

CEUS is performed with transtemporal insonation in the axial plane in perfusion imaging, although other insonation planes may be used. After administration of a UCA, the perfusion deficit can be detected according to the affected vascular territory in stroke patients, and in patients with space-occupying intracranial lesions [297] [298] [299]. CEUS perfusion imaging has been shown to improve prognostic assessment in the acute phase of cerebral ischemia and to provide comparable results to CT [300] and MR imaging [301]. After bolus injection, time-intensity curves can be generated to extract features that describe the perfusion characteristics quantitatively in standardized regions of interest [293] [302].

Sono-thrombolysis

The combination of systemic thrombolysis and repeated administration of a UCA over an hour in patients with middle cerebral artery occlusion accelerates recanalization but also increases hemorrhage into the infarct [303] [304]. While of great interest as a method to enhance therapy, the hemorrhagic risk with repeated CEUS studies forced the two major sono-thrombolysis trials NOR-SASS and CLOTBUSTER to be terminated [305] [306].

Limitations

Despite UCA administration, only the proximal basilar artery can be evaluated. The distal portion can be depicted transtemporally, rendering the middle portion as a diagnostic gap for CE-TCCS. The quality of transtemporal unenhanced imaging is strongly predictive of the potential diagnostic benefit from the administration of a UCA. In patients without visible intracranial structures and vessels on conventional B-mode and Doppler US, there is little benefit from the addition of a UCA. The clinical value of the quantification of enhancement is limited by both physical and technical factors, with reliable identification of the absence of enhancement rather than the exact degree of blood supply impairment.

Endoscopic

Contrast-Enhanced Endoscopic US (CE-EUS)

Background

Contrast-enhanced endoscopic ultrasound (CE-EUS) combines the advantage of high-resolution US of the gastrointestinal wall, pancreas and other organs adjacent to the upper gastrointestinal tract with the ability to delineate micro- and macrovasculature [307] [308]. Two different techniques are available: with contrast-enhanced Doppler EUS (CED-EUS), the intensity of Doppler signals (color Doppler, power Doppler) is enhanced by the UCA, imaged at a high MI, used to visualize slow, low-volume blood flow (e. g. tumor vessels). Disadvantages of this technique include artifacts caused by tissue motion and microbubble destruction. Contrast-enhanced harmonic EUS (CEH-EUS) uses low MI techniques to visualize flow in small vessels and is established as an evidence-based technique [309] complementary to B-mode EUS and possibly EUS-elastography [310] to differentiate solid appearing structures, to characterize mass lesions, to improve staging of gastrointestinal and pancreatobiliary cancer and for real-time guidance of diagnostic and therapeutic EUS interventions [307] [308] [309] [311].

Study procedures

Contrast-enhanced high mechanical index EUS

In CED-EUS the color Doppler region of interest box should include the whole tumor where possible. CE endoscopic Doppler US scanning takes an extra 3 – 4 min. [312].

Contrast-enhanced low mechanical index EUS

“Peak-hold” techniques may be used to improve visualization with low MI techniques. With the high-frequency transducers used in EUS, a larger dose of UCA is used (e. g. 4.8 mL SonoVue™) [307] [308].

Applications in pancreatic lesions

Differential diagnosis of solid pancreatic lesions

CE-EUS can be used to differentiate between solid pancreatic lesions, mainly the hypoenhancing pancreatic ductal adenocarcinoma (PDAC) and iso- or hyper-enhancing solid pancreatic lesions (e. g. neuroendocrine tumors, pancreatic metastases, mass-forming focal pancreatitis, and serous microcystic cystadenoma). Meta-analyses showed a pooled sensitivity of 94 % and a specificity of 89 % for the differential diagnosis of PDAC from non-PDAC independent of the CE-EUS technique used [136] [313].

PDAC is characterized by hypoenhancement, irregular vascularization and a lack of venous vessels. Mass-forming focal pancreatitis exhibits netlike regular vascularization [314] [315] [316] [317]. Hypovascularity was shown to have a high diagnostic value for the detection of solid pancreatic masses ≤ 20 mm [316], and for the differentiation of PDAC from inflammatory and non-PDAC neoplastic masses. For small pancreatic tumors ≤ 20 mm, CED-EUS is significantly more accurate than CE-CT [316].

CEH-EUS is the more widely used technique for the differentiation of PDAC from other solid pancreatic lesions. With this technique, microvasculature and perfusion comparative qualitative or quantitative (time-intensity curves, TIC) analysis may be performed. In general, heterogeneous hypoenhancement is typical for PDAC, whereas almost all solid non-PDAC lesions exhibit iso- or hyperenhancement [313] [318] [319] [320] [321] [322]. Hyperenhancement with slow washout is a typical pattern of pancreatic neuroendocrine tumors (P-NET), while filling defects are highly predictive of malignancy [322] [323] [324] [325] [326]. In pseudo-tumoral chronic pancreatitis, isoenhancement and hyperenhancement are the most common patterns [319] [321] [322] [323] [327] [328]. Both focal and diffuse autoimmune pancreatitis demonstrate hyper-enhancement with CEH-EUS [329]. Prospective studies indicate that the diagnostic accuracy of CEH-EUS and EUS-FNA is comparable [320] [321] [323]. An accurate differential diagnosis of small solid pancreatic lesions is important. A retrospective multicenter study showed a high accuracy (86 %) of CEH-EUS for the differentiation of small solid pancreatic lesions ≤ 15 mm [330]. Concomitant use of both EUS-FNA and CEH-EUS increases the diagnostic yield and accuracy of EUS-FNA [323] [331] [332]. In patients with hypoenhancing solid pancreatic lesions and negative EUS-FNA, continuing suspicion of PDAC demands repeat tissue sampling.

Staging in pancreatic ductal adenocarcinoma

CEH-EUS may increase the accuracy of preoperative tumor staging and resectability evaluation of pancreatico-biliary malignancies [327] [333].

Characterization of cystic pancreatic lesions

Contrast enhancement of the wall, septations, nodules or solid parts of cystic pancreatic lesions in CE-EUS reliably separates neoplastic pancreatic cysts from pseudocysts and non-neoplastic cysts [334] [335] [336]. However, differentiation between serous cystadenoma and mucinous neoplastic cysts is not improved by CE-EUS [336] [337]. CE-EUS is significantly more reliable for the differentiation of mural nodules from intracystic mucus or debris than contrast-enhanced CT and B-mode EUS [336] [337] [338] [339] [340]. Further characterization of mural nodules by CE-EUS (morphological type, height, degree of enhancement) has been shown to be useful for risk stratification [337] [341].

Applications in non-pancreatic lesions

Gallbladder lesions

CEH-EUS improves the diagnosis of malignant gallbladder polyps and wall thickening over B-mode EUS [342] [343] [344] [345]. In gallbladder malignancy (protruding lesions as well as circumferential wall thickening), a heterogeneous enhancement pattern, the presence of perfusion defects and an irregular vessel pattern were found to be typical features with CEH-EUS. Homogeneous or absent enhancement occurs with benign lesions [342] [343] [344] [345].

Characterization of lymph nodes

Heterogeneous lymph node enhancement with focal filling defects is present in lymph nodes with metastatic infiltration, whereas the majority of benign lymph nodes demonstrate homogeneous enhancement [346]. However, due to similar homogeneous enhancement patterns of both benign lymph nodes and malignant lymphoma, the sensitivity was not improved over B-mode US [347]. CEH-EUS had a similar accuracy as EUS-FNA for diagnosing lymph node metastasis of pancreatobiliary cancer [348].

Gastrointestinal wall lesions

Assessment of the vascularization of gastric cancer is feasible using CE-EUS [349] [350]. The intensity of enhancement is correlated with pathological criteria of neo-angiogenesis (microvascular density; vascular endothelial growth factor, VGEF) [349]. CEH-EUS allows the assessment of treatment-induced changes of tumor vascularity in gastric cancer [350]. Differentiation between potentially malignant GIST and benign sub-epithelial tumors of the upper gastrointestinal tract can be improved by CE-EUS [351] [352]. Significantly stronger enhancement was observed in GIST than in leiomyoma and lipoma [353]. The detection of irregular intratumoral vessels in the arterial phase and a heterogeneous enhancement pattern are highly predictive for intermediate or high-risk GIST [353] [354] [355].

Visceral vascular diseases

CE-EUS may be used to diagnose splanchnic arterial and venous occlusive disease [356]. Moreover, CE-EUS improves the visualization of flow in esophageal varices, paraesophageal veins and perforating veins [357] [358] [359].

Abdominal Trauma

Background

CT imaging remains the standard technique for evaluating hemodynamically stable patients with high-energy multi-trauma, allowing rapid triage and reducing morbidity and mortality. CT has inherent disadvantages, which restrict its adequacy in some clinical scenarios: the patient needs to be stable and cooperative (sedation may be required, particularly in pediatric patients), it utilizes iodinated contrast media and carries the risks associated with radiation exposure. The latter is an important limiting factor, especially when a low-risk mechanism of injury and the patient’s condition would not necessarily warrant a CT examination, even though an imaging investigation is required. Focused Assessment with Sonography for Trauma (FAST) has been widely used in the diagnostic pathway of the trauma patient, with a sensitivity that ranges from 63 % to 99 % for the detection of free fluid [360], but has poor sensitivity in the diagnosis of parenchymal injuries. UCAs have significantly improved the diagnostic performance of B-mode US in the depiction of solid organ injuries [361] [362] [363], with performance close to that of CT: CEUS can achieve a sensitivity and specificity of 99 % [364] , avoiding overutilization of CT [365].

Study procedure

Commencing from the side of clinical concern, the examination should begin with the kidneys, their enhancement being the most fleeting, followed by the adrenals, liver, pancreas and lastly the spleen. The kidneys are studied during the arterial phase, while the liver, spleen, pancreas and adrenals are studied in the venous phases. Most commonly, the CEUS examination utilizes two separate doses of intravenous UCA: one dose is used to evaluate the right kidney, right adrenal, liver and pancreas and the second dose is aimed at the left kidney, left adrenal and spleen. In follow-up CEUS examinations, the known injured organ is targeted.

Image interpretation of abdominal injuries

On CEUS, lacerations and hematomas will show a complete lack of enhancement and will be clearly demarcated against the normal parenchyma, whereas areas of contusion may demonstrate faint enhancement. CEUS may also readily depict areas of hyperemia, infarct and active bleeding: any UCA pooling in the abdominal cavity will indicate the presence of ongoing hemorrhage, management becomes interventional. Crucial complications such as devascularized parenchyma, pseudoaneurysm formation and acute cortical necrosis of the kidney can also be promptly diagnosed on CEUS [41] [366]. CEUS can also allow further evaluation of abdominal injuries where CT findings are uncertain due to artifacts or where CT is discouraged, e. g. in renal impairment and in children. CEUS can confidently exclude major abdominal visceral injuries and therefore, patients sustaining minor, low-energy trauma can be discharged following a normal CEUS examination without the need to perform a CT examination.

Limitations

CEUS cannot diagnose traumatic lesions of the pelvicalyceal system, UCAs being purely intravascular and not excreted through the renal collecting system. The limitations with respect to bowel injury and a hemodynamically unstable patient would warrant a CT examination rather than a CEUS examination.

Superficial Structures

Thyroid

Background

An increasing thyroid malignancy incidence (≤ 8 per 100 000 in Europe) [367] would benefit from a noninvasive diagnostic method that allows reliable differentiation between malignant and benign thyroid nodules, superior to the current B-mode US features [368]. CEUS is able to focus on the analysis of macro- and microvascularization patterns [369] [370] [371].

Study procedure

Thyroid nodule assessment

Qualitative parameters

Qualitative parameters characterize nodule vascularization compared to the surrounding tissue, defined as intensity, homogeneity, UCA uptake and washout rate [369] [370] [371]. Hypoenhancement is the most precise predictor of malignancy on CEUS with high sensitivity, specificity and accuracy of 82 %, 85 % and 84 % respectively [372]. A heterogeneous contrast enhancement pattern has a sensitivity, specificity and accuracy of 88.2 %, 92.5 % and 90.4 %, respectively [370] [373] [374] [375] [376]. A ring enhancement pattern of a solid thyroid nodule is likely a benign feature with a sensitivity, specificity and accuracy of 83.0 %, 94.1 % and 88.5 %, respectively [370] [374].

Quantitative parameters

Time-intensity curves (TIC) for quantitative analysis are generated by placing the region of interest (ROI) in the nodule occupying the largest possible nodule area and comparing it to the surrounding tissues. The following parameters are evaluated: area of ROI, wash-in slope, time to peak, peak intensity, area under the curve, mean transit time and washout [369] [373]. Time-intensity curve patterns of washout may appear as poly-phasic or mono-phasic related to the heterogeneity of the nodule and histology, with a sensitivity, specificity and accuracy of 76.9 %, 84.8 % and 82.6 %, respectively [373] [375] [376].

Size

Nodule size affects CEUS examination and interpretation. A nodule < 10 mm shows absent vascularization (incomplete neovascularization), while larger nodules > 10 mm appear hypervascular [369] [371] [375].

Image interpretation

The diagnostic value of CEUS has been analyzed in a meta-analysis showing high pooled accuracy of CEUS in the differentiation between benign and malignant nodules [376] [376] [377] [378] [379] [380]. There is insufficient evidence regarding the application of CEUS in the assessment of thyroiditis.

Limitations

CEUS is a promising noninvasive method for the differential diagnosis of benign and malignant thyroid nodules. However, overlapping data between CEUS qualitative and quantitative evaluation parameters and criteria of benign and malignant nodules indicate a limitation in the interpretation of tumor microvascularity. No single indicator is sufficiently sensitive or specific. Therefore, the results should be interpreted in conjunction with the clinical data, conventional US and other imaging examination findings to improve diagnostic accuracy in the assessment of thyroid nodules [371] [372] [375].

Lymph Nodes

Background

The US discrimination between benign and malignant superficial lymphadenopathy is dependent on shape, anatomical appearance and vascular pattern with a wide range of sensitivities and specificities [381] [382]. UCAs have been shown to increase the accuracy of the analysis of the vascular pattern using the conventional color Doppler mode [383].

Study procedure

Normal linear high-frequency transducers enabled for CEUS examination with higher doses of UCA administered, normally 4.8 mL of SonoVue™, as in other superficial structures, are used.

Image interpretation

Malignant neo-vascularization, demonstrated when vessels penetrate the capsule of the node away from the hilum, is a characteristic feature of a metastatic lymph node [381] [382]. A benign reactive lymph node has preserved morphology and vascular anatomy, with a single vascular pedicle at the hilum, containing both arteries and veins, regularly branching towards the periphery of the lymph node [381] [382]. Display of the vascular anatomy can be facilitated by the addition of UCA during color Doppler US [383] [384] [385]. Using low MI CEUS techniques further improves characterization with a sensitivity and specificity of 93 % and 88 %, respectively [384] [386] [387] [388] [389].
US studies of lymph node vascularization have limitations, with most studies undertaken in specialized units and in patients with known head and neck cancer, melanoma or breast cancer [390]. Vessel distribution analysis is usually satisfactory if the whole lymph node is involved but is less informative when focal lymph node involvement or necrosis renders a CEUS examination (as well as other imaging modalities) inconclusive. Lymph nodes with lymphoma infiltration are unique as the vascular pattern resembles that of non-malignant nodes [390] [391], with a reported “speckled” pattern [392] and a different configuration on time-intensity curves [393] that may help to improve diagnosis.

Salivary Glands

Background

The B-mode US, Doppler US, elastography and CEUS appearance of parotid gland lesions has been analyzed to discriminate benign from malignant lesions [394] [395] [396]. CEUS investigations were initially performed with high MI US using color Doppler [394] and later with low MI techniques [397] [398]. The role of CEUS assessment of parotid gland lesions is limited by a paucity of studies, and relies on expert opinion [399] [400].

Study procedure

Normal linear high-frequency transducers enabled for CEUS examination with higher doses of UCA administered, normally 4.8 mL of SonoVue™, as in other superficial structures, are used, but fractionated doses have also been used [396].

Image interpretation

Qualitative approach

Malignant lesions demonstrate chaotic vessel formation on color Doppler US with increased enhancement with CEUS or with prominent organized vessel formation combined with slight enhancement on CEUS. Monomorphic adenomas showed vascularization patterns of all other entities [396]. Pleomorphic adenomas with minor vessel identification on color Doppler US result in poor perfusion on CEUS. All Warthin’s tumors show prominent internal vessel visualization on color Doppler US and increased enhancement with CEUS. According to the morphologic and distribution features of microvascularity, CEUS imaging of the lesions can be classified into three types: diffuse homogeneous enhancement (type 1), heterogeneous enhancement (type 2) and no enhancement/iso-enhancement (type 3). Types 1 and 3 are suggestive of benign tumors; Type 2 can indicate the presence of a malignant lesion [397].

Quantitative approach

Parotid gland lesions can be divided into different benign and malignant lesions by using specific time-intensity curve parameters from CEUS measurements. Malignant lesions appear highly vascularized, while benign lesions enhance less [398] [401]. The area under curve (AUC) and mean transit time (MTT) show significantly higher values for malignant lesions. The intratumoral time to peak in pleomorphic adenoma appears markedly longer than in cystadenolymphoma [402].

Breast

Background

CEUS in the differential diagnosis of breast masses was an early application, with encouraging initial results, but this early promise has not been fulfilled, despite numerous studies using modern methods including temporal accumulation methods (microvascular imaging) [403] [404] [405]. Studies relating to CEUS, MR imaging and biological factors [406] and studies to obtain a precise qualitative and quantitative vascular map of the tumor, which appears to correlate well with prognostic factors [407] or use CEUS to identify BI-RADS category 3 or 4 small breast lesions [408] have all been conducted, without specific patterns of CEUS enhancement of malignant lesions. A single study documented characteristic CEUS enhancement patterns which could be helpful for identifying papillary lesions and for predicting a potentially malignant papilloma [409]. CEUS has been used to estimate tumor size in invasive ductal cancer, which in turn predicted regional lymph node metastasis [410]. Notwithstanding, no specific pattern indicating malignancy has been identified and, although an important research topic, cannot be recommended for routine clinical use.

Sentinel lymph nodes

CEUS can be used for detecting axillary sentinel lymph nodes in cancer patients. SonoVue™ 1 mL (or 2 mL Sonazoid™ [411]) as the UCA is injected intradermally into the locally anesthetized periareolar skin towards the upper outer quadrant of the involved breast. The UCA is taken up by the subdermal lymphatics and the enhanced lymphatics can be traced to the sentinel node(s) [412] [413] [414] [415] [416] [417] [418]. Initial experience indicates that the method is non-toxic and performs as well as the blue dye or radioisotope methods [414]. It enables core biopsy of the sentinel node and, if positive on histology, is a reliable indicator of nodal involvement, directing patient counselling.

Inflammatory joint diseases

Background

Color or power Doppler US can detect the vascularity in the synovial proliferation associated with inflammatory activity. However, these US techniques have limited sensitivity and could benefit from the addition of a UCA.

Study procedure

Reports on the use of UCAs in inflammatory joint disease detect enhancement by conventional color or power Doppler US (CE Doppler). A full dose of 4.8 mL (SonoVue™) is used with standard transducers and equipment when investigating joints with CEUS.

Image interpretation

Arthritis and synovitis

Microscopic examination of synovial biopsies shows angiogenesis from the earliest stages of inflammatory disease. Proliferation of hypervascularized pannus can be detected before joint destruction. It correlates with disease activity and appears to be crucial to its invasive and destructive behavior [419]. The development of novel biological therapies (e. g. tumor necrosis factor-alpha inhibitors), which target the microvasculature, needs more sensitive vascular imaging to assess response to treatment [419] [420] [421] [422] [423]. The addition of UCAs to Doppler US significantly improves the detection of vascularity in active rheumatoid arthritis [424] [425] and psoriatic arthritis [426]. There is also evidence that CE power Doppler US helps to differentiate active from inactive disease in subclinical juvenile rheumatoid arthritis of the knee [427]. CE Doppler correlates with the findings of CEMR imaging, indicating the degree of inflammation in patients with synovitis [427]. CE Doppler is also more useful in the diagnosis of sacroiliitis than conventional Doppler [428] [429].

Differentiation between synovial pannus and fluid

Early detection of vascularized synovia is a primary goal of the assessment of inflammation. CE Doppler US improves the differentiation between active synovitis and other articular thickenings, such as fibrotic pannus and articular fluid [430] [431] [432].

Bursae and tendon

Contrast administration can highlight peripheral enhancement on Doppler US, corresponding to the vascularized synovial lining of an inflamed bursa, and can better differentiate between fluid, fibrous and hypervascular synovial thickening in comparison to non-enhanced Doppler US [433] [434] [435].

Therapeutic follow-up

Successful treatment results in a decrease in synovial thickening and necrosis of the pannus with reduction of vascularity and Doppler US signals. The distinction between fibrous pannus and active synovial proliferation is important during follow-up, because the volume of the synovium itself is not clinically significant, as it may contain varying amounts of fibrous tissue. Fibrotic pannus shows no vascularity on conventional power Doppler US and lacks enhancement on CEUS [436] [437] [438] [439] [440].

Gallbladder diseases

Background

B-mode and color Doppler US are the first-line imaging modalities for the diagnosis of gallbladder disease. The use of CEUS improves the diagnostic accuracy of US in selected cases. CEUS is not indicated if conventional US provides a clear diagnosis.

Study Procedure

For evaluation of the gallbladder wall, 1.2 – 2.4 mL of SonoVue™ is used, unless a high-frequency transducer is used when the dose is increased to 4.8 mL [176], with the arterial phase (< 30 s) differentiated from the venous phase (> 31 s) [441] [442] [443] [444] [445]. CEUS study of the gallbladder wall evaluates perfusion, contrast kinetics, branching intramural vessels and gallbladder wall integrity; with a late liver sweep for malignant metastasis.

Cholecystitis

Acute cholecystitis is normally associated with cholelithiasis, acalculous cholecystitis accounts for the minority of cases, but is associated with a higher incidence of gangrene and perforation [446]. In acute cholecystitis, the inflammatory process may involve the adjacent liver tissue (“reactive hepatitis” [447]) causing hepatic arterial hyperenhancement on CEUS. Gangrenous cholecystitis, transmural necrosis of the gallbladder wall, causes a discontinuous or irregular gallbladder on CEUS [448] [449]. CEUS should be considered in patients at risk for complicated acute cholecystitis [442] [450] [451] [452] [453]. Superficial or infiltrating gallbladder carcinoma may mimic chronic cholecystitis, presenting with diffuse wall thickening, with stones or sludge obscuring a malignant tumor. CEUS may help to detect a silent carcinoma [445] [454] [455].

Tumors of the gallbladder wall

Polypoid lesions

Polypoid gallbladder lesions are commonly seen on US (2.6 % – 12.1 % of cholecystectomy specimens) [456]. In primary sclerosing cholangitis and gastrointestinal polyposis syndromes, 60 % of gallbladder polyps are malignant [457] . Malignancy in gallbladder polyps between 6 – 10 mm is extremely rare, while polyps > 10 mm are regarded as preinvasive adenomas and papillary neoplasms [456] [458]. Adenomas have a wider vascular stalk, thought to be significant, that is best seen on CEUS [456] [459]. It remains unclear if CEUS can contribute to the differentiation between polyps, adenomas and noninvasive gallbladder carcinoma [441] [460]. Polyps > 10 mm which show an iso- and inhomogeneous enhancement pattern may be a criterion to differentiate adenomas from cholesterol polyps.

Adenomyomatosis

Adenomyomatosis is a hyperplastic process of the gallbladder wall affecting the complete gallbladder wall or parts of it, with the fundus representing the most frequent site. No intrinsic malignant potential has been described, but has been reported at 6.6 % in Asia [461]. On CEUS, the thickened wall demonstrates isoenhancement with a small non-enhancement rim surrounding the gallbladder [444] [462].

Adenocarcinoma of the wall

Adenocarcinoma is the most common malignancy of the gallbladder arising in the majority of cases from underlying chronic cholecystitis [463]. Nonspecific clinical signs result in a late diagnosis with a 5-year survival rate of 5 % [464]. Differentiation between benign and malignant gallbladder tumors cannot be made by hyperenhancement during the arterial phase as gallbladder cancers (85 %) and benign gallbladder diseases (70 %) both show hyperenhancement [452] [455]. The CEUS features of washout within 35 s after UCA administration, the destruction of gallbladder wall integrity and infiltration of the adjacent liver tissue are highly suggestive features of malignancy and highly suggestive of gallbladder cancer [441] [445]. CEUS can be used to differentiate between GB tumors and biliary sludge [465]. Gallbladder wall destruction beneath a solid lesion and the infiltration of adjacent liver tissue are highly suggestive features of malignancy [441] [444] [445] [460] [461] [465].

Gallbladder metastasis

Metastatic lesions of the gallbladder wall are rare with melanoma accounting for > 50 % [466]. On B-mode and CEUS, exophytic mural tumor nodules extend into the lumen of the gallbladder, with CEUS indicating a flow away from the wall [467].

Neurosurgery

Background

Intraoperative CEUS (iCEUS) allows for excellent evaluation with distinct enhancement phases and good delineation between lesions/vessels and healthy structures. These iCEUS features, together with high temporal and spatial resolution, make iCEUS invaluable in neurosurgery for vascular and oncological applications [468] [469] [470] [471] [472] [473] [474].

Study procedure

Ultrasound equipment

A contrast-enabled multi-frequency linear array transducer (3 – 11 MHz), most frequently using the UCA SonoVue™, is deployed [468] [469] [470] [471] [472] [473] [474] [475].

Examination technique

Patient positioning and craniotomy must be designed to allow direct contact of the transducer with the brain surface or the cavity filled with saline, to allow transducer manipulation. A preliminary CEUS examination is performed through the dura-mater after bone flap removal, preceded by a B-mode US examination, allowing identification of anatomical landmarks and lesion position/relationships. A standard evaluation to identify principal arteries, capillary and veins in the region of interest, evaluating the timing distribution and degree of UCA enhancement, is required [468] [469] [470] [471] [472] [473] [474] [475].

Intraoperative applications

Intraoperative evaluation of cerebral and spinal neoplastic lesions

Neoplastic lesion identification

Standard B-mode US is able to visualize and delineate most neoplastic lesions, both intra- and extra-axial. In intrinsic tumors with ill-defined borders or in the presence of brain edema, B-mode US is insufficient to evaluate tumor morphology and borders. iCEUS highlights the tumor parenchyma and the tumor-brain interface accurately, relying on the abnormal density of capillaries between the pathological tissue and the surrounding parenchyma [161] [468] [469] [471] [472] [474] [476] [477].

Tumor characterization

The degree of contrast enhancement and distribution is related to the density of capillaries in the region of interest. iCEUS allows real-time characterization of different histological types and grades dependent on timing, distribution and degree of contrast enhancement [468] [469] [474] [478] [479].

Tumor vascularization and surgical strategy

The direct visualization of parental and surrounding vessels allows determination of vessel location in the surgical field and optimizes the surgical strategy, allowing for early tumor devascularization before removal, thus reducing intraoperative bleeding [468] [470] [471] [472] [478] [480].

Tumor resection control

Safe repeated iCEUS examinations during surgery allow visualization of residual tumor within the surgical cavity, overcoming B-mode US limitations. iCEUS also allows assessment of complete tumor removal, showing no remaining enhancing areas and an absence of abnormal venous drainage [472] [477].

Intraoperative angio-sonography for cerebral and spinal vascular lesions

Vascular malformations are identified with Doppler US. iCEUS allows interpretation of the vascular tree prior to surgical exposure. iCEUS is able to determine the location of a vessel and follow its entire course and may be used with many different vascular abnormalities. iCEUS can also verify exclusion of the lesion from the circulation at the end of the procedure, and can also asses flow direction, vessel patency after aneurysm clipping, and brain perfusion in the distal territories [470] [473] [480].

Intraoperative contrast-enhanced ultrasound in traumatic brain surgery

iCEUS during surgery for trauma allows distinction between normal and injured brain tissue, more clearly than B-mode and color Doppler US. This improves the accuracy of the classification of traumatic brain injury, effectively removing hematoma and/or infarcted brain while preserving healthy tissue [475].

Limitations

Operator training is paramount and the craniotomy has to be large enough to allow free transducer movement. Transducer pressure on neural structures must not damage vessels or the parenchyma. Static retractors must be temporarily removed during iCEUS evaluation. The use of hemostatic materials must be limited to prevent artifact formation and restriction of the field of view.

Interventional CEUS

Background

CEUS has obvious potential during US-guided interventional procedures. Any CEUS-guided intervention can be performed in a similar manner to the routine US-guided version of the procedure [481]. It may be necessary to use two UCA injections, one to plan the procedure and a second to perform it. Alternatively, infusion may be used throughout the procedure. Besides the established use of CEUS in relation to percutaneous ablation and the potential benefit from intracavity CEUS, potential indications relate to accurate delineation of tissue vascularization.

Avoiding biopsy of necrotic tissue

By directing the biopsy needle towards contrast-enhanced areas within the target lesion, sampling from necrotic parts of the tumor can be avoided, resulting in an up to 15 % increase in diagnostic accuracy reported in large tumors and liver metastases [482] [483] and in lung, neck and musculoskeletal tumors [484] [485] [486] [487] [488].

Biopsy of poorly visualized or “invisible” lesions

When a biopsy is required based on findings from CT, MR or PET-CT imaging and the lesion is not clearly visualized or not visualized with B-mode US, CEUS may be helpful in two different ways: the target lesion suspected from previous imaging may become conspicuous on CEUS or additional lesions that are more accessible for biopsy may be visualized and biopsied [154] [489] [490].

Further benefits from CEUS in interventional US

CEUS may be used to:

• Diagnose and monitor all stages of bleeding related to interventional procedures and guide percutaneous local application of hemostatic drugs [491] [492].

• Improve breast cancer staging by identifying and guiding biopsy of the sentinel node after intradermal CEUS if axillary B-mode US is normal [413].

• Improve visualization of poorly depicted fluid collections [153] [493].

• Avoid biopsy of lesions if CEUS study unequivocally shows benign lesion, e. g. hepatic hemangioma [3].

Interstitial Ablation Therapy

Background

Interstitial ablation treatments are nonsurgical options for the management of confined tumors in the liver, kidney, prostate and uterus. CT and MR imaging represent the standard imaging modalities to assess therapeutic efficacy, but with evidence of the useful role of CEUS in the detection, guidance and confirmation of treatment success [494] [495].

Kidney

Thermal ablation is an accepted treatment option for unresectable renal cell carcinoma (RCC). The American Urological Association guidelines recommend ablation in patients with T1a disease (< 4 cm) with high surgical risk, or in case of solitary kidney [496]. Until recently, both preprocedural diagnostic workup and postprocedural follow-up of patients referred for RCC ablation have included CT and/or MR imaging, whereas conventional B-mode US is frequently used for guidance during the ablation procedure. CEUS is an important tool in the management of these patients and plays a decisive role in all stages of percutaneous ablation therapies [494] [495] [497] [498] [499] [500].

Study procedure

Pretreatment evaluation

Diffuse heterogeneous enhancement in the arterial phase, washout in the late phase and perilesional rim-like enhancement are typical features of renal malignancies [499] [500] [501]. Identification of a pseudo-capsule predicts improved ablation efficacy [502], and inclusion of CEUS in the preprocedural imaging workup is useful to compare pre-ablation and post-ablation tumor viability.

Intraprocedural evaluation

Intraprocedural ablation evaluation is important but CEUS can be affected by gas artifacts of the ablation technique that can mask evaluation of tumor necrosis. Normally a 10- to 15-minute post-ablation period should be allowed before assessing the outcome [500]. CEUS has demonstrated high sensitivity, specificity and accuracy for the early detection of residual un-ablated tumor, comparable to CT and MR imaging [499] [500] [501] [502] [503].

Follow-up

Surveillance is recommended in patients who have undergone ablation due to a high local recurrence rate for tumors > 3 cm [494] [497] [498] [499] [500], with suggested imaging surveillance every 6 months as CEUS can detect early recurrence not visible on B-mode US [496]. For the evaluation of residual or recurrent RCC, the sensitivity and specificity of CEUS are 82.2 – 100 % and 96.6 – 100 %, respectively [499] [503] [504]. The concordance of CEUS with CT or MR imaging is between 80 % and 100 % [498] [499] [503] [505] [506].

Prostate

Interstitial ablation through high-intensity focused ultrasound (HIFU) can be applied in localized prostate cancer in patients at high surgical risk or for local recurrence after radiotherapy [507]. There is good concordance between MR and CEUS imaging, with CEUS being able to clearly and correctly identify the devascularized area of necrosis and the residual viable tissue, permitting immediate repeat treatment [508].

Uterus

CEUS in the intraprocedural evaluation of treatment response of benign uterine fibroids to US-guided HIFU demonstrated that CEUS correlated well with MR imaging. Four studies for the evaluation of the therapeutic efficacy of uterine fibroids compared the performance of CEUS to MR [509] [510] [511] or unenhanced US [512] with CEUS performing well compared to MR and better than B-mode US. 

Miscellaneous

Intracavitary uses

Background

Extravascular or intracavitary administration of UCAs may be used as a problem-solving tool, recognized in a number of reports as an adjunct to US-guided interventional techniques [493], with practical advice detailing the available concepts and techniques [209] [513].

Study procedure

No standard UCA dosage has been established for intracavitary applications. The range reported is 0.1 mL – 1 mL SonoVue™ (or a few drops) diluted in ≥ 10 mL 0.9 % normal saline. A higher UCA dose may be needed for high-frequency US transducers.

Injection into physiological cavities

Imaging of tubal patency

Originally performed using agitated saline infused into the uterine cavity, hystero-salpingo-sonography has a 12 % false-negative patency rate [514]. Contrast-enhanced hystero-salpingo-contrast sonography (CE-HyCoSy) with SonoVue^™ provides better specificity [514] [515] [516], but is low for the diagnosis of an occlusion [514]. CE-HyCoSy should only be performed if conventional hystero-salpingo-contrast sonography does not show patency.

Detection of peritoneal-pleural communication

The detection of direct connections between the abdominal and pleural cavities, hepatic hydrothorax, can be established in cirrhotic patients by injecting a UCA into the peritoneal cavity, early (< 2 days) after thoracentesis and demonstrating UCA passage into the pleural cavity [517] [518] [519].

CEUS-guided percutaneous transhepatic cholangiography

CEUS-guided percutaneous cholangiography is able to delineate the biliary tree via an indwelling T-tube in place of the conventional fluoroscopic techniques, with the advantage of 3 D techniques [210] [520] [521] [522] [523] [524] [525] [526]. This technique allows for deployment at the point of care. UCA for endoscopic retrograde cholangiography (CEUS-ERC) has been reported [527] [528].

Intracavitary CEUS for guiding percutaneous nephrostomy

Intracavitary CEUS can guide percutaneous nephrostomy and assess complications and is able to confirm the needle or catheter position, evaluate the site of obstruction and assess catheter-related complications. Patients with contraindications to iodinated contrast agents are suitable for this technique or at the point of care [529] [530].

Salivary glands

CEUS injected into the main duct of a salivary gland may be a diagnostic method to categorize obstructive diseases of the salivary glands. The salivary gland is cannulated with appropriate dilatators and the plastic tube of a peripheral vein catheter is inserted [531] [532].

Injection into non-physiological cavities

CEUS for the imaging of fistula

CEUS detection and classification of fistulas, irrespective of the underlying disease, is effective [533] [534]. The following conditions have been reported: rectovaginal fistulas via a transvaginal approach [208], vesico-intestinal fistulas via a transabdominal approach [535] and anal fistulas via the transrectal approach [533].

CEUS for the imaging of abscesses

Image-guided treatment of abscesses includes drainage with a needle or catheter, plus lavage [493]. Direct injection of a UCA through the needle or catheter has been reported to facilitate confirmation of correct needle or catheter position and allows evaluation of any communication between cavities in complex abscesses [493] [513] [536] [537].

Free Tissue Transplants

Background

Free flap reconstruction of complex defects after trauma, tumor resection, burns, or poor wound healing is able to restore the integrity of the defect and provide return of function. Despite technical refinement, flap loss due to vascular compromise occurs and is a serious complication. Early identification of vascular compromise and prompt revision permits early flap salvage, with CEUS being an ideal technique for the early detection of reduced vascularization [538] [539] [540] [541] [542]. CEUS is the only imaging method for the evaluation of dynamic changes of microvascularization during surgery and postoperative follow-up

Study procedure

High-frequency transducers (≥6 MHz) are used to evaluate the microcirculation of the cutaneous, subcutaneous, and deeper layers of free flaps most frequently using 1.2 – 2.4 mL SonoVue™. Postoperative TIC analysis allows calculation of peak and time to peak of enhancement and regional blood volume.

Image Interpretation

Preoperative planning

The blood vessels in the transplanted free flap are small (1 – 2 mm). The surgeon needs to know the integrity of the flow, precise number, course and position of these blood vessels in order to estimate the proportion with a good blood supply. Evaluation to determine time to peak (TTP), relative blood flow (rBF) and relative blood volume (rBV) as well as the evaluation of the critical microvascularization in the different layers of the free flaps is undertaken.

Intraoperative imaging

CEUS enables the identification of perforator vessels intraoperatively, detecting abnormalities, to allow a more accurate decision as to whether the entire flap is perfused and if the estimated flap size is correct.

Postoperative monitoring

The feeding vessels or, if there is a connection to a bypass, the anastomosis, as well as the free flap vessels is examined to identify thrombosis, embolism, twisting, kinking, or compression to confirm successful surgical salvage [541] [543].

Critical microvascularization

A significant difference between normally vascularized and compromised flaps can be observed most usefully with TTP and RBF [544]. For CEUS and CE-MRI, the mean signal increase of the TIC was significantly higher in ROIs of normally perfused flaps compared to compromised flaps [545] [546] [547] [548] [549]. With CEUS, the exact size of the necrotic regions, hematoma or seroma can be evaluated by analyzing avascular areas.

Limitations

A limitation for the evaluation of flap perfusion is the time allowed after a bolus injection of the UCA. Continuous infusion may improve this, but this has not been evaluated.

Lung

Background

US of parenchymal lung lesions targets only those lesions abutting the pleura, and in this context, an accurate diagnosis is possible [550] [551] [552] [553]. CEUS in the evaluation of lung lesions is less well investigated. The lung parenchyma has a dual arterial system, the pulmonary arteries and the bronchial arteries. The ratio between blood supply from pulmonary arteries and bronchial arteries varies depending on the etiology of the underlying disease [554].

Study Procedure

The administered dose varies (SonoVue™ 2.4, rarely 4.8 mL) followed by a bolus of normal saline [554] [555] [556] [557], with the enhancement continuously observed for at least 30 seconds. A time to enhancement of < 10 seconds is indicative of a predominant supply from pulmonary arteries [555] [556] [557].

Clinical applications

CEUS might be a valuable tool to differentiate benign from malignant lesions [555] [557] and in the assessment of pulmonary embolic consolidation [555]. Studies are limited, with few patients to allow for determination of the diagnostic value of CEUS in the evaluation of lung lesions.

Pneumonia

Pneumonia is mainly supplied by the pulmonary artery, resulting in early (< 10 seconds) homogenous enhancement [554] [557]. CEUS has also been reported to be a valuable tool for detecting and guiding drainage of abscess formation within pneumonia [558].

Pulmonary embolism

Embolic consolidations in patients with pulmonary embolism are reported to show absent or non-homogenous enhancement on CEUS, a consequence of variable degrees of bronchial arterial supply [555]. This feature could be helpful for distinguishing pulmonary infarction from pneumonia or compression atelectasis.

Atelectasis

Compression atelectasis is mainly supplied by the pulmonary artery and demonstrates early, marked enhancement on CEUS [556], whereas obstructive atelectasis presents with a delayed enhancement pattern [559]. Responsive vasoconstriction in obstructive atelectasis is considered responsible for the differences in enhancement pattern, but this is debatable [559].

Lung cancer

The enhancement pattern of lung cancer is variable [556], but there are suggestions that delayed (> 7.5 seconds) enhancement in neoplastic lesions might be a useful characterization of malignant pulmonary lesions [554]. CEUS may be used to avoid areas of necrosis in US-guided biopsies to increase diagnostic accuracy.

Tumor Response Assessment

Background

The advent of novel therapies targeting tumor angiogenesis and vascularity has highlighted the need for accurate and reproducible quantitative techniques to assess early changes in tumor vascularity [560]. However, as these therapies are predominantly cytostatic, current response assessment, which is based on interval evaluation of the tumor size using the Response Evaluation Criteria In Solid Tumors (RECIST) [561] is inadequate as it reflects only late changes and is unable to identify non-responders at an early time-point [562].

Study procedure

Dynamic contrast-enhanced US (DCE-US) can be performed using two different approaches with different results [563]:

Bolus injection of a UCA with TIC analysis

Single plane imaging is usually performed at 10 – 20 frames per second for the duration of the enhancement. The average intensity within a region of interest (ROI) can be displayed as a function of time, i. e., a TIC which describes the wash-in and washout of the UCA in the ROI [564]. In addition, a second ROI can be placed in a reference tissue for comparison purposes [565]. The majority of clinical studies to date are based on this method.

Intravenous infusion of a UCA with disruption-replenishment analysis

The UCA is administered over 5 to 20 minutes. UCA is first imaged without being disrupted at a low MI, then the MI is increased for a few frames, causing microbubble disruption. Immediately after that, the MI is returned to the non-disrupting level to observe the replenishment of the microbubbles into the ROI. Various models describe the echo-signal dynamics during the UCA-replenishment phase, which can be used for flow analysis [566]. Initially, monitoring for tumor response with UCAs relied on qualitative analyses [567], but new methodologies have been developed to produce more robust and semi-quantitative indices. Analyses of the TIC, including wash-in and washout times, can be performed with curve fitting to determine functional indices [568]. The main indices include: peak intensity (PI); area under the curve (AUC); area under the wash-in (AUWI); area under the washout (AUWO; all corresponding to blood volume); time to peak intensity (TPI); slope of the wash-in (SWI; both corresponding to blood flow); and mean transit time (MTT). No permeability information can be obtained because of the pure blood pool nature of microbubbles.

Clinical application

Early clinical trials employed qualitative analysis in the assessment of the response of different tumors such as gastrointestinal stromal tumor (GIST) or renal cell carcinoma [569] [570] [571] [572]. More recently, there have been studies using semi-quantitative techniques with UCA bolus injection in renal cell carcinoma, hepatocellular carcinoma (HCC) and GIST [573] [574] [575]. Studies showed that two indices representing blood volume correlated with the RECIST response; one study on renal cell carcinoma demonstrated a correlation of such indices with Progression Free Survival and Overall Survival [573]. The results could not be reproduced in a study testing the disruption-replenishment technique versus Progression Free Survival assessed by the RECIST method [566].

A multicenter study of various types of tumors treated with anti-angiogenic therapies, such as metastatic renal cell carcinoma, GIST, colon cancer, melanoma, breast cancer and HCC, with approximately half of the tumors being located outside the liver, is currently being conducted in 539 patients with more than 2000 DCE-US scans. A quality score was proposed in a standardized acquisition [576], with AUC being the best parameter. A decrease of 40 % at one month was significantly correlated with Freedom From Progression (FFP) and also with Overall Survival which is the best end-point for the validation of a biomarker [577]. There is now emerging evidence that DCE-US may be used with appropriate tools to differentiate between responders and non-responders at an earlier stage than conventional methods and this potentially allows tailoring of the treatment regimen, particularly changing treatment for non-responders. DCE-US has been endorsed by the European Medical Oncology Society to assess response under biological therapy for GIST [578].

Conflict of Interest

Fabrizio Calliada: Congress participation support, Toshiba, Guerbet, Bayer, Hitachi, Mindray
Vito Cantisani: Congress participation support, Toshiba, Guerbet, Bayer, Hitachi, Mindray
Dirk Clevert: Speaker honoraria for Siemens, Philips, Samsung Falk, Bracco; Advisory Board Member Siemens, Philips, Samsung, Bracco; Research grants, Siemens, Philips, Samsung, Bracco
David Cosgrove: Speaker honoraria, Bracco, Toshiba, SuperSonic, BK Medical, Carestream; Advisory Board Member, Toshiba, Carestream; Research grant, Carestream; Congress participation support, Bracco, Toshiba
Annamarie Dagenello: Speaker honoraria, Bracco
Christoph F Dietrich: Speaker honoraria, Bracco, Hitachi, GE, Mindray, Supersonic, Pentax, Olympus, Fuji, Covidien, Boston Scientific, AbbVie, MSD, Falk Foundation, Novartis, Roche; Advisory Board Member, Hitachi and Mindray; Research grant, Bracco, Hitachi, GE, Siemens, Mindray, SuperSonic; Congress participation support, IPSEN
Odd Helge Gilja: Speaker honoraria, GE Healthcare Takeda AS and Meda AS
Christian Jenssen: Speaker honoraria, Bracco, Hitachi, Toshiba, Falk Foundation, Covidien; Research grant, Novartis
Nathalie Lassau: Speaker honoraria, Bracco, Toshiba; Congress participation support, Bracco, Toshiba
Edward Leen: Research equipment support, Philips Healthcare & SuperSonic Imaging
Maria Franca Meloni: Speaker honoraria, Bracco
Christian Pállson Nolsøe: Speaker honoraria and congress participation support, GE Healthcare and Neovitalis
Mirko D’Onofrio: Speaker honoraria, Bracco, Siemens; Advisor Board Member, Bracco, Siemens, Congress participation support, Bracco
Fabio Piscaglia: Speaker honoraria Bracco, Bayer; Advisory Board Member, Bayer; Research support, Esaote
Maija Radzina: Speaker honoaria, Bayer, Covidien; Congress participation support, Bayer
Adrian Saftiou: Speaker honoraria, Pentax Medical Singapore Ltd; Consulting/Advisory board, Mediglobe Corporation Gmbh; Congress participation support, Hitachi Medical Systems UK
Paul Sidhu: Speaker honoraria, Siemens, Bracco, Hitachi, Philips and GE
Hans-Peter Weskott: Speaker honoraria for Bracco, Samsung and GE
The following members declared no conflicts of interest: Eva Bartels, Michele Bertolotto, Francesca Drudi, Simon Freeman, Christopher Harvey, Ernst Michael Jung, Andrea Klauser, Carlos Nicolau, Francesco Prada, Luca Savelli, Hessel Wijkstra

Acknowledgements

The authors thank the EFSUMB’s Lynne Rudd for her continuing support of the guidelines.

We also thank the following companies for funding a consensus meeting of the authors held in London in July 2016, at which we agreed on recommendations: bk/Ultrasound, Echosens, Esaote SpA, GE Healthcare, Hitachi Medical Systems, Philips Healthcare, Shenzhen Mindray Bio-medical Electronics Co., Ltd, Siemens Heathineers, Supersonic, Toshiba Medical and Bracco SpA.

Representatives of these companies were in attendance at this meeting to assist with technical product information but did not take part in the writing of this manuscript or the recommendations.

• References

• 1 Albrecht T, Blomley MJK, Bolondi L. et al. Guidelines for the use of contrast agents in ultrasound. Ultraschall in Med 2004; 25: 249-256
  Article in Thieme ConnectPubMedGoogle Scholar
• 2 Claudon M, Cosgrove D, Albrecht T. et al. Guidelines and Good Clinical Practice Recommendations for Contrast Enhanced Ultrasound (CEUS) – Update 2008. Ultraschall in Medizin 2008; 29: 28-44
  PubMedGoogle Scholar
• 3 Claudon M, Dietrich CF, Choi BI. et al. Guidelines and good clinical practice recommendations for contrast enhanced ultrasound (CEUS) in the liver – update 2012. Ultraschall in Med 2013; 34: 11-29
  Article in Thieme ConnectPubMedGoogle Scholar
• 4 Piscaglia F, Nolsoe C, Dietrich CF. et al. The EFSUMB guidelines and recommendations on the clinical practice of contrast enhanced ultrasound (CEUS): update 2011 on non-hepatic applications. Ultraschall in Med 2012; 32: 33-59
  Article in Thieme ConnectPubMedGoogle Scholar
• 5 Sidhu PS, Cantisani V, Deganello A. et al. Role of contrast-enhanced ultrasound (CEUS) in paediatric practice: An EFSUMB position statement. Ultraschall in Med 2017; 38: 33-43
  Article in Thieme ConnectPubMedGoogle Scholar
• 6 Sidhu PS, Choi BI, Bachmann Nielsen M. The EFSUMB guidelines and recommendations on the clinical practice of contrast enhanced ultrasound (CEUS): a new dawn for the escalating use of this ubiquitous technique. Ultraschall in Med 2012; 32: 5-7
  Article in Thieme ConnectPubMedGoogle Scholar
• 7 Food & Drug Administration. MARCH 2016 – APPROVED DRUG PRODUCT LIST. 2016 http://www.fda.gov/downloads/drugs/developmentapprovalprocess/ucm071120.pdf
  PubMedGoogle Scholar
• 8 Bracco. Lumason Prescribing Information. 2016 http://imaging.bracco.com/sites/braccoimaging.com/files/technica_sheet_pdf/US-20160330-LUMASON-PI_0.pdf
  PubMedGoogle Scholar
• 9 Seitz K, Strobel D. A Milestone: Approval of CEUS for Diagnostic Liver Imaging in Adults and Children in the USA. Ultraschall in Med 2016; 37: 229-232
  Article in Thieme ConnectPubMedGoogle Scholar
• 10 Education and Practical Standards Committee E. Minimal Training recommendations for the practice of medical ultrasound. Ultraschall in Med 2006; 27: 79-95
  PubMedGoogle Scholar
• 11 Education and Practical Standards Committee E. Minimum Training Requirements for the Practice of Medical Ultrasound in Europe. Appendix 14: (CEUS) Contrast Enhanced Ultrasound. Ultraschall in Med 2010; 31: 426-427
  Article in Thieme ConnectPubMedGoogle Scholar
• 12 Quaia E, Alaimo V, Baratella E. et al. Effect of Observer Experience in the Differentiation Between Benign and Malignant Liver Tumors After Ultrasound Contrast Agent Injection. J Ultrasound Med 2010; 29: 25-36
  CrossrefPubMedGoogle Scholar
• 13 Greis C. Technical aspects of contrast-enhanced ultrasound (CEUS) examinations: tips and tricks. Clin Hemorheol Microcirc 2014; 58: 89-95
  PubMedGoogle Scholar
• 14 Blomley MJK, Sidhu PS, Cosgrove DO. et al. Do different types of liver lesions differ in their uptake of the microbubble contrast agent SH U 508A in the late liver phase? Early experience. Radiology 2001; 220: 661-667
  CrossrefPubMedGoogle Scholar
• 15 Bryant TH, Blomley MJK, Albrecht T. et al. Liver phase uptake of a liver specific microbubble improves characterization of liver lesions: a prospective multi-center study. Radiology 2004; 232: 392-399
  PubMedGoogle Scholar
• 16 Edey AJ, Ryan SM, Beese RC. et al. Ultrasound imaging of liver metastases in the delayed parenchymal phase following administration of Sonazoid™ using a destructive mode technique (Agent Detection Imaging™). Clin Radiol 2008; 63: 1112-1120
  CrossrefPubMedGoogle Scholar
• 17 Piscaglia F, Bolondi L. The safety of SonoVue in abdominal applications: retrospective analysis of 23188 investigations. Ultrasound Med Biol 2006; 32: 1369-1375
  CrossrefPubMedGoogle Scholar
• 18 Main ML. Ultrasound contrast agent safety: from anecdote to evidence. JACC Cardiovasc Imaging 2009; 2: 1057-1059
  CrossrefPubMedGoogle Scholar
• 19 Main ML, Goldman JH, Grayburn PA. Thinking Outside the box:The Ultrasound Contrast Controversy. J Am Coll Cardiol 2007; 50: 2434-2437
  CrossrefPubMedGoogle Scholar
• 20 Tang C, Fang K, Guo Y. et al. Safety of Sulfur Hexafluoride Microbubbles in Sonography of Abdominal and Superficial Organs: Retrospective Analysis of 30222 Cases. J Ultrasound Med 2017; 36: 531-538
  CrossrefPubMedGoogle Scholar
• 21 Wilson SR, Burns PN. Microbubble-enhanced US in body imaging: What role?. Radiology 2010; 257: 24-39
  CrossrefPubMedGoogle Scholar
• 22 Kitzman DW, Goldman ME, Gilliam LD. et al. Efficacy and safety of the novel ultrasound contrast agent perflutren (Definity) in patients with suboptimal baseline left ventricular echocardiographic images. Am J Cardiol 2000; 86: 669-674
  CrossrefPubMedGoogle Scholar
• 23 Cochran ST, Bomyea K, Sayre JW. Trends in adverse events after IV administration of contrast media. Am J Roentgenol 2001; 176: 1385-1388
  CrossrefPubMedGoogle Scholar
• 24 Hunt CH, Hartman RP, Hesley GK. Frequency and Severity of Adverse Effects of Iodinated and Gadolinium Contrast Materials: Retrospective Review of 456930 Doses. Am J Roentgenol 2009; 193: 1124-1127
  CrossrefPubMedGoogle Scholar
• 25 Committee for Medicinal Products for Human Use (CHMP). Assessment report EMA/84084/2014. SonoVue. international non-properietary name: sulfur hexafluoride, Procedure No. EMEA/H/C/000303/II/0025. 2014
  PubMedGoogle Scholar
• 26 Darge K, Papadopoulu F, Ntoulia A. et al. Safety of contrast-enhanced ultrasound in children for non-cardiac applications: a review by the Society for Pediatric Radiology (SPR) and the International Contrast Ultrasound Society (ICUS). Pediatr Radiol 2013; 43: 1063-1073
  CrossrefPubMedGoogle Scholar
• 27 Harvey CJ, Alsafi A, Kuzmich S. et al. Role of US contrast agents in the assessment of indeterminate solid and cystic lesions in native and transplant kidneys. Radiographics 2015; 35: 1419-1430
  CrossrefPubMedGoogle Scholar
• 28 Barr RG, Peterson C, Hindi A. Evaluation of indeterminate renal massess with contrast-enhanced US: a diagnostic performance study. Radiology 2014; 271: 133-142
  CrossrefPubMedGoogle Scholar
• 29 Harkanyi Z. Potential applications of contrast-enhanced ultrasound in pediatric patients. Ultrasound Clin North Am 2013; 8: 403-422
  CrossrefPubMedGoogle Scholar
• 30 Sellars ME, Deganello A, Sidhu PS. Paediatric contrast-enhanced ultrasound (CEUS); a technique that requires co-operation for rapid implementation into clinical practice. Ultraschall in Med 2014; 35: 203-206
  Article in Thieme ConnectPubMedGoogle Scholar
• 31 Caruso G, Salvaggio G, Campisi A. et al. Bladder Tumor Staging: Comparison of Contrast-Enhanced and Gray-Scale Ultrasound. Am J Roentgenol 2010; 194: 151-156
  CrossrefPubMedGoogle Scholar
• 32 Drudi FM, Di Leo N, Maghella F. et al. CEUS in the study of bladder, method, administration and evaluation, a technical note. J Ultrasound 2014; 17: 57-63
  CrossrefPubMedGoogle Scholar
• 33 Drudi FM, Cantisani V, Liberatore M. et al. Role of Low-Mechanical Index CEUS in the Differentiation between Low and High Grade Bladder Carcinoma: a Pilot Study. Ultraschall in Med 2010; 31: 589-595
  Article in Thieme ConnectPubMedGoogle Scholar
• 34 Wang XH, Wang YJ, Lei CG. Evaluating the perfusion of occupying lesions of kidney and bladder with contrast-enhanced ultrasound. Clin Imaging 2011; 35: 447-451
  CrossrefPubMedGoogle Scholar
• 35 Nicolau C, Bunesch L, Sebastia C. et al. Diagnosis of bladder cancer: contrast-enhanced ultrasound. Abdom Imaging 2010; 35: 494-503
  CrossrefPubMedGoogle Scholar
• 36 Nicolau C, Bunesch L, Peri L. et al. Accuracy of contrast-enhanced ultrasound in the detection of bladder cancer. Br J Radiol 2011; 84: 1091-1099
  CrossrefPubMedGoogle Scholar
• 37 Correas JM, Claudon M, Tranquart F. et al. The kidney: imaging with microbubble contrast agents. Ultrasound Q 2006; 22: 53-66
  PubMedGoogle Scholar
• 38 Tsuruoka K, Yasuda T, Koitabashi K. et al. Evaluation of Renal Microcirculation by Contrast-Enhanced Ultrasound With Sonazoid^TM as a Contrast Agent Comparison Between Normal Subjects and Patients With Chronic Kidney Disease. Int Heart J 2010; 51: 176-182
  CrossrefPubMedGoogle Scholar
• 39 Ma F, Cang Y, Zhao B. et al. Contrast-enhanced ultrasound with SonoVue could accurately assess the renal microvascular perfusion in diabetic kidney damage. Nephrol Dial Transplant 2012; 27: 2891-2898
  CrossrefPubMedGoogle Scholar
• 40 Bertolotto M, Martegani A, Aiani L. et al. Value of contrast-enhanced ultrasonography for detecting renal infarcts proven by contrast enhanced CT. A feasibility study. Eur Radiol 2008; 18: 376-383
  CrossrefPubMedGoogle Scholar
• 41 Yusuf GT, Sellars ME, Huang DY. et al. Cortical Necrosis Secondary to Trauma in a Child: Contrast-enhanced ultrasound comparable to Magnetic Resonance Imaging. Pediatr Radiol 2014; 44: 484-487
  CrossrefPubMedGoogle Scholar
• 42 Mazziotti S, Zimbaro F, Pandolfo A. et al. Usefulness of contrast-enhanced ultrasonography in the diagnosis of renal pseudotumors. Abdom Imaging 2010; 35: 241-245
  CrossrefPubMedGoogle Scholar
• 43 Quaia E, Bertolotto M, Cioffi V. et al. Comparison of contrast-enhanced sonography with unenhanced sonography and contrast-enhanced CT in the diagnosis of malignancy in complex renal masses. Am J Roentgenol 2008; 191: 1239-1249
  CrossrefPubMedGoogle Scholar
• 44 Clevert DA, Minaifar N, Weckbach S. et al. Multislice computed tomography versus contrast-enhanced ultrasound in evaluation of complex cystic renal masses using the Bosniak classification system. Clin Hemorheol Microcirc 2008; 39: 171-178
  Google Scholar
• 45 Park BK, Kim B, Kim SH. et al. Assessment of cystic renal masses based on Bosniak classification: comparison of CT and contrast-enhanced US. Eur J Radiol 2007; 61: 310-314
  CrossrefPubMedGoogle Scholar
• 46 Ascenti G, Mazziotti S, Zimbaro G. et al. Complex Cystic Renal Masses: Characterization with Contrast-enhanced US. Radiology 2007; 243: 158-165
  CrossrefPubMedGoogle Scholar
• 47 Bertolotto M, Cicero C, Perrone R. et al. Renal masses with equivocal enhamcement at CT: characterization with contrast-enhanced ultrasound. Am J Roentgenol 2015; 205: W557-W565
  Google Scholar
• 48 Fontanilla T, Minaya J, Cortes C. et al. Acute complicated pyelonephritis: contrast-enhanced ultrasound. Abdominal Imaging 2012; 37: 639-646
  CrossrefPubMedGoogle Scholar
• 49 Ignee A, Straub B, Brix D. et al. The value of contrast enhanced ultrasound (CEUS) in the characterisation of patients with renal masses. Clin Hemorheol Microcirc 2010; 46: 275-290
  PubMedGoogle Scholar
• 50 Papadopoulou F, Ntoulia A, Siomou E. et al. Contrast-enhanced voiding urosonography with intravesical administration of a second-generation ultrasound contrast agent for diagnosis of vesicoureteral reflux: prospective evaluation of contrast safety in 1010 children. Pediatr Radiol 2014; 44: 719-728
  CrossrefPubMedGoogle Scholar
• 51 Darge K. Voiding urosonography with US contrast agents for the diagnosis of vesicureteric reflux in children. I. Procedure. Pediatr Radiol 2008; 38: 40-53
  CrossrefPubMedGoogle Scholar
• 52 Darge K. Voiding urosonography with US contrast agents for the diagnosis of vesicureteric reflux in children. II. Comparison with radiological examinations. Pediatr Radiol 2008; 38: 54-63
  CrossrefPubMedGoogle Scholar
• 53 Ascenti G, Zimbaro G, Mazziotti S. et al. Harmonic US imaging of vesicoureteric reflux in children: usefulness of a second generation US contrast agent. Pediatr Radiol 2004; 34: 481-487
  CrossrefPubMedGoogle Scholar
• 54 Wong LS, Tse KS, Fan TW. et al. Voiding urosonography with second-generation ultrasound contrast versus micturating cystourethrography in the diagnosis of vesicoureteric reflux. Eur J Pediatr 2014; 173: 1095-1101
  CrossrefPubMedGoogle Scholar
• 55 Duran C, Riego J, Riera L. et al. Voiding urosonography including urethrosonography: high-quality examinations with an optimised procedure using a second-generation US contrast agent. Pediatr Radiol 2012; 42: 660-667
  CrossrefPubMedGoogle Scholar
• 56 Kis E, Nyitrai A, Varkonyi I. et al. Voiding urosonography with second-generation contrast agent versus voiding cystourethrography. Pediatr Nephrol 2010; 25: 2289-2293
  CrossrefPubMedGoogle Scholar
• 57 Papadopoulou F, Anthopoulou A, Siomou E. et al. Harmonic voiding urosonography with a second-generation contrast agent for the diagnosis of vesicoureteral reflux. Pediatr Radiol 2009; 39: 239-244
  PubMedGoogle Scholar
• 58 Darge K. Voiding urosonography with US contrast agent for the diagnosis of vesicoureteric reflux in children: an update. Pediatr Radiol 2010; 40: 956-962
  CrossrefPubMedGoogle Scholar
• 59 Giordano M, Marzolla R, Puteo F. et al. Voiding urosonography as first step in the diagnosis of vesicoureteral reflux in children: a clinical experience. Pediatr Radiol 2007; 37: 674-677
  CrossrefPubMedGoogle Scholar
• 60 Duran C, Valera A, Alguersuari A. et al. Voiding urosonography: the study of the urethra is no longer a limitation of the technique. Pediatr Radiol 2009; 39: 124-131
  CrossrefPubMedGoogle Scholar
• 61 Lebowitz RL, Olbing H, Parkkulainen KV. et al. International system of radiographic grading of vesicourteric reflux. Internationa Reflux Study in Children. Pediatr Radiol 1985; 15: 105-109
  CrossrefPubMedGoogle Scholar
• 62 Fernaíndez-Ibieta M, Parrondo-Muiros C, Fernaíndez-Masaguer LC. et al. Urosonografi¡a miccional con contraste de segunda generaci+¦n como herramienta primaria en el estudio de la vi¡a urinaria superior e inferior en pediatri¡a. Estudio Piloto. Actas Urolgicas Espaolas 2016; 40: 183-189
  PubMedGoogle Scholar
• 63 Wozniak MM, Wieczorek AP, Pawelec A. et al. Two-dimensional (2D), three-dimensional static (3D) and real-time (4D) contrast enhanced voiding urosonography (ceVUS) versus voiding cystourethrography (VCUG) in children with vesicoureteral reflux. Eur J Radiol 2016; 85: 1238-1245
  CrossrefPubMedGoogle Scholar
• 64 Duran C, Riego J, Riere L. Serial voiding urosonography: a safe technique for the study of the entire urinary tract in children. Radiologia 2013; 55: 160-166
  CrossrefPubMedGoogle Scholar
• 65 Kmetec A, Bren AF, Kandus A. et al. Contrast-enhanced ultrasound voiding cystography as a screening examination for vesicoureteral reflux in the follow-up of renal transplant recipient: a new approach. Nephrol Dial Transplant 2001; 16: 120-123
  PubMedGoogle Scholar
• 66 Valentini AL, De Gaetano AM, Minordi LM. et al. Contrast-enhanced Voiding US for Grading of Reflux in Adult Patients Prior to Antireflux Ureteral Implantation. Radiology 2004; 233: 35-39
  CrossrefPubMedGoogle Scholar
• 67 Kenda RB, Kenig A, Novijan G. et al. Cyclic voiding urosonography for detecting vesicoureteric reflux in renal transplant recipients. Nephrol Dial Transplant 2001; 16: 2229-2231
  CrossrefPubMedGoogle Scholar
• 68 Jaffer OS, Sidhu PS. Contrast-enhanced ultrasonography of the testes. Ultrasound Clin North Am 2013; 8: 509-523
  PubMedGoogle Scholar
• 69 Albrecht T, Lotzof K, Hussain HK. et al. Power Doppler US of the normal prepubertal testis: does it live up to its promises?. Radiology 1997; 203: 227-231
  CrossrefPubMedGoogle Scholar
• 70 Moschouris H, Stamatiou K, Lampropoulou E. et al. Imaging of the acute scrotum; is there a place for contrast-enhanced ultrasonography?. Int Braz J Urol 2009; 35: 702-705
  PubMedGoogle Scholar
• 71 Yusuf T, Sellars ME, Kooiman GG. et al. Global testicular infarction in the presence of epididymitis. Clinical features, appearances on grayscale, color Doppler, and contrat-enhanced sonography, and histologic correlation. J Ultrasound Med 2013; 32: 175-180
  CrossrefPubMedGoogle Scholar
• 72 Bilagi P, Sriprasad S, Clarke JL. et al. Clinical and ultrasound features of segmental testicular infarction: Six-year experience from a single centre. Eur Radiol 2007; 17: 2810-2818
  CrossrefPubMedGoogle Scholar
• 73 Fernandez-Perez GC, Tardaguila FM, Velasco M. et al. Radiologic Findings of Segmental Testicular Infarction. Am J Roentgenol 2005; 184: 1587-1593
  CrossrefPubMedGoogle Scholar
• 74 Sriprasad SI, Kooiman GG, Muir GH. et al. Acute sgmental testicular infarction: differentiation from tumour using high frequency colour Doppler ultrasound. Br J Radiol 2001; 74: 965-967
  CrossrefPubMedGoogle Scholar
• 75 Bertolotto M, Derchi LE, Sidhu PS. et al. Acute segmental testicular infarction at contrast-enhanced ultrasound: early features and changes during follow-up. Am J Roentgenol 2011; 196: 834-841
  CrossrefPubMedGoogle Scholar
• 76 Lung PF, Jaffer OS, Sellars ME. et al. Contrast enhanced ultrasound (CEUS) in the evaluation of focal testicular complications secondary to epidiymitis. Am J Roentgenol 2012; 199: W345-W354
  CrossrefPubMedGoogle Scholar
• 77 Patel K, Huang DY, Sidhu PS. Metachronous Bilateral Segmental Testicular Infarction: Multi-parametric Ultrasound imaging with Grey-scale Ultrasound, Doppler Ultrasound, Contrast Enhanced Ultrasound (CEUS) and Real-time Tissue Elastography (RTE). J Ultrasound 2014; 17: 233-238
  CrossrefPubMedGoogle Scholar
• 78 Bhatt S, Dogra VS. Role of US in testicular and scrotal trauma. Radiographics 2008; 28: 1617-1629
  CrossrefPubMedGoogle Scholar
• 79 Valentino M, Bertolotto M, Derchi L. et al. Role of contrast enhanced ultrasound in acute scrotal diseases. Eur Radiol 2011; 21: 1831-1840
  CrossrefPubMedGoogle Scholar
• 80 Lobianco R, Regine R, De Siero M. et al. Contrast-enhanced sonography in blunt scrotal trauma. J Ultrasound 2011; 14: 188-195
  CrossrefPubMedGoogle Scholar
• 81 Hedayati V, Sellars ME, Sharma DM. et al. Contrast-enhanced ultrasound in testicular trauma: role in directing exploration, debridement and organ salvage. Br J Radiol 2012; 85: e65-e68
  CrossrefPubMedGoogle Scholar
• 82 Yusuf GT, Konstantatou E, Sellars ME. et al. Multiparametric sonography of testicular hematomas. Features on grayscale, color Doppler, and contrast-enhanced sonography and strain elastography. J Ultrasound Med 2015; 34: 1319-1328
  CrossrefPubMedGoogle Scholar
• 83 Rafailidis V, Robbie H, Konstantatou E. et al. Sonographic imaging of extra-testicular focal lesions: comparison of grey-scale, colour Doppler and contrast-enhanced ultrasound. Ultrasound 2016; 24: 23-33
  CrossrefPubMedGoogle Scholar
• 84 Horstman WG, Melson GL, Middleton WD. et al. Testicular tumours: Findings with color Doppler US. Radiology 1992; 185: 733-737
  CrossrefPubMedGoogle Scholar
• 85 Bhatt S, Rubens DJ, Dogra VS. Sonography of benign intrascrotal lesions. Ultrasound Q 2006; 22: 121-136
  CrossrefPubMedGoogle Scholar
• 86 Winter TC. There is a mass in the scrotum – what does it mean? Evaluation of the scrotal mass. Ultrasound Q 2009; 25: 195-205
  CrossrefPubMedGoogle Scholar
• 87 Patel K, Sellars ME, Clarke JL. et al. Features of testicular epidermoid cysts on contrast enhanced ultrasound and real time elastography. J Ultrasound Med 2012; 31: 1115-1122
  PubMedGoogle Scholar
• 88 Huang DY, Sidhu PS. Focal testicular lesions: colour Doppler ultrasound, contrast-enhanced ultrasound and tissue elastography as adjuvants to the diagnosis. Br J Radiol 2012; 85: S41-S53
  CrossrefPubMedGoogle Scholar
• 89 Lock G, Schmidt C, Helmich F. et al. Early experience with contrast enhanced ultrasound in the diagnosis of testicular masses; a feasibility study. Urology 2011; 77: 1049-1053
  CrossrefPubMedGoogle Scholar
• 90 Isidori AM, Pozza C, Gianfrilli D. et al. Differential diagnosis of nonpalpable testicular lesions: qualitative and quantitave contrast-enhanced US of benign and malignant testicular tumors. Radiology 2014; 273: 606-618
  CrossrefPubMedGoogle Scholar
• 91 Drudi FM, Maghella F, Martino G. et al. Detection of small testicular masses in monorchid patients using US, CPDUS, CEUS and US-guided biopsy. J Ultrasound 2016; 19: 25-28
  CrossrefPubMedGoogle Scholar
• 92 Drudi FM, Valentino M, Bertolotto M. et al. CEUS time intensity curves in the differentiation between Leydig cell carcinoma nd seminoma: a multicenter study. Ultraschall in Med 2016; 37: 201-205
  Article in Thieme ConnectPubMedGoogle Scholar
• 93 Lock G, Schoder C, Schmidt C. et al. Contrast-enhanced ultrasound and real time elastography for the diagnosis of benign leydig cell tumors of the testis – a single centre report on 13 cases. Ultraschall in Med 2014; 35: 534-539
  Article in Thieme ConnectPubMedGoogle Scholar
• 94 Gaur S, Bhatt S, Derchi L. et al. Spontaneous intratesticular hemorrhage. Two case descriptions and a brief review of the literature. J Ultrasound Med 2011; 30: 101-104
  CrossrefPubMedGoogle Scholar
• 95 Bertolotto M, Cantisani V, Valentino M. et al. Pitfalls in Imaging for Acute Scrotal Pathology. Semin in Roentgenol 2016; 51: 60-69
  PubMedGoogle Scholar
• 96 Russo G, Mischi M, Scheepens W. et al. Angiogenesis in prostate cancer: onset, progression and imaging. BJU International 2012; 110: E794-E808
  CrossrefPubMedGoogle Scholar
• 97 Mitterberger MJ, Aigner F, Horninger W. et al. Comparative efficiency of contrast-enhanced colour Doppler ultrasound targeted versus systematic biopsy for prostate cancer detection. Eur Radiol 2010; 20: 2791-2796
  CrossrefPubMedGoogle Scholar
• 98 Aigner F, Pallwein L, Mitterberger M. et al. Contrast-enhanced ultrasonography using cadence-contrast pulse sequencing technology for targeted biopsy of the prostate. BJU International 2009; 103: 458-463
  CrossrefPubMedGoogle Scholar
• 99 Sano F, Terao H, Kawahara T. et al. Contrast-enhanced ultrasonography of the prostate: various imaging findings that indicate prostate cancer. BJU International 2011; 107: 1404-1410
  CrossrefPubMedGoogle Scholar
• 100 Strazdina A, Krumina G, Sperga M. The value and limitations of contrast-enhanced ultrasound in detection of prostate cancer. Anticancer Res 2011; 31: 1421-1426
  PubMedGoogle Scholar
• 101 Sano F, Uemura H. The Utility and Limitations of Contrast-Enhanced Ultrasound for the Diagnosis and Treatment of Prostate Cancer. Sensors (Basel) 2015; 15: 4947-4957
  CrossrefPubMedGoogle Scholar
• 102 Smeenge M, Barentsz J, Cosgrove D. et al. Role of transrectal ultrasonography (TRUS) in focal therapy of prostate cancer: report from a Consensus Panel. BJU International 2012; 110: 942-948
  CrossrefPubMedGoogle Scholar
• 103 Schalk SG, Demi L, Smeenge M. et al. 4-D spatiotemporal analysis of ultrasound contrast agent dispersion for prostate cancer localization: a feasibility study. IEEE Trans UltrasonFerroelectri Freq Control 2015; 62: 839-851
  PubMedGoogle Scholar
• 104 Postema AW, Frinking PJA, Smeenge M. et al. Dynamic contrast-enhanced ultrasound parametric imaging for the detection of prostate cancer. BJU International 2016; 117: 598-603
  CrossrefPubMedGoogle Scholar
• 105 Postema A, Mischi M, de la Rosette J. et al. Multiparametric ultrasound in the detection of prostate cancer: a systematic review. World J Urol 2015; 33: 1651-1659
  CrossrefPubMedGoogle Scholar
• 106 Harvey CJ, Sidhu PS, Bachmann-Nielsen M. Contrast-enhanced ultrasound in renal transplants: applications and future directions. Ultraschall in Med 2013; 34: 319-321
  Article in Thieme ConnectPubMedGoogle Scholar
• 107 McArthur C, Baxter GM. Current and potential renal applications of contrast-enhanced ultrasound. Clin Radiol 2012; 67: 909-922
  CrossrefPubMedGoogle Scholar
• 108 Girometti R, Stocca E, Granata A. et al. Impact of contrast-enhanced ultrasound in patients with renal function impairment. World J Radiol 2017; 28: 10-16
  Google Scholar
• 109 Granata A, Andrulli S, Fiorini F. et al. Diagnosis of acute pyelonephritis by contrast-enhanced ultrasonography in kidney transplant patients. Nephrol Dial Transplant 2011; 26: 715-720
  CrossrefPubMedGoogle Scholar
• 110 Stenberg B, Talbot D, Khurram M. et al. A new technique for assessing renal transplant perfusion preoperatively using contrast-enhanced ultrasound (CEUS) and three-dimensional ultrasound (3DUS) – a porcine modelpilot study. Ultraschall in Med 2011; 32: E8-E13
  Article in Thieme ConnectPubMedGoogle Scholar
• 111 Stenberg B, Chandler C, Wyrley-Birch H. et al. Post-Operative 3-Dimensional Contrast-Enhanced Ultrasound (CEUS) Versus Tc99m-DTPA in the Detection of Post-Surgical Perfusion Defects in Kidney Transplants: Preliminary Findings. Ultraschall in Med 2014; 35: 273-278
  Article in Thieme ConnectPubMedGoogle Scholar
• 112 Fernandez CP, Ripolles T, Martinez MJ. et al. Diagnosis of acute cortical necrosis in renal transplantation by contrast-enhanced ultrasound: a preliminary experience. Ultraschall in Med 2013; 34: 338-342
  PubMedGoogle Scholar
• 113 Kay DH, Mazonakis M, Geddes C. et al. Ultrasonic microbubble contrast agents and the transplant kidney. Clin Radiol 2009; 64: 1081-1087
  CrossrefPubMedGoogle Scholar
• 114 Jin Y, Yang C, Wu S. et al. A novel simple onoinvasive index to predict renal transplant acute rejection by contrast-enhanced ultrasonography. Transplantation 2015; 99: 636-641
  CrossrefPubMedGoogle Scholar
• 115 Tranquart F, Mercier L, Frinking P. et al. Perfusion quantification in contrast-enhanced ultrasound (CEUS) ready for research projects and routine clinical use. Ultraschall in Med 2012; 33: S31-S38
  Article in Thieme ConnectPubMedGoogle Scholar
• 116 Wang X, Yu Z, Guo R. et al. Assessment of postoperative perfusion with contrast-enhanced ultrasonography in kidney transplantation. Int J Clin Exp Med 2015; 8: 18399-18405
  PubMedGoogle Scholar
• 117 Dietrich CF, Wehrmann T, Hoffmann C. et al. Detection of the Adrenal Glands by Endoscopic or Transabdominal Ultrasound. Endoscopy 1997; 29: 859-864
  Article in Thieme ConnectPubMedGoogle Scholar
• 118 Trojan J, Schwarz W, Sarrazin C. et al. Role of Ultrasonography in the Detection of Small Adrenal Masses. Ultraschall in Med 2002; 23: 96-100
  Article in Thieme ConnectPubMedGoogle Scholar
• 119 Friedrich-Rust M, Schneider G, Bohle RM. et al. Contrast-enhanced sonography of adrenal masses; differentiation of adenomas and nonadenomatous lesions. Am J Roentgenol 2008; 191: 1852-1860
  CrossrefPubMedGoogle Scholar
• 120 Friedrich-Rust M, Glasemann T, Polta A. et al. Differentiation between benign and malignant adrenal mass using contrast-enhanced ultrasound. Ultraschall in Medizin 2011; 32: 460-471
  PubMedGoogle Scholar
• 121 Dietrich CF, Ignee A, Barreiros AP. et al. Contrast-enhanced ultrasound for imaging of adrenal masses. Ultraschall in Med 2010; 31: 163-168
  Article in Thieme ConnectPubMedGoogle Scholar
• 122 Slapa RZ, Kasperlik-Zaluska AA, Migda B. et al. Application of parametric ultrasound contrast agent perfusion studies for differentiation of hyperplastic adrenal nodules from adenomas – Initial study. Eur J Radiol 2015; 84: 1432-1435
  CrossrefPubMedGoogle Scholar
• 123 Al Bunni F, Deganello A, Sellars ME. et al. Contrast-enhanced ultrasound (CEUS) appearances of an adrenal phaeochromocytoma in a child with Von Hippel-Lindau disease. J Ultrasound 2014; 17: 307-311
  CrossrefPubMedGoogle Scholar
• 124 Schreiber-Dietrich D, Buchhorn R, Dietrich CF. Blickdiagnose Nebennierentumor (Phächromozytom). Pädiat Prax 2014; 83: 239-248
  PubMedGoogle Scholar
• 125 Denbow ML, Welsh AW, Taylor MJ. et al. Twin fetuses: intravascular microbubble US contrast agent administration – early experience. Radiology 2000; 214: 724-728
  CrossrefPubMedGoogle Scholar
• 126 Denbow ML, Blomley MJK, Cosgrove DO. et al. Ultrasound microbubble contrast angiography in monochorionic twin fetuses. Lancet 1997; 349: 773
  CrossrefPubMedGoogle Scholar
• 127 Song Y, Yang J, Shen K. Preoperative evaluation of endometrial carcinoma by contrast-enhanced ultrasonography. BJOG 2008; 116: 294-298
  PubMedGoogle Scholar
• 128 Testa AC, Ferrandina G, Fruscella E. et al. The Use of Contrasted Transvaginal Sonography in the Diagnosis of Gynecologic Diseases: A Preliminary Study. J Ultrasound Med 2005; 24: 1267-1278
  CrossrefPubMedGoogle Scholar
• 129 Lieng M, Qvigstad E, Dahl GF. et al. Flow differences between endometrial polyps and cancer: a prospective study using intravenous contrast-enhanced transvaginal color flow Doppler and three-dimensional power Doppler ultrasound. Ultrasound Obstet Gynecol 2008; 32: 935-940
  CrossrefPubMedGoogle Scholar
• 130 Dorenberg EJ, Hol PK, Jakobsen J. et al. Improved infarction rates in fibroids after the introduction of contrast-enhanced ultrasound during uterine artery embolization. Acta Radiologica 2012; 53: 34-38
  CrossrefPubMedGoogle Scholar
• 131 Sconfienza LM, Lacelli F, Gandolfo N. et al. Contrast-enhanced ultrasound (CEUS) assessment of superselective uterine fibroid embolization (SUFE): Preliminary experience. J Ultrasound 2008; 11: 158-161
  CrossrefPubMedGoogle Scholar
• 132 Orden MR, Jurvelin JS, Kirkinen PP. Kinetics of a US Contrast Agent in Benign and Malignant Adnexal Tumors. Radiology 2003; 226: 405-410
  CrossrefPubMedGoogle Scholar
• 133 Marret H, Sauget S, Giraudeau B. et al. Contrast-Enhanced Sonography Helps in Discrimination of Benign From Malignant Adnexal Masses. J Ultrasound Med 2004; 23: 1629-1639
  PubMedGoogle Scholar
• 134 Testa AC, Timmerman D, Exacoustos C. et al. The role of CnTI-SonoVue in the diagnosis of ovarian masses with papillary projections: a preliminary study. Ultrasound Obstet Gynecol 2007; 29: 512-516
  CrossrefPubMedGoogle Scholar
• 135 Testa AC, Timmerman D, Van Belle V. et al. Intravenous contrast ultrasound examination using contrast-tuned imaging (CnTI) and the contrast medium SonoVue fro discrimination between benign and malignant adnexal masses with solid components. Ultrasound Obstet Gynecol 2009; 34: 699-710
  CrossrefPubMedGoogle Scholar
• 136 D’Onofrio M, Biagioli E, Gerardi C. et al. Diagnostic performance of contrast-enhanced ultrasound (CEUS) and contrast-enhanced endoscopic ultrasound (ECEUS) for the differentation of pancreatic lesions: a systematic review and meta-analysis. Ultraschall in Med 2014; 35: 515-521
  Article in Thieme ConnectPubMedGoogle Scholar
• 137 D’Onofrio M, Canestrini S, De Robertis R. et al. CEUS of the pancreas: Still research or the standard of care. Eur J Radiol 2015; 84: 1644-1649
  CrossrefPubMedGoogle Scholar
• 138 Dietrich CF, Braden B, Hocke M. et al. Improved characterisation of solitary solid pancreatic tumours using contrast enhanced transabdominal ultrasound. J Cancer Res Clin Oncol 2008; 134: 635-643
  CrossrefPubMedGoogle Scholar
• 139 D’Onofrio M, Megibow AJ, Faccioli N. et al. Comparison of Contrast-Enhanced Sonography and MRI in Displaying Anatomic Features of Cystic Pancreatic Masses. Am J Roentgenol 2007; 189: 1435-1442
  CrossrefPubMedGoogle Scholar
• 140 Fan Z, Li Y, Yan K. et al. Application of contrast-enhanced ultrasound in the diagnosis of solid pancreatic lesionsGÇöA comparison of conventional ultrasound and contrast-enhanced CT. Eur J Radiol 2013; 82: 1385-1390
  CrossrefPubMedGoogle Scholar
• 141 Kitano M, Kudo M, Maekawa K. et al. Dynamic imaging of pancreatic diseases by contrast enhanced coded phase inversion harmonic ultrasonography. Gut 2004; 53: 854-859
  CrossrefPubMedGoogle Scholar
• 142 D’Onofrio M, Malago R, Zamboni G. et al. Contrast-enhanced ultrasonography better identifies pancreatic tumor vascularization than helical CT. Pancreatology 2005; 5: 398-402
  CrossrefPubMedGoogle Scholar
• 143 Faccioli N, D’Onofrio M, Malaga R. et al. Resectable Pancreatic Adenocarcinoma: Depiction of Tumoral Margins at Contrast-Enhanced Ultrasonography. Pancreas 2008; 37: 265-268
  CrossrefPubMedGoogle Scholar
• 144 Grossjohann HS, Rappeport ED, Jensen C. et al. Usefulness of contrast-enhanced transabdominal ultrasound for tumor classification and tumor staging in the pancreatic head. Scand j Gastroenterol 2010; 45: 917-924
  CrossrefPubMedGoogle Scholar
• 145 D’Onofrio M, Zamboni G, Tognolini A. et al. Mass-forming pancreatitis: Value of contrast-enhanced ultrasonography. World J Gastroenterol 2006; 12: 4181-4184
  CrossrefPubMedGoogle Scholar
• 146 Kersting S, Konopke R, Kersting F. et al. Quantitative Perfusion Analysis of Transabdominal Contrast-Enhanced Ultrasonography of Pancreatic Masses and Carcinomas. Gastroenterol 2009; 137: 1903-1911
  CrossrefPubMedGoogle Scholar
• 147 Numata K, Ozawa Y, Kobayashi N. et al. Contrast-enhanced sonography of pancreatic carcinoma; correlations with pathological findings. J Gastroenterol 2005; 40: 631-640
  CrossrefPubMedGoogle Scholar
• 148 D’Onofrio M, Barbi E, Dietrich CF. et al. Pancreatic multicenter ultrasound study (PAMUS). Eur J Radiol 2012; 81: 630-638
  CrossrefPubMedGoogle Scholar
• 149 Serra C, Felicani C, Mazzotta E. et al. Contrast-Enhanced Ultrasound in the Differential Diagnosis of Exocrine Versus Neuroendocrine Pancreatic Tumors. Pancreas 2013; 42: 871-877
  CrossrefPubMedGoogle Scholar
• 150 Wang Y, Yan K, Fan Z. et al. Contrast-Enhanced Ultrasonography of Pancreatic Carcinoma: Correlation with Pathologic Findings. Ultrasound Med Biol 2016; 42: 891-898
  CrossrefPubMedGoogle Scholar
• 151 D’Onofrio M, Crosara S, Signorini M. et al. Comparison between CT and CEUS in the Diagnosis of Pancreatic Adenocarcinoma. Ultraschall in Med 2013; 34: 377-381
  Article in Thieme ConnectPubMedGoogle Scholar
• 152 Bernatik T, Seitz K, Blang W. et al. Unclear focal liver lesions in contrast-enhanced ultrasonography – lessons to be learned from the DEGUM multicenter study for the characterization of liver tumors. Ultraschall in Med 2010; 31: 587-596
  PubMedGoogle Scholar
• 153 Sidhu PS, Brabrand K, Cantisani V. et al. EFSUMB Guidelines on Interventional Ultrasound (INVUS) Part II Diagnostic Ultrasound-Guided Interventional Procedures (Short Version). Ultraschall in Med 2016; 36: 566-580
  Article in Thieme ConnectPubMedGoogle Scholar
• 154 Wei Y, Yu XL, Liang P. et al. Guiding and Controlling Percutaneous Pancreas Biopsies with Contrast-Enhanced Ultrasound: Target Lesions Are Not Localized on B-Mode Ultrasound. Ultrasound Med Biol 2015; 41: 1561-1569
  CrossrefPubMedGoogle Scholar
• 155 Tawada K, Yamaguchi T, Kobayashi A. et al. Changes in Tumor Vascularity Depicted by Contrast-Enhanced Ultrasonography as a Predictor of Chemotherapeutic Effect in Patients With Unresectable Pancreatic Cancer. Pancreas 2009; 38: 30-35
  CrossrefPubMedGoogle Scholar
• 156 Kobayashi A, Yamaguchi T, Ishihara T. et al. Evaluation of vascular signal in pancreatic ductal carcinoma using contrast enhanced ultrasonography: effect of systemic chemotherapy. Gut 2005; 54: 1047
  CrossrefPubMedGoogle Scholar
• 157 D’Onofrio M, Mansueto G, Falconi M. et al. Neuroendocrine pancreatic tumor. Abdom Imaging 2004; 29: 246-258
  CrossrefPubMedGoogle Scholar
• 158 Malago R, D’Onofrio M, Zamboni GA. et al. Contrast-Enhanced Sonography of Nonfunctioning Pancreatic Neuroendocrine Tumors. Am J Roentgenol 2009; 192: 424-430
  CrossrefPubMedGoogle Scholar
• 159 Falconi M, Bartsch DF, Eriksson B. et al. ENETS consesus guidelines for the management of patients with digestive neuroendocrine neoplasms of the digestive system: well-differentiated pancreatic non-functioning tumors. Neuroendocrinology 2012; 95: 120-134
  CrossrefPubMedGoogle Scholar
• 160 Fan Z, Yan K, Wang Y. et al. Application of Contrast-Enhanced Ultrasound in Cystic Pancreatic Lesions Using a Simplified Classification Diagnostic Criterion. Biomed Res Int 2015; 2015: 974621
  PubMedGoogle Scholar
• 161 Vasile TA, Socaciu M, Stanluga R. et al. Added value of intravenous contrast-enhanced ultrasoundfor characterization of cystic pancreatic masses: a prospective study on 37 patients. Med Ultrason 2012; 14: 108-114
  PubMedGoogle Scholar
• 162 Rickes S, Wermke W. Differentiation of cystic pancreatic neoplasms and pseudocysts by conventional and echo-enhanced ultrasound. J Gastroenterol Hepatol 2004; 19: 761-766
  CrossrefPubMedGoogle Scholar
• 163 Itoh T, Hirooka Y, Itoh A. et al. Usefulness of Contrast-Enhanced Transabdominal Ultrasonography in the Diagnosis of Intraductal Papillary Mucinous Tumors of the Pancreas. Am J Gastroenterol 2005; 100: 144-152
  CrossrefPubMedGoogle Scholar
• 164 Pezzilli R, Serra C, Calculli L. et al. Three-Dimensional Contrast-Enhanced Ultrasonography of Intraductal Papillary Mucinous Neoplasms of the Pancreas: A Comparison With Magnetic Resonance Imaging. Pancreas 2013; 42: 1164-1168
  CrossrefPubMedGoogle Scholar
• 165 Buscarini E, Pezzilli R, Cannizzaro R. et al. Italian consensus guidelines for the diagnostic work-up and follow-up of cystic pancreatic neoplasms. Dig Liver Dis 2014; 46: 479-493
  CrossrefPubMedGoogle Scholar
• 166 D’Onofrio M, Gallotti A, Pozzi Mucelli R. Imaging techniques in pancreatic tumors. Expert Rev Med Devices 2010; 7: 257-273
  CrossrefPubMedGoogle Scholar
• 167 Ripolles T, Martinez MJ, Lopez E. et al. Contrast-enhanced ultrasound in the staging of acute pancreatitis. Eur Radiol 2010; 20: 2518-2523
  CrossrefPubMedGoogle Scholar
• 168 Ardelean M, Sirli R, Sporea I. et al. Contrast enhanced ultrasound in the pathology of the pancreas. A monocentric experience. Med Ultrason 2014; 16: 325-331
  PubMedGoogle Scholar
• 169 Vitali F, Pfeifer L, Janson C. et al. Quantitative perfusion analysis in pancreatic contrast enhanced ultrasound (DCE-US): a promising tool for the differentiation between autoimmune pancreatitis and pancreatic cancer. Z Gastroenterol 2015; 53: 1175-1181
  Article in Thieme ConnectPubMedGoogle Scholar
• 170 Mauch M, Blank W, Kunze G. et al. Importance of Abdominal Ultrasound in 17 Patients with Histologically Confirmed Autoimmune Pancreatitis (AIP). Ultraschall in Med 2015; 36: 248-254
  Article in Thieme ConnectPubMedGoogle Scholar
• 171 Ito T, Kenmochi T, Nishikawa T. et al. A Novel Screening Test for Detecting Graft Thrombosis After Pancreatic Transplantation Using Contrast-enhanced Ultrasonography With Sonazoid. Transplant Proc 2014; 46: 1917-1919
  CrossrefPubMedGoogle Scholar
• 172 Rennert J, Farkas S, Georgieva M. et al. Identification of early complications following pancreas and renal transplantation using contrast enhanced ultrasound (CEUS) – first results. Clin Hemorheol Microcirc 2014; 58: 343-352
  PubMedGoogle Scholar
• 173 Aboutaleb E, Leen E, Hakim N. Assessment of Viability of the Pancreas for Transplantation Using Contrast-Enhanced Ultrasound. Transplant Proc 2011; 43: 418-421
  CrossrefPubMedGoogle Scholar
• 174 Kersting S, Ludwig S, Ehehalt F. et al. Contrast-Enhanced Ultrasonography in Pancreas Transplantation. Transplantation 2013; 95: 209-214
  CrossrefPubMedGoogle Scholar
• 175 Nylund K, hausken T, Gilja OH. Ultrasound and inflammatory bowel disease. Ultrasound Q 2010; 26: 3-15
  CrossrefPubMedGoogle Scholar
• 176 Gorce JM, Arditi D, Schneider M. IInfluence of bubble size distribution on the echogenicity of ultrasound contrast agents: a study of SonoVue. Invest Radiol 2000; 35: 661-671
  CrossrefPubMedGoogle Scholar
• 177 Plikat K, Klebi F, Buchner C. et al. Evaluation of intestinal hyperaemia in inflammed bowel by high resolution contarst harmonic imaging (CHI). Ultraschall in Med 2000; 25: 257-262
  Article in Thieme ConnectPubMedGoogle Scholar
• 178 Girlich C, Jung EM, Iesalnieks I. et al. Quantitative assessment of bowel wall vascularisation in Crohn’s disease with contrast-enhanced ultrasound and perfusion analysis. Clin Hemorheol Microcirc 2009; 43: 141-148
  PubMedGoogle Scholar
• 179 Kratzer W, Schmidt SA, Mittrach C. et al. Contrast-enhanced wideband harmonic imaging ultrasound (SonoVue): a new technique for quantifying bowel wall vascularity in Crohn’s disease. Scand j Gastroenterol 2005; 40: 985-991
  CrossrefPubMedGoogle Scholar
• 180 De Pascale A, Garofalo G, Perna M. et al. Contrast-enhanced ultrasonography in Crohn’s disease. Radiol Med 2006; 111: 539-550
  CrossrefPubMedGoogle Scholar
• 181 De Franco A, MArzo M, Felice C. et al. Ileal Crohn’s disease: CEUS determination of activity. Abdom Imaging 2012; 37: 359-368
  CrossrefPubMedGoogle Scholar
• 182 Bialecki M, Bialecka A, Laskowska K. et al. Contrast-enhanced ultrasonography in Crohn’s disease diagnostic. Hepatogastroenterol 2015; 62: 927-932
  PubMedGoogle Scholar
• 183 Roccarina D, Garcovich M, Ainora ME. et al. Diagnosis of bowel diseases: the role of imaging and ultrasonography. World J Gastroenterol 2013; 19: 2144-2153
  CrossrefPubMedGoogle Scholar
• 184 Chiorean L, Schreiber-Dietrich D, Braden B. et al. Ultrasonographic imaging of inflammatory bowel disease in pediatric patients. World J Gastroenterol 2015; 21: 5231-5241
  CrossrefPubMedGoogle Scholar
• 185 Schreyer AG, Finkenzeller T, Gossmann H. et al. Microcirculation and perfusion with contrast enhanced ultrasound (CEUS) in Crohn’s disease: first results with linear contrast harmonic imaging (CHI). Clin Hemorheol Microcirc 2008; 40: 143-155
  PubMedGoogle Scholar
• 186 Pauls S, Gabelmann A, Schmidt SA. et al. Evaluting bowel wall vascularity in Crohn’s disease: a comparison of dynamic MRI and wideband harmonic imaging contrat-enhanced low MI ultrasound. Eur Radiol 2006; 16: 2410-2417
  CrossrefPubMedGoogle Scholar
• 187 Malago R, D’Onofrio M, Mantovani W. et al. Contrast-enhanced ultrasonography (CEUS) vs. MRI of the small bowel in the evaluation of Crohn’s disease activity. La Radiologia Medica 2012; 117: 268-281
  CrossrefPubMedGoogle Scholar
• 188 Badea R, Socaciu M, Ciobanu L. et al. Contrast-enhanced ultrasonography (CESU) for the evaluation of the inflammation of the digestive tract wall. J Gastrointestin Liver Dis 2010; 19: 439-444
  PubMedGoogle Scholar
• 189 Robotti D, Cammarota T, Debani P. et al. Activity of Crohn disease: value of Color-Power-Doppler and contrast-enhanced ultrasonography. Abdo Imaging 2004; 29: 648-652
  PubMedGoogle Scholar
• 190 Serra C, Menozzi G, Labate AMM. et al. Ultrasound assessment of vascularization of the thickened terminal ileum wall in Crohn’s disease patients using a low-mechanical index real-time scanning technique with a second generation ultrasound contrast agent. Eur J Radiol 2007; 62: 114-121
  CrossrefPubMedGoogle Scholar
• 191 Migaleddu V, Scanu AM, Quaia E. et al. Contrast-Enhanced Ultrasonographic Evaluation of Inflammatory Activity in Crohn’s Disease. Gastroenterology 2009; 137: 43-52
  CrossrefPubMedGoogle Scholar
• 192 Girlich C, Schacherer D, Jung EM. et al. Comparison between quantitative assessment of bowel wall vascularization by contrast-enhanced ultrasound and results of histopathological scoring in ulcerative colitis. Int J Colorectal Dis 2012; 27: 193-198
  CrossrefPubMedGoogle Scholar
• 193 Ripolles T, Martinez MJ, Paredes JM. et al. Crohn Disease: Correlation of Findings at Contrast-enhanced US with Severity at Endoscopy. Radiology 2009; 253: 241-248
  CrossrefPubMedGoogle Scholar
• 194 Girlich C, Jung EM, Huber E. et al. Comparison between Preoperative Quantitative Assessment of Bowel Wall Vascularization by Contrast-Enhanced Ultrasound and Operative Macroscopic Findings and Results of Histopathological Scoring in Crohn’s Disease. Ultraschall in Med 2011; 32: 154-159
  Article in Thieme ConnectPubMedGoogle Scholar
• 195 Romanini L, Passamonti M, Navarria M. et al. Quantitative analysis of contrast-enhanced ultrasonography of the bowel wall can predict disease activity in inflammatory bowel disease. Eur J Radiol 2014; 83: 1317-1323
  CrossrefPubMedGoogle Scholar
• 196 Saevik F, Nylund K, Hausken T. et al. Bowel Perfusion Measured with Dynamic Contrast-enhanced Ultrasound Predicts Treatment Outcome in Patients with Crohn’s Disease. Inflamm Bowel Dis 2014; 20: 2029-2037
  CrossrefPubMedGoogle Scholar
• 197 Guidi L, De Franco A, De Vitis I. et al. Contrast-enhanced ultrasonography with SonoVue after infliximab therapy in Crohn’s disease. Eur Rev Med Pharmacol Sci 2006; 10: 23-26
  PubMedGoogle Scholar
• 198 Quaia E, Migaleddu V, Baratella E. et al. The diagnostic value of small bowel wall vascularity after sulfur hexafluoride-filled microbubble injection in patients with Crohn’s disease. Correlation with the therapeutic effectiveness of specific anti-inflammatory treatment. Eur J Radiol 2009; 69: 438-444
  CrossrefPubMedGoogle Scholar
• 199 Paredes JM, Ripolles T, Cortis X. et al. Contrast-enhanced ultrasonography: Usefulness in the assessment of postoperative recurrence of Crohn’s disease. J Crohns Colitis 2013; 7: 192-201
  CrossrefPubMedGoogle Scholar
• 200 Serafin Z, Bialécki M, Bialécka A. et al. Contrast-enhanced Ultrasound for Detection of Crohn’s Disease Activity: Systematic Review and Meta-analysis. J Crohns Colitis 2016; 10: 354-362
  CrossrefPubMedGoogle Scholar
• 201 Ma X, Li Y, Jia H. et al. Contrast-Enhanced Ultrasound in the Diagnosis of Patients Suspected of Having Active Crohn’s Disease: Meta-analysis. Ultrasound Med Biol 2015; 41: 659-668
  CrossrefPubMedGoogle Scholar
• 202 Kratzer W, von Tirpitz C, Mason R. et al. Contrast-Enhanced Power Doppler Sonography of the Intestinal Wall in the Differentiation of Hypervascularized and Hypovascularized Intestinal Obstructions in Patients With Crohn’s Disease. J Ultrasound Med 2002; 21: 149-157
  CrossrefPubMedGoogle Scholar
• 203 Schirin-Sokhan R, Winograd R, Tischendorf S. et al. Assessment of Inflammatory and Fibrotic Stenoses in Patients with Crohns Disease Using Contrast-Enhanced Ultrasound and Computerized Algorithm: A Pilot Study. Digestion 2011; 83: 263-268
  CrossrefPubMedGoogle Scholar
• 204 Nylund K, Jirik R, Mezl M. et al. Quantitative Contrast-Enhanced Ultrasound Comparison Between Inflammatory and Fibrotic Lesions in Patients with Crohn’s Disease. Ultrasound Med Biol 2013; 39: 1197-1206
  CrossrefPubMedGoogle Scholar
• 205 Kinkel H, Michels G, Jaspers N. Ultraschall zur Diagnostik und Verlaufskontrolle chronisch-entzundlicher Darmerkrankungen. Dtsch Med Wochenschr 2015; 140: 46-50
  Article in Thieme ConnectPubMedGoogle Scholar
• 206 Schlottmann K, Kratzer W, Scholmerich J. Doppler ultrasound and intravenous contrast agents in gastrointestinal tract disorders: current role and future implications. Eur J Gastroenterol Hepatol 2005; 17: 263-275
  CrossrefPubMedGoogle Scholar
• 207 Ripolles T, Martinez-Perez MJ, Paredes JM. et al. Contrast-enhanced ultrasound in the differentiation between phlegmon and abscess in Crohn’s disease and other abdominal conditions. Eur J Radiol 2013; 82: e525-e531
  CrossrefPubMedGoogle Scholar
• 208 Henrich W, Meckies J, Friedmann W. Demonstration of a recto-vaginal fistula with ultrasound contrast medium Ehovist. Ultrasound Obstet Gynecol 2000; 15: 148-149
  CrossrefPubMedGoogle Scholar
• 209 Heinzmann A, Muller T, Leitlein J. et al. Endocavity contrast enhanced ultrasound (CEUS) – work in progress. Ultraschall in Med 2012; 33: 76-84
  Article in Thieme ConnectPubMedGoogle Scholar
• 210 Ignee A, Cui X, Schuessler G. et al. Percutaneous transhepatic cholangiography and drainage using extravascular contrast enhanced ultrasound. Z Gastroenterol 2015; 53: 385-390
  Article in Thieme ConnectPubMedGoogle Scholar
• 211 Nonnenmacher S, Muller T, Haug U. et al. Nachweis einer iliacoenteralen Fistel als seltene Ursache einer unteren gastrointestinalen Blutung mittels Kontrastmittelsonografie (CEUS). Ultraschall in Med 2013; 34: 478-480
  Article in Thieme ConnectPubMedGoogle Scholar
• 212 Gao JM, Tang SS, Fu W. et al. Signet-ring cell carcinoma of ampulla of Vater: Contrast-enhanced ultrasound findings. World J Gastroenterol 2009; 15: 888-891
  CrossrefPubMedGoogle Scholar
• 213 Wang Y, Li L, Wang YX. et al. Time-Intensity Curve Parameters in Rectal Cancer Measured Using Endorectal Ultrasonography with Sterile Coupling Gels Filling the Rectum: Correlations with Tumor Angiogenesis and Clinicopathological Features. Biomed Res Int 2014; 2014: 587806
  PubMedGoogle Scholar
• 214 Stock K, Hann von Weyhern C, Slotta-Huspenina J. et al. Microcirculation of subepithelial gastric tumors using contras-enhanced ultrasoun. Clin Hemorheol Microcirc 2010; 45: 225-232
  PubMedGoogle Scholar
• 215 Dorffel Y, Wermke W. Neuroendocrine Tumors: Characterization with Contrast-Enhanced Ultrasonography. Ultraschall in Med 2008; 29: 506-514
  Article in Thieme ConnectPubMedGoogle Scholar
• 216 Cao BS, Li L, Li YX. et al. Assessment of abnormal bowel perfusion using contrast-enhanced ultrasonography after small bowel transplantation: A case report. J Clin Ultrasound 2013; 41: 370-272
  CrossrefPubMedGoogle Scholar
• 217 Benedetti E, Bruno B, McDonald GB. et al. Prospective qualitative and quantitative non-invasive evaluation of intestinal acute GVHD by contrast-enhanced ultrasound sonography. Bone Marrow Transplant 2013; 48: 1421-1428
  CrossrefPubMedGoogle Scholar
• 218 Schreyer AG, Landfried K, Zorger N. et al. Transmural penetration of intravenously applied microbubbles during contrast-enhanced ultrasound as a new diagnostic feature in patients with GVHD of the bowel. Bone Marrow Transplant 2011; 46: 1006-1011
  CrossrefPubMedGoogle Scholar
• 219 Bachmann C, Klibanov AL, Olson TS. et al. Targeting Mucosal Addressin Cellular Adhesion Molecule (MAdCAM)-1 to Noninvasively Image Experimental Crohns Disease. Gastroenterology 2006; 130: 8-16
  CrossrefPubMedGoogle Scholar
• 220 Zink F, Kratzer W, Schmidt S. et al. Comparison of Two High-End Ultrasound Systems for Contrast-Enhanced Ultrasound Quantification of Mural Microvascularity in Crohn’s Disease. Ultraschall in Med 2016; 37: 74-81
  Article in Thieme ConnectPubMedGoogle Scholar
• 221 Neesse A, Huth J, Kunsch S. et al. Contrast-enhanced ultrasound pattern of splenic metastases. A retrospective study in 32 patients. Ultraschall in Medizin 2010; 31: 264-269
  PubMedGoogle Scholar
• 222 Catalano O, Lobianco R, Sandomenico F. et al. Real-time contrast enhanced ultrasound of the spleen: examination technique and preliminary clinical experience. Radiol Med 2003; 106: 338-356
  PubMedGoogle Scholar
• 223 Lim AKP, Patel N, Eckersley RJ. et al. Evidence for Spleen-specific Uptake of a Microbubble Contrast Agent: A Quantitative Study in Healthy Volunteers. Radiology 2004; 231: 785-788
  CrossrefPubMedGoogle Scholar
• 224 Catalano O, Cusati B, Nunziata A. et al. Real-time, contrast-specific sonography imaging of acute splenic disorders: a pictorial review. Emerg Radiol 2004; 11: 15-21
  PubMedGoogle Scholar
• 225 Catalano O, Sandomenico F, Vallone G. et al. Contrast-enhanced sonography of the spleen. Semin Ultrasound CT MR 2006; 27: 426-433
  CrossrefPubMedGoogle Scholar
• 226 Omar A, Freeman S. Contrast-enhanced ultrasound of teh spleen. Ultrasound 2016; 24: 41-49
  CrossrefPubMedGoogle Scholar
• 227 Catalano O, Sandomenico F, Matarazzo I. et al. Contrast-Enhanced Sonography of the Spleen. Am J Roentgenol 2005; 184: 1150-1156
  CrossrefPubMedGoogle Scholar
• 228 Peddu P, Shah M, Sidhu PS. Splenic abnormalities: a comparative review of ultrasound, microbubble enhanced ultrasound and computed tomography. Clin Radiol 2004; 59: 777-792
  CrossrefPubMedGoogle Scholar
• 229 Stang A, Keles H, Hentschke S. et al. Differentiation of Benign From Malignant Focal Splenic Lesions Using Sulfur Hexafluoride-Filled Microbubble Contrast-Enhanced Pulse-Inversion Sonography. Am J Roentgenol 2009; 193: 709-721
  CrossrefPubMedGoogle Scholar
• 230 Gorg C. The forgotten organ: Contrast enhanced sonography of the spleen. Eur J Radiol 2007; 64: 189-201
  CrossrefPubMedGoogle Scholar
• 231 Gorg C, Graef C, Bert T. Contrast-enhanced sonography for differential diagnosis of an inhomogenous spleen of unknown cause in patients with pain in the left upper quadrant. J Ultrasound Med 2006; 25: 729-734
  CrossrefPubMedGoogle Scholar
• 232 Gorg C, Bert T. Second-Generation Sonographic Contrast Agent for Differential Diagnosis of Perisplenic Lesions. Am J Roentgenol 2006; 186: 621-626
  CrossrefPubMedGoogle Scholar
• 233 Kim SH, Lee JM, Lee JY. et al. Contrast-Enhanced Sonography of Intrapancreatic Accessory Spleen in Six Patients. Am J Roentgenol 2007; 188: 422-428
  CrossrefPubMedGoogle Scholar
• 234 Bertolotto M, Quaia E, Zappetti R. et al. Differential diagnosis between splenic nodules and peritoneal metastases with contrast-enhanced ultrasound based on signal-intensity characteristics during the late phase. Radiol Med 2009; 114: 42-51
  CrossrefPubMedGoogle Scholar
• 235 Li W, Liu G, Wang W. et al. Real-time contrast enhanced ultrasound imaging of focal splenic lesions. Eur J Radiol 2014; 83: 646-653
  CrossrefPubMedGoogle Scholar
• 236 von Herbay A, Barreiros AP, Ignee A. et al. Contrast-enhanced ultrasonography with SonoVue. Differentiation between benign and malignant lesions of the spleen. J Ultrasound Med 2009; 28: 421-434
  CrossrefPubMedGoogle Scholar
• 237 Cai DM, Parajuly SS, Ling WW. et al. Diagnostic value of contrast enhanced ultrasound for splenic artery complications following acute pancreatitis. World J Gastroenterol 2014; 20: 1088-1094
  CrossrefPubMedGoogle Scholar
• 238 Menozzi G, Maccabruni V, Gabbi E. et al. Contrast-enhanced Ultrasound Evaluation of Splenic Embolization in Patients with Definite Left-Sided Infective Endocarditis. Ultrasound Med Biol 2013; 39: 2205-2210
  CrossrefPubMedGoogle Scholar
• 239 Ignee A, Cui X, Hirche T. et al. Percutaneous biopsies of splenic lesions – a clinical and contrast based algorithm. Clin Hemorheol Microcirc 2014; 58: 529-541
  CrossrefPubMedGoogle Scholar
• 240 Chen LW, Chien RN, Yen CL. et al. Splenic tumour: a clinicopathological study. Int J Clin Pract 2004; 58: 924-927
  CrossrefPubMedGoogle Scholar
• 241 Yu X, Yu J, Liang P. et al. Real-time contrast-enhanced ultrasound in diagnosing of focal spleen lesions. Eur J Radiol 2012; 81: 430-436
  CrossrefPubMedGoogle Scholar
• 242 Stang A, Keles H, Hentschke S. et al. Incidentally Detected Splenic Lesions in Ultrasound: Does Contrast-Enhanced Ultrasonography Improve the Differentiation of Benign Hemangioma/Hamartoma from Malignant Lesions?. Ultraschall in Med 2011; 32: 582-592
  Article in Thieme ConnectPubMedGoogle Scholar
• 243 Taibbi A, Bartolotta TV, Matranga D. et al. Splenic Hemangiomas: Contrast-Enhanced Sonographic Findings. J Ultrasound Med 2012; 31: 543-553
  CrossrefPubMedGoogle Scholar
• 244 Picardi M, Soricelli A, Pane F. et al. Contrast-enhanced Harmonic Compound US of the Spleen to Increase Staging Accuracy in Patients with Hodgkin Lymphoma: A Prospective Study. Radiology 2009; 251: 574-582
  CrossrefPubMedGoogle Scholar
• 245 Tafuto S, Catalano O, Barba G. et al. Real-time contrast-enhanced specific ultrasound in staging and follow-up of splenic lymphomas. Fron Biosci 2006; 11: 2224-2229
  PubMedGoogle Scholar
• 246 ten Kate GL, van den Oord SCH, Sijbrands EJG. et al. Current status and future developments of contrast-enhanced ultrasound of carotid atherosclerosis. J Vasc Surg 2013; 57: 539-546
  CrossrefPubMedGoogle Scholar
• 247 Ventura CAP, da Silva ES, Cerri GG. et al. Can contrast-enhanced ultrasound with second-generation contrast agents replace computed tomography angiography for distinguishing between occlusion and pseudo-occlusion of the internal carotid artery?. Clinics (Sao Paulo) 2015; 70: 1-6
  PubMedGoogle Scholar
• 248 Clevert DA, Sommer WH, Zengel P. et al. Imaging of carotid arterial diseases with contrast-enhanced ultrasound (CEUS). Eur J Radiol 2011; 80: 68-76
  CrossrefPubMedGoogle Scholar
• 249 Shalhoub J, Owen DRJ, Gauthier T. et al. The use of contrast enhanced ultrasound in carotid arterial disease. Eur J Vasc Endovasc Surg 2010; 39: 381-387
  CrossrefPubMedGoogle Scholar
• 250 Clevert DA, Sommer WH, Heick A. et al. Doplex and contrast enhanced ultrasound (CEUS) in evaluation of in-stent restenosis after carotid stenting. Clin Hemorheol Microcirc 2011; 48: 199-208
  Google Scholar
• 251 Li ZJ, Luo XH, Du LF. Identification of carotid artery dissection by contrast enhanced ultrasonography. A case report. Med Ultrason 2015; 17: 564-565
  PubMedGoogle Scholar
• 252 Clevert DA, Kubisch C, Meimarakis G. et al. Improved Visualization of Carotid-Jugular Arteriovenous Fistula by Contrast-Enhanced Ultrasound. Ultraschall in Med 2010; 31: 610-612
  Article in Thieme ConnectPubMedGoogle Scholar
• 253 Jaff MR, Goldmakher GV, Lev MH. et al. Imaging of the carotid arteries: the role of duplex ultrasonography, magnetic resonance arteriography, and computerized tomographic arteriography. Vasc Med 2008; 13: 281-292
  PubMedGoogle Scholar
• 254 van den Oord SCH, ten Kate GL, Sijbrands EJG. et al. Effect of Carotid Plaque Screening Using Contrast-Enhanced Ultrasound on Cardiovascular Risk Stratification. Am J Cardiol 2013; 111: 754-759
  CrossrefPubMedGoogle Scholar
• 255 ten Kate GL, Sijbrands EJ, Staub D. et al. Noninvasive Imaging of the Vulnerable Atherosclerotic Plaque. Curr Probl Cardiol 2010; 35: 556-591
  CrossrefPubMedGoogle Scholar
• 256 ten Kate GL, van Dijk AC, van den Oord SCH. et al. Usefulness of Contrast-Enhanced Ultrasound for Detection of Carotid Plaque Ulceration in Patients With Symptomatic Carotid&#xa0;Atherosclerosis. Am J Cardiol 2013; 112: 292-298
  CrossrefPubMedGoogle Scholar
• 257 Coli S, Magnoni M, Sangiorgi G. et al. Contrast-Enhanced Ultrasound Imaging of Intraplaque Neovascularization in Carotid Arteries: Correlation With Histology and Plaque Echogenicity. J Am Coll Cardiol 2008; 52: 223-230
  CrossrefPubMedGoogle Scholar
• 258 Giannoni MF, Vicenzini E, Citone M. et al. Contrast Carotid Ultrasound for the Detection of Unstable Plaques with Neoangiogenesis: A Pilot Study. Eur J Vasc Endovasc Surg 2009; 37: 722-727
  CrossrefPubMedGoogle Scholar
• 259 Zhang Q, Li C, Han H. et al. Spatio-temporal Quantification of Carotid Plaque Neovascularization on Contrast Enhanced Ultrasound: Correlation with Visual Grading and Histopathology. Eur J Vasc Endovas Surg 2015; 50: 289-296
  CrossrefPubMedGoogle Scholar
• 260 Li C, He W, Guo D. et al. Quantification of Carotid Plaque Neovascularization Using Contrast-Enhanced Ultrasound With Histopathologic Validation. Ultrasound Med Biol 2014; 40: 1827-1833
  CrossrefPubMedGoogle Scholar
• 261 Vavuranakis M, Sigala F, Vrachatis DA. et al. Quantitative analysis of carotid plaque vasa vasorum by CEUS and correlation with histology after endarterectomy. VASA 2013; 42: 184-195
  CrossrefPubMedGoogle Scholar
• 262 Owen DR, Shalhoub J, Miller S. et al. Inflammation within carotid atherosclerotic plaque: assessment with late-phase contrast-enhanced US. Radiology 2010; 255: 638-644
  CrossrefPubMedGoogle Scholar
• 263 Shalhoub J, Monaco C, Owen DRJ. et al. Late-Phase Contrast-Enhanced Ultrasound Reflects Biological Features of Instability in Human Carotid Atherosclerosis. Stroke 2011; 42: 3634-3636
  CrossrefPubMedGoogle Scholar
• 264 Staub D, Schinkel AFL, Coll B. et al. Contrast-Enhanced Ultrasound Imaging of the Vasa Vasorum: From Early Atherosclerosis to the Identification of Unstable Plaques. JACC: Cardiovasc Imaging 2010; 3: 761-771
  CrossrefPubMedGoogle Scholar
• 265 Staub D, Patel MB, Tibrewala A. et al. Vasa Vasorum and Plaque Neovascularization on Contrast-Enhanced Carotid Ultrasound Imaging Correlates With Cardiovascular Disease and Past Cardiovascular Events. Stroke 2010; 41: 41-47
  CrossrefPubMedGoogle Scholar
• 266 Ritter MA, Theismann K, Schmiedel M. et al. Vascularization of carotid plaque in recently symptomatic patients is associated with the occurrence of transcranial microembolic signals. Eur J Neurol 2013; 20: 1218-1221
  CrossrefPubMedGoogle Scholar
• 267 van den Oord SCH, Akkus Z, Renaud G. et al. Assessment of carotid atherosclerosis, intraplaque neovascularization, and plaque ulceration using quantitative contrast-enhanced ultrasound in asymptomatic patients with diabetes mellitus. Eur Heart J Cardiovasc Imaging 2014; 15: 1213-1218
  CrossrefPubMedGoogle Scholar
• 268 Kim HS, Woo JS, Kim BY. et al. Biochemical and clinical correlation of intraplaque neovascularization using contrast-enhanced ultrasound of the carotid artery. Atherosclerosis 2014; 233: 579-583
  CrossrefPubMedGoogle Scholar
• 269 van den Oord SCH, Akkus Z, Roeters van Lennep JE. et al. Assessment of subclinical atherosclerosis and intraplaque neovascularization using quantitative contrast-enhanced ultrasound in patients with familial hypercholesterolemia. Atherosclerosis 2013; 231: 107-113
  CrossrefPubMedGoogle Scholar
• 270 Nakamura J, Nakamura T, Deyama J. et al. Assessment of carotid plaque neovascularization using quantitative analysis of contrast-enhanced ultrasound imaging is useful for risk stratification in patients with coronary artery disease. Int J Cardiol 2015; 195: 113-119
  CrossrefPubMedGoogle Scholar
• 271 Deyama J, Nakamura T, Takishima I. et al. Contrast-Enhanced Ultrasound Imaging of Carotid Plaque Neovascularization Is Useful for Identifying High-Risk Patients With Coronary Artery Disease. Circ J 2013; 77: 1499-1507
  CrossrefPubMedGoogle Scholar
• 272 Schinkel AFL, van den Oord SCH, van der Steen AFW. et al. Utility of contrast-enhanced ultrasound for the assessment of the carotid artery wall in patients with Takayasu or giant cell arteritis. Eur Heart J Cardiovasc Imaging 2014; 15: 541-546
  CrossrefPubMedGoogle Scholar
• 273 Possemato N, Macchioni P, Germano G. et al. Clinical images: PET-CT and contrast-enhanced ultrasound in TakayasuGÇÖs arteritis. Rheumatology(Oxford) 2014; 53: 447
  CrossrefPubMedGoogle Scholar
• 274 Perren F, Poglia D, Landis T. et al. Vertebral artery hypoplasia: a predisposing factor for posterior circulation stroke?. Neurology 2007; 68: 65-67
  CrossrefPubMedGoogle Scholar
• 275 Caplan LR. Arterial occlusions: does size matter?. J Neuro Neurosurg Psych 2007; 78: 916
  PubMedGoogle Scholar
• 276 Catalano O, Lobianco R, Cusati B. et al. Contrast-enhanced sonography for diagnosis of ruptured abdominal aortic aneurysm. Am J Roentgenol 2005; 184: 423-427
  CrossrefPubMedGoogle Scholar
• 277 Clevert DA, Stickel M, Johnson T. et al. Imaging of aortic abnormalities with contrast-enhanced ultrasound. A pictorial comparison with CT. Eur Radiol 2007; 17: 2991-3000
  CrossrefPubMedGoogle Scholar
• 278 Pennell RC, Hollier LH, Lie JT. et al. Inflammatory abdominal aortic aneurysms: A thirty-year review. J Vasc Surg 1985; 2: 859-869
  CrossrefPubMedGoogle Scholar
• 279 Clevert DA, Schick K, Chen MH. et al. Role of contrast enhanced ultrasound in detection of abdominal aortic abnormalities in comparison with multislice computed tomography. Clin Med J (Eng) 2009; 122: 858-864
  PubMedGoogle Scholar
• 280 Thurnher M, Cejna M. Imaging of aortic stent-grafts and endoleaks. Radiol Clin North Am 2002; 40: 799-833
  CrossrefPubMedGoogle Scholar
• 281 Clevert DA, Sommer WH, Meimerakis G. et al. Contrast-enhanced ultrasound compared with multislice computed tomography for endovascular aneurysm repair surveillance. Ultrasound 2011; 19: 11-19
  CrossrefPubMedGoogle Scholar
• 282 Clevert DA, Horng A, Clevert DA. et al. Contrast-enhanced ultrasound versus conventional ultrasound and MS-CT in the diagnosis of abdominal aortic dissection. Clin Hemorheol Microcirc 2009; 43: 129-139
  PubMedGoogle Scholar
• 283 d’Audiffret A, Desgranges P, Kobeiter DH. et al. Follow-up evaluation of endoluminally treated abdominal aortic aneurysms with duplex ultrasonography: Validation with computed tomography. J Vasc Surg 2001; 33: 42-50
  CrossrefPubMedGoogle Scholar
• 284 Sommer WH, Hoffmann RT, Becker CR. et al. Comparison of time-resolved CT angiography, contrast-enhanced ultrasound and digital subtraction angiography in a patient with a small type II endoleak after endovascular aneurysm repair. Clin Hemorheol Microcirc 2010; 45: 19-25
  PubMedGoogle Scholar
• 285 Jung EM, Rennert J, Fellner C. et al. Detection and Characterization of Endoleaks Following Endovascular Treatment of Abdominal Aortic Aneurysms using Contrast Harmonic Imaging (CHI) with Quantitative Perfusion Analysis (TIC) Compared to CT Angiography (CTA). Ultraschall in Med 2010; 31: 564-570
  Article in Thieme ConnectPubMedGoogle Scholar
• 286 Napoli V, Bargellini I, Sardella SG. et al. Abdominal Aortic Aneurysm: Contrast-enhanced US for Missed Endoleaks after Endoluminal Repair. Radiology 2004; 233: 217-225
  CrossrefPubMedGoogle Scholar
• 287 Clevert DA, Gurtler VM, Meimarakis G. et al. Classification of endoleaks in the follow-up after EVAR using the time-to-peak of the contrast agent in CEUS examination. Clin Hemorheol Microcirc 2013; 55: 183-191
  PubMedGoogle Scholar
• 288 Ten Bosch JA, Rouwet EV, Peters CTH. et al. Contrast-enhanced Ultrasound versus Computed Tomographic Angiography for Surveillance of Endovascular Abdominal Aortic Aneurysm Repair. J Vasc Interv Radiol 2010; 21: 638-643
  CrossrefPubMedGoogle Scholar
• 289 Gurtler VM, Sommer WH, Meimarakis G. et al. A comparison between contrast-enhanced ultrasound imaging and multislice computed tomography in detecting and classifying endoleaks in the follow-up after endovascular aneurysm repair. J Vasc Surg 2013; 58: 340-345
  CrossrefPubMedGoogle Scholar
• 290 Sidhu PS, Allan PL, Cattin F. et al. Diagnostic efficacy of SonoVue(R), a second generation contrast agent, in the assessment of extracranial carotid or peripheral arteries using colour and spectral Doppler ultrasound: a multicentre study. Br J Radiol 2006; 79: 44-51
  CrossrefPubMedGoogle Scholar
• 291 Pfister K, Kasprzak PM, Apfelbeck H. et al. Stellenwert der Kontrastmittelsonografie in der Gefabchirurgie. Zentralbl Chir 2014; 139: 518-524
  Article in Thieme ConnectPubMedGoogle Scholar
• 292 Rubenthaler J, Reiser M, Clevert DA. Diagnostic vascular ultrasonography with the help of color Doppler and contrast-enhanced ultrasonography. Ultrasonography 2016; 35: 289-301
  CrossrefPubMedGoogle Scholar
• 293 Seidel G, Meairs S. Ultrasound Contrast Agents in Ischemic Stroke. Cerebrovasc Dis 2009; 27: 25-39
  PubMedGoogle Scholar
• 294 Seidel G, Kaps M. Harmonic imaging of the vertebrobasilar system. Stroke 1997; 28: 1610-1613
  CrossrefPubMedGoogle Scholar
• 295 Postert T, Braun B, Meves S. et al. Contrast-enhanced transcranial color-coded sonography in acute hemispheric brain infarction. Stroke 1999; 30: 1819-1826
  CrossrefPubMedGoogle Scholar
• 296 Droste DW, Jurgens R, Weber S. et al. Benefit of Echocontrast-Enhanced Transcranial Color-Coded Duplex Ultrasound in the Assessment of Intracranial Collateral Pathways. Stroke 2000; 31: 920-923
  CrossrefPubMedGoogle Scholar
• 297 Eyding J, Krogias C, Schollhammer M. et al. Contrast-Enhanced Ultrasonic Parametric Perfusion Imaging Detects Dysfunctional Tissue at Risk in Acute MCA Stroke. J Cerebl Blood Flow Metab 2006; 26: 576-582
  PubMedGoogle Scholar
• 298 Bartels E, Henning S, Wellmer A. et al. Evaluation of Cerebral Perfusion Deficit in Stroke Patients Using New Transcranial Contrast Imaging CPS Technology – Preliminary Results. Ultraschall in Med 2005; 26: 478-486
  Article in Thieme ConnectPubMedGoogle Scholar
• 299 Bartels E, Bittermann HJ. Transcranial Contrast Imaging of Cerebral Perfusion in Patients With Space-Occupying Intracranial Lesions. J Ultrasound Med 2006; 25: 499-507
  PubMedGoogle Scholar
• 300 Seidel G, Canger H, Meyer-Wiethe K. et al. On the Ability of Ultrasound Parametric Perfusion Imaging to Predict the Area of Infarction in AcuteIschemic Stroke. Ultraschall in Med 2006; 27: 543-548
  Article in Thieme ConnectPubMedGoogle Scholar
• 301 Krogias C, Hennebohl C, Geier B. et al. Transcranial Ultrasound Perfusion Imaging and Perfusion-MRI – A Pilot Study on the Evaluation of Cerebral Perfusion in Severe Carotid Artery Stenosis. Ultrasound Med Biol 2010; 36: 1973-1980
  CrossrefPubMedGoogle Scholar
• 302 Krogias C, Meves SH, Hansen C. et al. Ultrasound Perfusion Imaging of the Brain – Routine and Novel Applications: Uncommon Cases and Review of the Literature. J Neuroimaging 2011; 21: 255-258
  CrossrefPubMedGoogle Scholar
• 303 Nedelmann M, Ritschel N, Doenges S. et al. Combined Contrast-Enhanced Ultrasound and rt-PA Treatment is Safe and Improves Impaired Microcirculation after Reperfusion of Middle Cerebral Artery Occlusion. J Cereb Blood Flow Metab 2010; 30: 1712-1720
  CrossrefPubMedGoogle Scholar
• 304 Eggers J, Konig IR, Koch B. et al. Sonothrombolysis With Transcranial Color-Coded Sonography and Recombinant Tissue-Type Plasminogen Activator in Acute Middle Cerebral Artery Main Stem Occlusion: Results From a Randomized Study. Stroke 2008; 39: 1470-1475
  CrossrefPubMedGoogle Scholar
• 305 Nacu A, Kvistad CE, Logallo N. et al. A pragmatic approach to sonothrombolysis in acute ischaemic stroke: the Norwegian randomised controlled sonothrombolysis in acute stroke study (NOR-SASS). BMC Neurol 2015; 15: 110
  CrossrefPubMedGoogle Scholar
• 306 Schellinger PD, Alexandrov AV, Barreto AD. et al. Combined Lysis of Thrombus with Ultrasound and Systemic Tissue Plasminogen Activator for Emergent Revascularization in Acute Ischemic Stroke (Clotbust-ER): Design and Methodology of a Multinational Phase 3 Trial. Int J Stroke 2015; 10: 1141-1148
  CrossrefPubMedGoogle Scholar
• 307 Saftoiu A, Dietrich CF, Vilmann P. Contrast-enhanced harmonic endoscopic ultrasound. Endoscopy 2012; 44: 612-617
  Article in Thieme ConnectPubMedGoogle Scholar
• 308 Alvarez-Sanchez MV, Napoleon B. Contrast-enhanced harmonic endoscopic ultrasound imaging: Basic principles, present situation and future perspectives. World J Gastroenterol 2014; 20: 15549-15563
  CrossrefPubMedGoogle Scholar
• 309 Fusaroli P, Napoleon B, Gincul R. et al. The clinical impact of ultrasound contrast agents in EUS: a systematic review according to the levels of evidence. Gastrointest Endosc 2016; 84: 587-596
  CrossrefPubMedGoogle Scholar
• 310 Cosgrove D, Piscaglia F, Bamber JC. et al. EFSUMB guidelines and recommendations on the clinical use of ultrasound elastography. Part 2: clinical applications. Ultraschall in Med 2013; 34: 238-253
  Article in Thieme ConnectPubMedGoogle Scholar
• 311 Jenssen C, Hocke M, Fusaroli P. et al. EFSUMB Guidelines on Interventional Ultrasound (INVUS), Part IV: EUS-guided Interventions: General aspects and EUS-guided sampling (Long Version). Ultraschall in Med 2016; 37: E33-E76
  Article in Thieme ConnectPubMedGoogle Scholar
• 312 Hocke M, Schulze E, Gottschalk P. et al. Contrast-enhanced endoscopic ultrasound in discrimination between focal pancreatitis and pancreatic cancer. World J Gastroenterol 2006; 12: 246-250
  CrossrefPubMedGoogle Scholar
• 313 Gong T, Hu D, Zhu Q. Contrast-enhanced EUS for differential diagnosis of pancreatic mass lesions: a meta-analysis. Gastrointest Endosc 2012; 76: 301-309
  CrossrefPubMedGoogle Scholar
• 314 Hocke M, Ignee A, Topalidis T. et al. Contrast-Enhanced Endosonographic Doppler Spectrum Analysis Is Helpful in Discrimination Between Focal Chronic Pancreatitis and Pancreatic Cancer. Pancreas 2007; 35: 286-288
  CrossrefPubMedGoogle Scholar
• 315 Hocke M, Ignee A, Dietrich CF. Advanced Endosonographic Diagnostic Tools for Discrimination of Focal Chronic Pancreatitis and Pancreatic Carcinoma – Elastography, Contrast Enhanced High Mechanical Index (CEHMI) and Low Mechanical Index (CELMI) Endosonography in Direct Comparison. Z Gastroenterol 2012; 50: 199-203
  Article in Thieme ConnectPubMedGoogle Scholar
• 316 Sakamoto H, Kitano M, Suetomi Y. et al. Utility of Contrast-Enhanced Endoscopic Ultrasonography for Diagnosis of Small Pancreatic Carcinomas. Ultrasound Med Biol 2008; 34: 525-532
  CrossrefPubMedGoogle Scholar
• 317 Sâftoiu A, Iordache S, Gheonea DI. et al. Combined contrast-enhanced power Doppler and real-time sonoelastography performed during EUS, used in the differential diagnosis of focal pancreatic masses (with videos). Gastrointest Endosc 2010; 72: 739-747
  CrossrefPubMedGoogle Scholar
• 318 Fusaroli P, Spada A, Mancino MG. et al. Contrast Harmonic Echo-Endoscopic Ultrasound Improves Accuracy in Diagnosis of Solid Pancreatic Masses. Clin Gastroenterol Hepatol 2010; 8: 629-634
  CrossrefPubMedGoogle Scholar
• 319 Gincul R, Palazzo M, Pujol B. et al. Contrast-harmonic endoscopic ultrasound for the diagnosis of pancreatic adenocarcinoma: a prospective multicenter trial. Endoscopy 2014; 46: 373-379
  Article in Thieme ConnectPubMedGoogle Scholar
• 320 Napoleon B, Alvarez-Sanchez MV, Gincoul R. et al. Contrast-enhanced harmonic endoscopic ultrasound in solid lesions of the pancreas: results of a pilot study. Endoscopy 2010; 42: 564-570
  Article in Thieme ConnectPubMedGoogle Scholar
• 321 Sâftoiu A, Vilmann P, Dietrich CF. et al. Quantitative contrast-enhanced harmonic EUS in differential diagnosis of focal pancreatic masses (with videos). Gastroint Endosc 2015; 82: 59-69
  CrossrefPubMedGoogle Scholar
• 322 Matsubara H, Itoh A, Kawashima H. et al. Dynamic Quantitative Evaluation of Contrast-Enhanced Endoscopic Ultrasonography in the Diagnosis of Pancreatic Diseases. Pancreas 2011; 40: 1073-1079
  CrossrefPubMedGoogle Scholar
• 323 Kitano M, Kudo M, Yamao K. et al. Characterization of Small Solid Tumors in the Pancreas: The Value of Contrast-Enhanced Harmonic Endoscopic Ultrasonography. Am J Gastroenterol 2012; 107: 303-310
  CrossrefPubMedGoogle Scholar
• 324 Lee TY, Cheon YK, Shim CS. Clinical Role of Contrast-Enhanced Harmonic Endoscopic Ultrasound in Differentiating Solid Lesions of the Pancreas: A Single-Center Experience in Korea. Gut Liver 2013; 7: 599-604
  CrossrefPubMedGoogle Scholar
• 325 Ishikawa T, Itoh A, Kawashima H. et al. Usefulness of EUS combined with contrast-enhancement in the differential diagnosis of malignant versus benign and preoperative localization of pancreatic endocrine tumors. Gastrointest Endosc 2010; 71: 951-959
  CrossrefPubMedGoogle Scholar
• 326 Yamashita Y, Kato J, Ueda K. et al. Contrast-Enhanced Endoscopic Ultrasonography for Pancreatic Tumors. Biomed Res Int 2015; 2015: 491782
  PubMedGoogle Scholar
• 327 Seicean A, Badea R, Stan-Iuga R. et al. Quantitative Contrast-Enhanced Harmonic Endoscopic Ultrasonography for the Discrimination of Solid Pancreatic Masses. Ultraschall in Med 2010; 31: 571-576
  Article in Thieme ConnectPubMedGoogle Scholar
• 328 Gheonea DI, Streba CT, Ciurea T. et al. Quantitative low mechanical index contrast-enhanced endoscopic ultrasound for the differential diagnosis of chronic pseudotumoral pancreatitis and pancreatic cancer. BMC Gastroenterol 2013; 13: 2
  CrossrefPubMedGoogle Scholar
• 329 Imazu H, Kanazawa K, Mori N. et al. Novel quantitative perfusion analysis with contrast-enhanced harmonic EUS for differentiation of autoimmune pancreatitis from pancreatic carcinoma. Scand j Gastroenterol 2012; 47: 853-860
  CrossrefPubMedGoogle Scholar
• 330 Dietrich CF, Sahai AV, D’Onofrio M. et al. Differential diagnosis of small solid pancreatic lesions. Gastrointest Endosc 2016; 84: 933-940
  CrossrefPubMedGoogle Scholar
• 331 Seicean A, Badea R, Moldovan-Pop A. et al. Harmonic Contrast-Enhanced Endoscopic Ultrasonography for the Guidance of Fine-Needle Aspiration in Solid Pancreatic Masses. Ultraschall in Med 2017; 38: 174-182
  Article in Thieme ConnectPubMedGoogle Scholar
• 332 Hou X, Jin Z, Xu C. et al. Contrast-Enhanced Harmonic Endoscopic Ultrasound-Guided Fine-Needle Aspiration in the Diagnosis of Solid Pancreatic Lesions: A Retrospective Study. PLoS ONE 2015; 10: e0121236
  CrossrefPubMedGoogle Scholar
• 333 Imazu H, Uchiyama Y, Matsunaga K. et al. Contrast-enhanced harmonic EUS with novel ultrasonographic contrast (Sonazoid) in the preoperative T-staging for pancreaticobiliary malignancies. Scand j Gastroenterol 2010; 45: 732-738
  CrossrefPubMedGoogle Scholar
• 334 Hirooka Y, Goto H, Ito A. et al. Contrast-enhanced endoscopic ultrasonography in pancreatic diseases: a preliminary study. Am J Gastroenterol 1998; 93: 632-635
  CrossrefPubMedGoogle Scholar
• 335 Hocke M, Cui XW, Domagk D. et al. Pancreatic cystic lesions: The value of contrast-enhanced endoscopic ultrasound to influence the clinical pathway. Endosc Ultrasound 2014; 3: 123-130
  CrossrefPubMedGoogle Scholar
• 336 Fusaroli P, Serrani M, De Giorgio R. et al. Contrast Harmonic-Endoscopic Ultrasound Is Useful to Identify Neoplastic Features of Pancreatic Cysts (With Videos). Pancreas 2016; 45: 265-268
  CrossrefPubMedGoogle Scholar
• 337 Kamata K, Kitano M, Omoto S. et al. Contrast-enhanced harmonic endoscopic ultrasonography for differential diagnosis of pancreatic cysts. Endoscopy 2016; 48: 35-41
  Article in Thieme ConnectPubMedGoogle Scholar
• 338 Kurihara N, Kawamoto H, Kobayashi Y. et al. Vascular patterns in nodules of intraductal papillary mucinous neoplasms depicted under contrast-enhanced ultrasonography are helpful for evaluating malignant potential. Eur J Radiol 2012; 81: 66-70
  CrossrefPubMedGoogle Scholar
• 339 Yamashita Y, Ueda K, Itonaga M. et al. Usefulness of Contrast-Enhanced Endoscopic Sonography for Discriminating Mural Nodules From Mucous Clots in Intraductal Papillary Mucinous Neoplasms: A Single-Center Prospective Study. J Ultrasound Med 2013; 32: 61-68
  CrossrefPubMedGoogle Scholar
• 340 Harima H, Kaino S, Shinoda S. et al. Differential diagnosis of benign and malignant branch duct intraductal papillary mucinous neoplasm using contrast-enhanced endoscopic ultrasonography. World J Gastroenterol 2015; 21: 6252-6260
  CrossrefPubMedGoogle Scholar
• 341 Ohno E, Itoh A, Kawashima H. et al. Malignant Transformation of Branch DuctGÇôType Intraductal Papillary Mucinous Neoplasms of the Pancreas Based on Contrast-Enhanced Endoscopic Ultrasonography Morphological Changes: Focus on Malignant Transformation of Intraductal Papillary Mucinous Neoplasm Itself. Pancreas 2012; 41: 855-862
  CrossrefPubMedGoogle Scholar
• 342 Park CH, Chung MJ, Oh TG. et al. Differential diagnosis between gallbladder adenomas and cholesterol polyps on contrast-enhanced harmonic endoscopic ultrasonography. Surg Endosc 2013; 27: 1414-1421
  CrossrefPubMedGoogle Scholar
• 343 Choi JH, Seo DW, Choi JH. et al. Utility of contrast-enhanced harmonic EUS in the diagnosis of malignant gallbladder polyps (with videos). Gastrointest Endosc 2013; 78: 484-493
  CrossrefPubMedGoogle Scholar
• 344 Imazu H, Mori N, Kanazawa K. et al. Contrast-Enhanced Harmonic Endoscopic Ultrasonography in the Differential Diagnosis of Gallbladder Wall Thickening. Dig Dis Sci 2014; 59: 1909-1916
  CrossrefPubMedGoogle Scholar
• 345 Sugimoto M, Takagi T, Konno N. et al. The efficacy of contrast-enhanced harmonic endoscopic ultrasonography in diagnosing gallbladder cancer. Sci Rep 2016; 6: 25848
  CrossrefPubMedGoogle Scholar
• 346 Kojima S, Goto H, Hirooka Y. et al. Differentiation of benign and malignant lymph nodes with contrast-enhanced echolymphography using endoscopy ultrasound-guided puncture. Hepatogastroenterology 2003; 50: 1285-1291
  PubMedGoogle Scholar
• 347 Hocke M, Menges M, Topalidis T. et al. Contrast-enhanced endoscopic ultrasound in discrimination between benign and malignant mediastinal and abdominal lymph nodes. J Cancer Res Clin Oncol 2008; 134: 473-480
  CrossrefPubMedGoogle Scholar
• 348 Miyata T, Kitano M, Omoto S. et al. Contrast-enhanced harmonic endoscopic ultrasonography for assessment of lymph node metastases in pancreatobiliary carcinoma. World J Gastroenterol 2016; 22: 3381-3391
  CrossrefPubMedGoogle Scholar
• 349 Iordache S, Filip MM, Georgescu CV. et al. Contrast-enhanced power Doppler endosonography and pathological assessment of vascularization in advanced gastric carcinomas – a feasibility study. Med Ultrason 2012; 14: 101-107
  PubMedGoogle Scholar
• 350 Matsui S, Kudo M, Kitano M. et al. Evaluation of the response to chemotherapy in advanced gastric cancer by contrast-enhanced harmonic EUS. Hepatogastroenterology 2015; 62: 595-598
  PubMedGoogle Scholar
• 351 Nomura N, Goto H, Niwa Y. et al. Usefulness of contrast-enhanced EUS in the diagnosis of upper GI tract diseases. Gastrointest Endosc 1999; 50: 555-560
  CrossrefPubMedGoogle Scholar
• 352 Kannengiesser K, Mahlke R, Petersen F. et al. Contrast-enhanced harmonic endoscopic ultrasound is able to discriminate benign submucosal lesions from gastrointestinal stromal tumors. Scand j Gastroenterol 2012; 47: 1515-1520
  CrossrefPubMedGoogle Scholar
• 353 Sakamoto H, Kitano M, Matsui S. et al. Estimation of malignant potential of GI stromal tumors by contrast-enhanced harmonic EUS (with videos). Gastrointest Endosc 2011; 73: 227-237
  CrossrefPubMedGoogle Scholar
• 354 Yamashita Y, Kato J, Ueda K. et al. Contrast-enhanced endoscopic ultrasonography can predict a higher malignant potential of gastrointestinal stromal tumors by visualizing newly formed vessels. J Clin Ultrasound 2015; 43: 89-97
  CrossrefPubMedGoogle Scholar
• 355 Zhao Y, Qian L, Li P. et al. The diagnostic value of endoscopic ultrasonography and contrast-enhanced harmonic endoscopic ultrasonography in gastrointestinal stromal tumors. Endosc Ultrasound 2016; 5: 111-117
  CrossrefPubMedGoogle Scholar
• 356 Paik WH, Choi JH, Seo DW. et al. Clinical Usefulness With the Combination of Color Doppler and Contrast-enhanced Harmonic EUS for the Assessment of Visceral Vascular Diseases. J Clin Gastroenterol 2014; 48: 845-850
  CrossrefPubMedGoogle Scholar
• 357 Sato T, Yamazaki K, Toyota J. et al. Evaluation of hemodynamics in esophageal varices: Value of endoscopic color Doppler ultrasonography with a galactose-based contrast agent. Hepatology Research 2003; 25: 55-61
  CrossrefPubMedGoogle Scholar
• 358 Sato T, Yamazaki K, Toyota J. et al. Perforating veins in recurrent esophageal varices evaluated by endoscopic color Doppler ultrasonography with a galactose-based contrast agent. J Gastroenterol 2004; 39: 422-428
  CrossrefPubMedGoogle Scholar
• 359 Sato T, Yamazaki K, Toyota J. et al. Evaluation of arterial blood flow in esophageal varices via endoscopic color Doppler ultrasonography with a galactose-based contrast agent. J Gastroenterol 2005; 40: 64-69
  CrossrefPubMedGoogle Scholar
• 360 Chiu WC, Cushing BM, Rodriguez A. et al. Abdominal Injuries without Hemoperitoneum: A Potential Limitation of Focused Abdominal Sonography for Trauma (FAST). J Trauma 1997; 42: 617-623
  CrossrefPubMedGoogle Scholar
• 361 Catalano O, Aiani L, Barozzi L. et al. CEUS in abdominal trauma: multi-center study. Abdominal Imaging 2009; 34: 225-234
  CrossrefPubMedGoogle Scholar
• 362 Valentino M, Serra C, Zironi G. et al. Blunt Abdominal Trauma: Emergency Contrast-Enhanced Sonography for Detection of Solid Organ Injuries. Am J Roentgenol 2006; 186: 1361-1367
  CrossrefPubMedGoogle Scholar
• 363 Miele V, Piccolo CL, Galluzzo M. et al. Contrast-enhanced ultrasound (CEUS) in blunt abdominal trauma. Br J Radiol 2016; 89: 20150823
  CrossrefPubMedGoogle Scholar
• 364 Sessa B, Trinci M, Ianniello S. et al. Blunt abdominal trauma: role of contrast-enhanced ultrasound (CEUS) in the detection and staging of abdominal traumatic lesions compared to US and CE-MDCT. Radiol Med 2015; 120: 180-189
  CrossrefPubMedGoogle Scholar
• 365 Cokkinos DD, Antypa E, Stefanidis K. et al. Contrast-enhanced ultrasound for imaging blunt abdominal trauma – indications, description of the technique and imaging review. Ultraschall in Med 2012; 33: 60-67
  Article in Thieme ConnectPubMedGoogle Scholar
• 366 Durkin N, Deganello A, Sellars ME. et al. Post-traumatic liver and spleen pseudoaneurysms in children: diagnosis, management and follow-up screening using contrast enhanced ultrasound (CEUS). J Pediat Surg 2016; 51: 289-292
  CrossrefPubMedGoogle Scholar
• 367 Ferlay J, Steliarova-Foucher E, Lortet-Tieulent J. et al. Cancer incidence and mortality patterns in Europe: Estimates for 40 countries in 2012. Eur J Cancer 2013; 49: 1374-1403
  CrossrefPubMedGoogle Scholar
• 368 Haugen BR, Alexander EK, Bible KC. et al. 2015 American Thyroid Association Management Guidelines for Adult Patients with Thyroid Nodules and Differentiated Thyroid Cancer: The American Thyroid Association Guidelines Task Force on Thyroid Nodules and Differentiated Thyroid Cancer. Thyroid 2015; 26: 1-133
  PubMedGoogle Scholar
• 369 Bartolotta TV, Midiri M, Galia M. et al. Qualitative and quantitative evaluation of solitary thyroid nodules with contrast-enhanced ultrasound: initial results. Eur Radiol 2006; 16: 2234-2241
  CrossrefPubMedGoogle Scholar
• 370 Zhang B, Jiang YX, Liu JB. et al. Utility of Contrast-Enhanced Ultrasound for Evaluation of Thyroid Nodules. Thyroid 2010; 20: 51-57
  CrossrefPubMedGoogle Scholar
• 371 Yuan Z, Quan J, Yunxiao Z. et al. Contrast-enhanced ultrasound in the diagnosis of solitary thyroid nodules. J Cancer Res Ther 2015; 11: 41-45
  CrossrefPubMedGoogle Scholar
• 372 Deng J, Zhou P, Tian S. et al. Comparison of Diagnostic Efficacy of Contrast-Enhanced Ultrasound, Acoustic Radiation Force Impulse Imaging, and Their Combined Use in Differentiating Focal Solid Thyroid Nodules. PLoS ONE 2014; 9: e90674
  CrossrefPubMedGoogle Scholar
• 373 Nemec U, Nemec SF, Novotny C. et al. Quantitative evaluation of contrast-enhanced ultrasound after intravenous administration of a microbubble contrast agent for differentiation of benign and malignant thyroid nodules: assessment of diagnostic accuracy. Eur Radiol 2012; 22: 1357-1365
  CrossrefPubMedGoogle Scholar
• 374 Cantisani V, Consorti F, Guerrisi A. et al. Prospective comparative evaluation of quantitative-elastosonography (Q-elastography) and contrast-enhanced ultrasound for the evaluation of thyroid nodules: Preliminary experience. Eur J Radiol 2013; 82: 1892-1898
  CrossrefPubMedGoogle Scholar
• 375 Wu Q, Wang Y, Li Y. et al. Diagnostic value of contrast-enhanced ultrasound in solid thyroid nodules with and without enhancement. Endocrine 2016; 1: 1-9
  PubMedGoogle Scholar
• 376 Ma X, Zhang B, Ling W. et al. Contrast-enhanced sonography for the identification of benign and malignant thyroid nodules: Systematic review and meta-analysis. J Clin Ultrasound 2016; 44: 199-209
  CrossrefPubMedGoogle Scholar
• 377 Yu D, Han Y, Chen T. Contrast-Enhanced Ultrasound for Differentiation of Benign and Malignant Thyroid Lesions: Meta-analysis. Otolaryngol Head and Neck Surgery 2014; 151: 909-915
  PubMedGoogle Scholar
• 378 Sun B, Lang L, Zhu X. et al. Accuracy of contrast-enhanced ultrasound in the identification of thyroid nodules: a meta-analysis. Int J Clin Exp Med 2015; 8: 12882-12889
  PubMedGoogle Scholar
• 379 Zhang XF, Hong YR, Bao XF. et al. Qualitative evaluation of thyroid nodues with gray-scale contrast-enhanced ultrasound. Zhejiang Da Xue Xue Bao Yi Xue Ban 2008; 37: 515-518
  PubMedGoogle Scholar
• 380 Acharya UR, Sree SV, Swapna G. et al. Effect of complex wavelet transform filter on thyroid tumor classification in three-dimensional ultrasound. Proc Inst Mech Eng H 2013; 227: 284-292
  CrossrefPubMedGoogle Scholar
• 381 Vassallo P, Wernecke K, Roos N. et al. Differentiation of benign from malignant superficial lymphadenopathy: the role of high resolution US. Radiology 1992; 183: 215-220
  CrossrefPubMedGoogle Scholar
• 382 Na DG, Lim HK, Byun HS. et al. Differential diagnosis of cervical lymphadenopathy: usefulness of color Doppler sonography. Am J Roentgenol 1997; 168: 1311-1316
  CrossrefPubMedGoogle Scholar
• 383 Schmid-Wendter MH, Partscht K, Korting HC. et al. Improved differentiation of benign and malignant lymphadenopathy in patients with cutaneous melanoma by contrast-enhanced color Doppler sonography. Arc Dermatol 2002; 138: 491-497
  CrossrefPubMedGoogle Scholar
• 384 Jin Y, He YS, Zhang MM. et al. Value of contrast-enhanced ultrasonography in the differential diagnosis of enlarged lymph nodes: a meta-analysis of diagnostic accuracy studies. Asian Pac J Cancer Prev 2015; 16: 2361-2368
  CrossrefPubMedGoogle Scholar
• 385 Moritz JD, Ludwig A, Oestmann JW. Contrast-enhanced color Doppler sonography for evaluation of enlarged cervical lymph nodes in head and neck tumors. Am J Roentgenol 2000; 174: 1279-1284
  CrossrefPubMedGoogle Scholar
• 386 Steppan I, Reimer D, Müller-Holzner E. et al. Breast Cancer in Women: Evaluation of Benign and Malignant Axillary Lymph Nodes with Contrast-Enhanced Ultrasound. Ultraschall in Med 2010; 31: 63-67
  Article in Thieme ConnectPubMedGoogle Scholar
• 387 Stramare R, Scagliori E, Mannucci M. et al. The Role of Contrast-Enhanced Gray-Scale Ultrasonography in the Differential Diagnosis of Superficial Lymph Nodes. Ultrasound Q 2010; 26: 45-51
  CrossrefPubMedGoogle Scholar
• 388 Rubaltelli L, Beltrame V, Tregnaghi A. et al. Contrast-Enhanced Ultrasound for Characterizing Lymph Nodes With Focal Cortical Thickening in Patients With Cutaneous Melanoma. Am J Roentgenol 2011; 196: W8-W12
  CrossrefPubMedGoogle Scholar
• 389 Dudau C, Hameed S, Gibson D. et al. Can Contrast-Enhanced Ultrasound Distinguish Malignant from Reactive Lymph Nodes in Patients with Head and Neck Cancers?. Ultrasound Med Biol 2014; 40: 747-754
  CrossrefPubMedGoogle Scholar
• 390 Yu M, Liu Q, Song HP. et al. Clinical Application of Contrast-Enhanced Ultrasonography in Diagnosis of Superficial Lymphadenopathy. J Ultrasound Med 2010; 29: 735-740
  CrossrefPubMedGoogle Scholar
• 391 Nakase K, Yamamoto K, Hiasa A. et al. Contrast-enhanced ultrasound examination of lymph nodes in different types of lymphoma. Cancer Detect Prev 2006; 30: 188-191
  CrossrefPubMedGoogle Scholar
• 392 Rubaltelli L, Khadivi Y, Tregnaghi A. et al. Evaluation of Lymph Node Perfusion Using Continuous Mode Harmonic Ultrasonography With a Second-Generation Contrast Agent. J Ultrasound Med 2004; 23: 829-836
  CrossrefPubMedGoogle Scholar
• 393 Jin Y, Peng YL, Ma BY. et al. The perfusion pattern of lymphadenopathy in contrast-enhanced ultrasonography under different reference conditions. Sichuan Da Xue Xue BAo Yi Xue Ban 2014; 45: 1005-1009
  PubMedGoogle Scholar
• 394 Steinhart H, Zenk J, Sprang K. et al. Contrast-enhanced color Doppler sonography of parotid gland tumors. Eur Arch OtorhinoLaryngol 2003; 260: 344-348
  CrossrefPubMedGoogle Scholar
• 395 Mansour N, Bas M, Stock KF. et al. Multimodal Ultrasonographic Pathway of Parotid Gland Lesions. Ultraschall in Med 2017; 38: 166-173
  Article in Thieme ConnectPubMedGoogle Scholar
• 396 Knopf A, Mansour N, Chaker A. et al. Multimodal ultrasonographic characterisation of parotid gland lesions&#x2014;A pilot study. Eur J Radiol 2012; 81: 3300-3305
  CrossrefPubMedGoogle Scholar
• 397 Wei X, Li Y, Zhang S. et al. Evalution of microvascularization in focal salivary gland lesions by contrast-enhanced ultrasonography (CEUS) and color Doppler sonography. Clin Hemorheol Microcirc 2013; 54: 259-271
  CrossrefPubMedGoogle Scholar
• 398 Klotz LV, Gorkov R, Eichhorn ME. et al. Perfusion characteristics of parotid gland tumors evaluated by contrast-enhanced ultrasound. Eur J Radiol 2013; 82: 2227-2232
  CrossrefPubMedGoogle Scholar
• 399 David E, Cantisani V, De Vincentiis M. et al. Contrast-enhanced ultrasound in the evaluation of parotid gland lesions: an update of the literature. Ultrasound 2016; 24: 104-110
  CrossrefPubMedGoogle Scholar
• 400 Badea AF, Bran S, Tamas-Szora A. et al. Solid parotid tumors: an individual and integrative analysis of various ultrasonographic criteria. A prospective and observational study. Med Ultrason 2013; 15: 289-298
  CrossrefPubMedGoogle Scholar
• 401 Klotz LV, Ingrisch M, Eichhorn ME. et al. Monitoring parotid gland tumors with a new perfusion software for contrast-enhanced ultrasound. Clin Hemorheol Microcirc 2014; 58: 261-269
  PubMedGoogle Scholar
• 402 Fischer T, Paschen CF, Slowinski T. et al. Differentiation of Parotid Gland Tumors with Contrast-Enhanced Ultrasound. Rofo 2010; 182: 155-162
  Article in Thieme ConnectPubMedGoogle Scholar
• 403 Sorelli PG, Cosgrove DO, Svensson WE. et al. Can contrast-enhanced sonography distingush benign from malignant breast masses. J Clin Ultrasound 2010; 38: 177-181
  PubMedGoogle Scholar
• 404 Balleyguier C, Opolon P, Mathieu MC. et al. New potential and applications of contrast-enhanced ultrasound of the breast: Own investigations and review of the literature. Eur J Radiol 2009; 69: 14-23
  CrossrefPubMedGoogle Scholar
• 405 Liu H, Jiang YX, Liu JB. et al. Evaluation of breast lesions with contrast-enhanced ultrasound using the microvascular imaging technique: Initial observations. Breast 2008; 17: 532-539
  CrossrefPubMedGoogle Scholar
• 406 Jia WR, Chai WM, Tang L. et al. Three-dimensional contrast enhanced ultrasound score and dynamic contrast-enhanced magnetic resonance imaging score in evaluating breast tumor angiogenesis: Correlation with biological factors. Eur J Radiol 2014; 83: 1098-1105
  CrossrefPubMedGoogle Scholar
• 407 Cao XL, Bao W, Zhu SG. et al. Contrast-Enhanced Ultrasound Characteristics of Breast Cancer: Correlation with Prognostic Factors. Ultrasound Med Biol 2014; 40: 11-17
  CrossrefPubMedGoogle Scholar
• 408 Zhang J, Cai L, Chen L. et al. CEUS Helps to Rerate Small Breast Tumors of BI-RADS Category 3 and Category 4. Biomed Res Int 2014; 2014: 572532
  PubMedGoogle Scholar
• 409 Xia HS, Wang X, Ding H. et al. Papillary breast lesions on contrast-enhanced ultrasound: morphological enhancement patterns and diagnostic strategy. Eur Radiol 2014; 24: 3178-3190
  CrossrefPubMedGoogle Scholar
• 410 Wang Z, Zhou Q, Liu J. et al. Tumor size of breast invasive ductal cancer measured with contrast-enhanced ultrasound predicts regional lymph node metastasis and N stage. Int J Clin Exp Pathol 2014; 7: 6985-6991
  PubMedGoogle Scholar
• 411 Omoto K, Matsunaga H, Take N. et al. Sentinel Node Detection Method Using Contrast-Enhanced Ultrasonography with Sonazoid in Breast Cancer: Preliminary Clinical Study. Ultrasound Med Biol 2009; 35: 1249-1256
  CrossrefPubMedGoogle Scholar
• 412 Sever A, Jones S, Cox K. et al. Preoperative localization of sentinel lymph nodes using intradermal microbubbles and contrast-enhanced ultrasonography in patients with breast cancer. Br J Surg 2009; 96: 1295-1299
  CrossrefPubMedGoogle Scholar
• 413 Sever AR, Mills P, Weeks J. et al. Preoperative Needle Biopsy of Sentinel Lymph Nodes Using Intradermal Microbubbles and Contrast-Enhanced Ultrasound in Patients With Breast Cancer. Am J Roentgenol 2012; 199: 465-470
  CrossrefPubMedGoogle Scholar
• 414 Sever AR, Mills P, Jones SE. et al. Preoperative sentinel node identification with ultrasound using microbubbles in patients with breast cancer. Am J Roentgenol 2011; 196: 251-256
  CrossrefPubMedGoogle Scholar
• 415 Cox K, Sever A, Jones S. et al. Validation of a technique using microbubbles and contrast enhanced ultrasound (CEUS) to biopsy sentinel lymph nodes (SLN) in pre-operative breast cancer patients with a normal grey-scale axillary ultrasound. Eur J Surg Oncol 2013; 39: 760-765
  CrossrefPubMedGoogle Scholar
• 416 Wang Y, Wang W, Li J. et al. Gray-Scale Contrast-Enhanced Ultrasonography Of Sentinel Lymph Nodes In A Metastatic. Acad Radiol 2009; 16: 957-962
  CrossrefPubMedGoogle Scholar
• 417 Xie F, Zhang D, Cheng L. et al. Intradermal microbubbles and contrast-enhanced ultrasound (CEUS) is a feasible approach for sentinel lymph node identification in early-stage breast cancer. World J Surg Oncol 2015; 13: 319
  CrossrefPubMedGoogle Scholar
• 418 Gkegkes ID, Iavazzo C. Contrast enhanced ultrasound (CEU) using microbubbles for sentinel lymph node biopsy in breas cancer; a systemic review. Acta Chir Belg 2015; 115: 212-218
  PubMedGoogle Scholar
• 419 FitzGerald O, Bresnihan B. Synovial membrane cellularity and vascularity. Ann Rheum Dis 1995; 54: 511-515
  CrossrefPubMedGoogle Scholar
• 420 Klauser A, Frauscher F, Schirmer M. Letter to the Editor. Eur Radiol 2004; 14: 545-546
  CrossrefPubMedGoogle Scholar
• 421 Klauser AS, Peetrons P. Developments in musculoskeletal ultrasound and clinical applications. Skeletal Radiol 2010; 39: 1061-1071
  CrossrefPubMedGoogle Scholar
• 422 De Zordo T, Mlekusch SP, Feuchtner GM. et al. Value of contrast-enhanced ultrasound in rheumatoid arthritis. Eur J Radiol 2007; 64: 222-230
  CrossrefPubMedGoogle Scholar
• 423 Taylor PC. The value of sensitive imaging modalities in rheumatoid arthritis. Arthritis Res Ther 2003; 5: 210-213
  CrossrefPubMedGoogle Scholar
• 424 Hermann KG, Backhaus M, Schneider U. et al. Rheumatoid arthritis of the shoulder joint: Comparison of conventional radiography, ultrasound, and dynamic contrast-enhanced magnetic resonance imaging. Arthritis Rheum 2003; 48: 3338-3349
  CrossrefPubMedGoogle Scholar
• 425 Klauser A, Frauscher F, Schirmer M. et al. The value of contrast-enhanced color doppler ultrasound in the detection of vascularization of finger joints in patients with rheumatoid arthritis. Arthritis Rheum 2002; 46: 647-653
  CrossrefPubMedGoogle Scholar
• 426 Fiocco U, Stramare R, Coran A. et al. Vascular perfusion kinetics by contrast-enhanced ultrasound are related to synovial microvascularity in the joints of psoriatic arthritis. Clin Rheumatol 2015; 34: 1903-1912
  CrossrefPubMedGoogle Scholar
• 427 Doria SA, Kiss BMH, Lotito NAP. et al. Juvenile rheumatoid arthritis of the knee: evaluation with contrast-enhanced color Doppler ultrasound. Pediatr Radiol 2001; 31: 524-531
  CrossrefPubMedGoogle Scholar
• 428 Klauser A, Halpern EJ, Frauscher F. et al. Inflammatory low back pain: High negative predictive value of contrast-enhanced color Doppler ultrasound in the detection of inflamed sacroiliac joints. Arthritis Rheum 2005; 53: 440-444
  CrossrefPubMedGoogle Scholar
• 429 Magarelli N, Guglielmi G, Di Matteo L. et al. Diagnostic utility of an echo-contrast agent in patients with synovitis using power Doppler ultrasound: a preliminary study with comparison to contrast-enhanced MRI. Eur Radiol 2001; 11: 1039-1046
  CrossrefPubMedGoogle Scholar
• 430 Klauser A, Demharter J, De Marchi A. et al. Contrast enhanced gray-scale sonography in assessment of joint vascularity in rheumatoid arthritis: results from the IACUS study group. Eur Radiol 2005; 15: 2404-2410
  CrossrefPubMedGoogle Scholar
• 431 Schueller-Weidekamm C, Krestan C, Schueller G. et al. Power Doppler Sonography and Pulse-Inversion Harmonic Imaging in Evaluation of Rheumatoid Arthritis Synovitis. Am J Roentgenol 2007; 188: 504-508
  CrossrefPubMedGoogle Scholar
• 432 Cai XH, Yang SP, Shen HL. et al. Application of contrast-enhanced ultrasonography and ultrasonography scores in rheumatoid arthritis. Int J Clin Exp Med 2015; 8: 20056-20064
  PubMedGoogle Scholar
• 433 Klauser AS, Franz M, Arora R. et al. Detection of vascularity in wrist tenosynovitis: power doppler ultrasound compared with contrast-enhanced grey-scale ultrasound. Arthritis Res Ther 2010; 12: R209
  CrossrefPubMedGoogle Scholar
• 434 Wamser G, Bohndorf K, Vollert K. et al. Power Doppler sonography with and without echo-enhancing contrast agent and contrast-enhanced MRI for the evaluation of rheumatoid arthritis of the shoulder joint: differentiation between synovitis and joint effusion. Skeletal Radiol 2003; 32: 351-359
  CrossrefPubMedGoogle Scholar
• 435 Carotti M, Salaffi F, Manganelli P. et al. Power Doppler sonography in the assessment of synovial tissue of the knee joint in rheumatoid arthritis: a preliminary experience. Ann Rheum Dis 2002; 61: 877-882
  CrossrefPubMedGoogle Scholar
• 436 Hau M, Kneitz C, Tony H. et al. High resolution ultrasound detects a decrease in pannus vascularisation of small finger joints in patients with rheumatoid arthritis receiving treatment with soluble tumour necrosis factor alpha receptor (etanercept). Ann Rheum Dis 2002; 61: 55-58
  CrossrefPubMedGoogle Scholar
• 437 Genovese E, Ronga M, Recaldini C. et al. Analysis of achilles tendon vascularity with second-generation contrast-enhanced ultrasound. J Clin Ultrasound 2011; 39: 141-145
  CrossrefPubMedGoogle Scholar
• 438 Song IH, Althoff CE, Hermann KG. et al. Contrast-enhanced ultrasound in monitoring the efficacy of a bradykinin receptor 2 antagonist in painful knee osteoarthritis compared with MRI. Ann Rheum Dis 2009; 68: 75-83
  CrossrefPubMedGoogle Scholar
• 439 Qvistgaard E, Rogind H, Torp-Pedersen S. et al. Quantitative ultrasonography in rheumatoid arthritis: evaluation of inflammation by Doppler technique. Ann Rheum Dis 2001; 60: 690-693
  CrossrefPubMedGoogle Scholar
• 440 Stramare R, Raffeiner B, Ciprian L. et al. Evaluation of finger joint synovial vascularity in patients with rheumatoid arthritis using contrast-enhanced ultrasound with water immersion and a stabilized probe. J Clin Ultrasound 2012; 40: 147-154
  CrossrefPubMedGoogle Scholar
• 441 Xie XH, Xu HX, Xie XY. et al. Differential diagnosis between benign and malignant gallbladder diseases with real-time contrast-enhanced ultrasound. Eur Radiol 2010; 20: 239-248
  CrossrefPubMedGoogle Scholar
• 442 Tang S, Wang Y, Wang Y. Contrast-enhanced ultrasonography to diagnose gallbladder perforation. Am J Emerg Med 2013; 31: 1240-1243
  CrossrefPubMedGoogle Scholar
• 443 Fei X, Lu WP, Luo YK. et al. Contrast-enhanced ultrasound may distinguish gallbladder adenoma from cholesterol polyps: a prospective caseGÇôcontrol study. Abdom Imaging 2015; 40: 2355-2363
  CrossrefPubMedGoogle Scholar
• 444 Sun LP, Guo LH, Xu HX. et al. Value of contrast-enhanced ultrasound in the differential diagnosis between gallbladder adenoma and gallbladder adenoma canceration. Int J Clin Exp Med 2015; 8: 1115-1121
  PubMedGoogle Scholar
• 445 Liu LN, Xu HX, Lu MD. et al. Contrast-Enhanced Ultrasound in the Diagnosis of Gallbladder Diseases: A Multi-Center Experience. PLoS ONE 2012; 7: e48371
  CrossrefPubMedGoogle Scholar
• 446 Date RS, Thrumurthy SG, Whiteside S. et al. Gallbladder perforation: Case series and systematic review. Int J Surg 2012; 10: 63-68
  CrossrefPubMedGoogle Scholar
• 447 Smith EA, Dillman JR, Elsayes KM. et al. Cross-Sectional Imaging of Acute and Chronic Gallbladder Inflammatory Disease. Am J Roentgenol 2009; 192: 188-196
  CrossrefPubMedGoogle Scholar
• 448 Kawai R, Hata J, Manabe N. et al. Contrast-enhanced ultrasonography with Sonazoid for diagnosis of gangrenous cholecystitis. J Med Ultrason 2016; 43: 193-199
  CrossrefPubMedGoogle Scholar
• 449 Revel L, Lubrano J, Badet N. et al. Preoperative diagnosis of gangrenous acute cholecystitis: usefulness of CEUS. Abdom Imaging 2014; 39: 1175-1181
  CrossrefPubMedGoogle Scholar
• 450 Ripolles T, Martinez-Perez MJ, Martin G. et al. Usefulness of contrast-enhanced US in the diagnosis of acute gangrenous cholecystitis: A comparative study with surgical and pathological findings. Eur J Radiol 2016; 85: 31-38
  CrossrefPubMedGoogle Scholar
• 451 Adamietz B, Wenkel E, Uder M. et al. Contrast enhanced sonography of the gallbladder: A tool in the diagnosis of cholecystitis?. Eur J Radiol 2007; 61: 262-266
  CrossrefPubMedGoogle Scholar
• 452 Shapira-Rootman M, Mahamid A, Reindorp N. et al. Diagnosis of gallbladder perforation by ultrasound. Clin Imaging 2015; 39: 827-829
  CrossrefPubMedGoogle Scholar
• 453 Sagrini E, Pecorelli A, Pettinari I. et al. Contrast-enhanced ultrasonography to diagnose complicated acute cholecystitis. Intern Emerg Med 2016; 11: 19-30
  CrossrefPubMedGoogle Scholar
• 454 Runner GJ, Corwin MT, Siewert B. et al. Gallbladder Wall Thickening. Am J Roentgenol 2013; 202: W1-W12
  PubMedGoogle Scholar
• 455 Xu JM, Guo LH, Xu HX. et al. Differential Diagnosis of Gallbladder Wall Thickening: The-áUsefulness of Contrast-Enhanced Ultrasound. Ultrasound Med Biol 2014; 40: 2794-2804
  CrossrefPubMedGoogle Scholar
• 456 Mellnick VM, Menias CO, Sandrasegaran K. et al. Polypoid Lesions of the Gallbladder: Disease Spectrum with Pathologic Correlation. Radiographics 2015; 35: 387-399
  CrossrefPubMedGoogle Scholar
• 457 Gallahan WC, Conway JD. Diagnosis and Management of Gallbladder Polyps. Gastroenterol Clin North Am 2010; 39: 359-367
  CrossrefPubMedGoogle Scholar
• 458 Corwin MT, Siewert B, Sheiman RG. et al. Incidentally Detected Gallbladder Polyps: Is Follow-up Necessary?GÇöLong-term Clinical and US Analysis of 346 Patients. Radiology 2011; 258: 277-282
  CrossrefPubMedGoogle Scholar
• 459 Aloia TA, J+írufe N, Javle M. et al. Gallbladder Cancer: expert consensus statement. HPB (Oxford) 2015; 17: 681-690
  CrossrefPubMedGoogle Scholar
• 460 Yuan HX, Cao JY, Kong WT. et al. Contrast-enhanced ultrasound in diagnosis of gallbladder adenoma. Hepatobiliary Pancreat Dis Int 2015; 14: 201-207
  CrossrefPubMedGoogle Scholar
• 461 Nabatame N, Shirai Y, Nishimura A. et al. High risk of gallbladder carcinoma in elderly patients with segmental adenomyomatosis of the gallbladder. J Exp Clin Cancer Res 2004; 23: 593-598
  PubMedGoogle Scholar
• 462 Tang S, Huang L, Wang Y. et al. Contrast-enhanced ultrasonography diagnosis of fundal localized type of gallbladder adenomyomatosis. BMC Gastroenterol 2015; 15: 99
  CrossrefPubMedGoogle Scholar
• 463 Levy AD, Murakata LA, Rohrmann CA. Gallbladder Carcinoma: Radiologic-Pathologic Correlation. Radiographics 2001; 21: 295-314
  CrossrefPubMedGoogle Scholar
• 464 Stinton LM, Shaffer EA. Epidemiology of Gallbladder Disease: Cholelithiasis and Cancer. Gut Liver 2012; 6: 172-187
  CrossrefPubMedGoogle Scholar
• 465 Meacock LM, Sellars ME, Sidhu PS. Evaluation of Gall Bladder and Biliary Duct Disease Using Microbubble Contrast Enhanced Ultrasound. Br J Radiol 2010; 83: 615-627
  CrossrefPubMedGoogle Scholar
• 466 Yoon WJ, Yoon YB, Kim YJ. et al. Metastasis to the gallbladder: A single-center experience of 20 cases in South Korea. World J Gastroenterol 2009; 15: 4806-4809
  CrossrefPubMedGoogle Scholar
• 467 Barretta ML, Catalano O, Setola SV. et al. Gallbladder metastasis: spectrum of imaging findings. Abdom Imaging 2011; 36: 729-734
  CrossrefPubMedGoogle Scholar
• 468 Engelhardt M, Hansen C, Eyding J. et al. Feasibility of Contrast-Enhanced Sonography During Resection of Cerebral Tumours: Initial Results of a Prospective Study. Ultrasound Med Biol 2007; 33: 571-575
  CrossrefPubMedGoogle Scholar
• 469 He W, Jiang X, Wang S. et al. Intraoperative contrast-enhanced ultrasound for brain tumors. Clin Imaging 2008; 32: 419-424
  CrossrefPubMedGoogle Scholar
• 470 Holscher T, Ozgur B, Singel S. et al. Introoperative ultrasound using phase inversion harmonic imaging: first experiences. Neurosurgery 2007; 60: 382-386
  CrossrefPubMedGoogle Scholar
• 471 Kanno H, Ozawa Y, Sakata K. et al. Intraoperative power Doppler ultrasonography with a contrast-enhancing agent for intracranial tumors. J Neurosurg 2005; 102: 295-301
  CrossrefPubMedGoogle Scholar
• 472 Prada F, Del Bene M, Moiraghi A. et al. From Grey Scale B-Mode to Elastosonography: Multimodal Ultrasound Imaging in Meningioma SurgeryGÇöPictorial Essay and Literature Review. Biomed Res Int 2015; 2015: 925729
  PubMedGoogle Scholar
• 473 Prada F, Del Bene M, Saini M. et al. Intraoperative cerebral angiosonography with ultrasound contrast agents: how I do it. Acta Neurochir (Wein) 2015; 157: 1025-1029
  CrossrefPubMedGoogle Scholar
• 474 Prada F, Perin A, Martegani A. et al. Intraoperative Contrast-Enhanced Ultrasound for Brain Tumor Surgery. Neurosurgery 2014; 74: 542-552
  CrossrefPubMedGoogle Scholar
• 475 He W, Wang L, Li HZ. et al. Intraoperative contrast-enhanced ultrasound in traumatic brain surgery. Clin Imaging 2013; 37: 983-988
  CrossrefPubMedGoogle Scholar
• 476 Arlt F, Chalopin C, Muns A. et al. Intraoperative 3D contrast-enhanced ultrasound (CEUS): a prospective study of 50 patients with brain tumours. Acta Neurochir (Wein) 2016; 158: 685-694
  CrossrefPubMedGoogle Scholar
• 477 Prada F, Bene MD, Fornaro R. et al. Identification of residual tumor with intraoperative contrast-enhanced ultrasound during glioblastoma resection. Neurosurg Focus 2016; 40: E7
  CrossrefPubMedGoogle Scholar
• 478 Lekht I, Brauner N, Bakhsheshian J. et al. Versatile utilization of real-time intraoperative contrast-enhanced ultrasound in cranial neurosurgery: technical note and retrospective case series. Neurosurg Focus 2016; 40: E6
  CrossrefPubMedGoogle Scholar
• 479 Prada F, Mattei L, Del Bene M. et al. Intraoperative Cerebral Glioma Characterization with Contrast Enhanced Ultrasound. Biomed Res Int 2014; 2014: 484261
  PubMedGoogle Scholar
• 480 Prada F, Bene MD, Casali C. et al. Intraoperative Navigated Angiosonography for Skull Base Tumor Surgery. World Neurosurg 2015; 84: 1699-1707
  CrossrefPubMedGoogle Scholar
• 481 Huang DY, Yusuf GT, Daneshi M. et al. Contrast-enhanced US guided Interventions: Improving Success Rate and Avoiding Complications Using US Contrast Agents. Radiographics 2016; 37: 652-664
  PubMedGoogle Scholar
• 482 Bang N, Bachmann Nielsen M, Vejborg I. et al. Clinical report: contrast enhancement of tumor perfusion as a guidance for biopsy. Eur J Ultrasound 2000; 12: 159-161
  CrossrefPubMedGoogle Scholar
• 483 Wu W, Chen MH, Yin SS. et al. The Role of Contrast-Enhanced Sonography of Focal Liver Lesions Before Percutaneous Biopsy. Am J Roentgenol 2006; 187: 752-761
  CrossrefPubMedGoogle Scholar
• 484 Wang S, Yang W, Zhang H. et al. The Role of Contrast-Enhanced Ultrasound in Selection Indication and Improveing Diagnosis for Transthoracic Biopsy in Peripheral Pulmonary and Mediastinal Lesions. Biomed Res Int 2015; 2015: 231782
  PubMedGoogle Scholar
• 485 Cao BS, Wu JH, Li XL. et al. Sonographically Guided Transthoracic Biopsy of Peripheral Lung and Mediastinal Lesions: Role of Contrast-Enhanced Sonography. J Ultrasound Med 2011; 30: 1479-1490
  CrossrefPubMedGoogle Scholar
• 486 Sparchez Z, Radu P, Kasco G. et al. Contrast-enhanced ultrasound guided biopsy of superficial toraco-abdominal and neck lesions. Initial experience in 20 patients. Med Ultrason 2012; 14: 288-293
  PubMedGoogle Scholar
• 487 De Marchi A, Brach del Prever EM, Linari A. et al. Accuracy of core-needle biopsy after contrast-enhanced ultrasound in soft-tissue tumours. Eur Radiol 2010; 20: 2740-2748
  CrossrefPubMedGoogle Scholar
• 488 Loizides A, Widmann G, Freuis T. et al. Optimizing Ultrasound-Guided Biopsy of Musculoskeletal Masses by Application of an Ultrasound Contrast Agent. Ultraschall in Med 2011; 32: 307-310
  Article in Thieme ConnectPubMedGoogle Scholar
• 489 Schlottmann K, Klebl F, Zorger N. et al. Contrast-Enhanced Ultrasound Allows for-áInterventions of Hepatic Lesions which are Invisible on-Conventional B-Mode. Z Gastroenterol 2004; 42: 303-310
  Article in Thieme ConnectPubMedGoogle Scholar
• 490 Yoon SH, Lee KH, Kim SY. et al. Real-time contrast-enhanced ultrasound-guided biopsy of focal hepatic lesions not localised on B-mode ultrasound. Eur Radiol 2010; 20: 2047-2056
  CrossrefPubMedGoogle Scholar
• 491 Tang J, Zhang H, Lv F. et al. Percutaneous Injection Therapy for Blunt Splenic Trauma Guided by Contrast-Enhanced Ultrasonography. J Ultrasound Med 2008; 27: 925-932
  PubMedGoogle Scholar
• 492 Tokunaga S, Koda M, Kato J. et al. Assessment of Track Microbubble Flow Signals on Contrast-enhanced Ultrasound with Perflubutane Following Percutaneous Liver Biopsy. Intern Med 2013; 52: 1455-1459
  CrossrefPubMedGoogle Scholar
• 493 Lorentzen T, Nolsoe CP, Ewertsen C. et al. EFSUMB guidelines on interventional ultrasound (INVUS), Part I general aspects (short version). Ultraschall in Med 2015; 36: 461-472
  PubMedGoogle Scholar
• 494 Wink MH, Lagerveld BW, Laguna MP. et al. Cryotherapy for Renal-Cell Cancer: Diagnosis, Treatment, and Contrast-Enhanced Ultrasonography for Follow-Up. J Endourol 2006; 20: 456-459
  CrossrefPubMedGoogle Scholar
• 495 Johnson DB, Duchene DA, Taylor GD. et al. Contrast-Enhanced Ultrasound Evaluation of Radiofrequency Ablation of the Kidney: Reliable Imaging of the Thermolesion. J Endourol 2005; 19: 248-252
  CrossrefPubMedGoogle Scholar
• 496 Campbell SC, Novick AC, Belldegrun A. et al. Guideline for Management of the Clinical T1 Renal Mass. J Urol 2009; 182: 1271-1279
  CrossrefPubMedGoogle Scholar
• 497 Ignee A, Straub B, Schuessler G. et al. Contrast enhanced ultrasound of renal masses. World J Radiol 2010; 2: 15-31
  CrossrefPubMedGoogle Scholar
• 498 Hoeffel C, Pousset M, Timsit MO. et al. Radiofrequency ablation of renal tumours: diagnostic accuracy of contrast-enhanced ultrasound for early detection of residual tumour. Eur Radiol 2010; 20: 1812-1821
  CrossrefPubMedGoogle Scholar
• 499 Meloni MF, Bertolotto M, Alberzoni C. et al. Follow-Up After Percutaneous Radiofrequency Ablation of Renal Cell Carcinoma: Contrast-Enhanced Sonography Versus Contrast-Enhanced CT or MRI. Am J Roentgenol 2008; 191: 1233-1238
  CrossrefPubMedGoogle Scholar
• 500 Meloni MF, Smolock A, Cantisani V. et al. Contrast enhanced ultrasound in the evaluation and percutaneous treatment of hepatic and renal tumors. Eur J Radiol 2015; 84: 1666-1674
  CrossrefPubMedGoogle Scholar
• 501 Oh TH, Lee YH, Seo IY. Diagnostic Efficacy of Contrast-Enhanced Ultrasound for Small Renal Masses. Korean J Urol 2014; 55: 587-592
  CrossrefPubMedGoogle Scholar
• 502 Ascenti G, Gaeta M, Magno C. et al. Contrast-Enhanced Second-Harmonic Sonography in the Detection of Pseudocapsule in Renal Cell Carcinoma. Am J Roentgenol 2004; 182: 1525-1530
  CrossrefPubMedGoogle Scholar
• 503 Li X, Liang P, Yu J. et al. Role of contrast-enhanced ultrasound in evaluating the efficiency of ultrasound guided percutaneous microwave ablation in patients with renal cell carcinoma. Radiol Oncol 2013; 47: 398-404
  CrossrefPubMedGoogle Scholar
• 504 Kong WT, Zhang WW, Guo HQ. et al. Application of contrast-enhanced ultrasonography after radiofrequency ablation for renal cell carcinoma: is it sufficient for assessment of therapeutic response?. Abdom Imaging 2011; 36: 342-347
  CrossrefPubMedGoogle Scholar
• 505 Zhao X, Wang W, Zhang S. et al. Improved outcome of percutaneous radiofrequency ablation in renal cell carcinoma: a retrospective study of intraoperative contrast-enhanced ultrasonography in 73 patients. Abdom Imaging 2012; 37: 885-891
  CrossrefPubMedGoogle Scholar
• 506 Barwari K, Wijkstra H, van Delden OM. et al. Contrast-Enhanced Ultrasound for the Evaluation of the Cryolesion After Laparoscopic Renal Cryoablation: An Initial Report. J Endourol 2012; 27: 402-407
  PubMedGoogle Scholar
• 507 Murat FJ, Poissonnier L, Rabilloud M. et al. Mid-term Results Demonstrate Salvage High-Intensity Focused Ultrasound (HIFU) as an Effective and Acceptably Morbid Salvage Treatment Option for Locally Radiorecurrent Prostate Cancer. Eur Urol 2009; 55: 640-649
  CrossrefPubMedGoogle Scholar
• 508 Rouviere O, Glas L, Girouin N. et al. Prostate Cancer Ablation with Transrectal High-Intensity Focused Ultrasound: Assessment of Tissue Destruction with Contrast-enhanced US. Radiology 2011; 259: 583-591
  CrossrefPubMedGoogle Scholar
• 509 Lei F, Jing Z, Bo W. et al. Uterine myomas treated with microwave ablation: The agreement between ablation volumes obtained from contrast-enhanced sonography and enhanced MRI. Int J Hyperthermia 2014; 30: 11-18
  CrossrefPubMedGoogle Scholar
• 510 Orsi F, Monfardini L, Bonomo G. et al. Ultrasound guided high intensity focused ultrasound (USgHIFU) ablation for uterine fibroids: Do we need the microbubbles?. Int J Hyperthermia 2015; 31: 233-239
  CrossrefPubMedGoogle Scholar
• 511 Peng S, Hu L, Chen W. et al. Intraprocedure contrast enhanced ultrasound: The value in assessing the effect of ultrasound-guided high intensity focused ultrasound ablation for uterine fibroids. Ultrasonics 2015; 58: 123-128
  CrossrefPubMedGoogle Scholar
• 512 Wang F, Zhang J, Han ZY. et al. Imaging manifestation of conventional and contrast-enhanced ultrasonography in percutaneous microwave ablation for the treatment of uterine fibroids. Eur J Radiol 2012; 81: 2947-2952
  CrossrefPubMedGoogle Scholar
• 513 Ignee A, Jenssen C, Cui XW. et al. Intracavitary contrast-enhanced ultrasound in abscess drainage – feasibility and clinical value. Scand J Gastroenterol 2016; 51: 41-47
  CrossrefPubMedGoogle Scholar
• 514 Lanzani C, Savasi V, Leone FP. et al. Two-dimensional HyCoSy with contrast tuned imaging technology and a second generation contrast media for the assessment of tubal patency in an infertility program. Fertil-Steril 2009; 92: 1158-1161
  PubMedGoogle Scholar
• 515 Boudghene FP, BAzot M, Robert Y. et al. Assessment of fallopian tube patency by HyCoSy: comparison of a positive contrast agent with saline solution. Ultrasound Obstet Gynecol 2001; 18: 525-530
  CrossrefPubMedGoogle Scholar
• 516 Tamasi F, Weidner A, Domokos N. et al. ECHOVIST-200 enhanced hystero-sonography. Eur J Obstet Gynecol Reprod Biol 2005; 121: 186-190
  CrossrefPubMedGoogle Scholar
• 517 Foschi FG, Piscaglia F, Pompili M. et al. Real-Time Contrast-Enhanced Ultrasound GÇô a-áNew-áSimple Tool for Detection of Peritoneal-Pleural Communications in Hepatic Hydrothorax. Ultraschall in Med 2008; 29: 538-542
  Article in Thieme ConnectPubMedGoogle Scholar
• 518 Matono T, Koda M, Murawaki Y. Right diaphragmatic defect in hepatic hydrothorax exposed by contrast-enhanced ultrasonography after radiofrequency ablation. Hepatology 2016; 56: 784-785
  PubMedGoogle Scholar
• 519 Tamano M, Hashimoto T, Kojima K. et al. Diagnosis of hepatic hydrothorax using contrast-enhanced ultrasonography with intraperitoneal injection of Sonazoid. J Gastroenterol Hepatol 2010; 25: 383-386
  CrossrefPubMedGoogle Scholar
• 520 Ignee A, Baum U, Schuessler G. et al. Contrast-enhanced ultrasound-guided percutaneous cholangiography and cholangiodrainage (CEUS-PTCD). Endoscopy 2009; 41: 725-726
  Article in Thieme ConnectPubMedGoogle Scholar
• 521 Urade T, Fukumoto T, Tanaka M. et al. Contrast-Enhanced Intraoperative Ultrasonic Cholangiography for Real-Time Biliary Navigation in Hepatobiliary Surgery. J Am Coll Surg 2014; 218: e43-e50
  CrossrefPubMedGoogle Scholar
• 522 Chopra SS, Eisele R, Seehofer D. et al. Contrast enhanced ultrasound cholangiography via T-tube following liver transplantation. Ann Transplant 2012; 17: 108-112
  PubMedGoogle Scholar
• 523 Daneshi M, Rajayogeswaran B, Peddu P. et al. Demonstration of an ocult biliary-arterial fistula using percutaneous contrast-enhanced ultrasound cholangiography in a transplanted liver. J Clin Ultrasound 2014; 42: 108-111
  CrossrefPubMedGoogle Scholar
• 524 Mao R, Xu EJ, Li K. et al. Usefulness of contrast-enhanced ultrasound in the diagnosis of biliary leakage following T-tube removal. J Clin Ultrasound 2010; 38: 38-40
  PubMedGoogle Scholar
• 525 Xu EJ, Mao R, Zheng RQ. et al. Three-dimensional contrast-enhanced ultrasonic cholangiography: a new technique for delineation of the biliary tract in a liver donor. Liver Transpl 2009; 15: 1154-1156
  CrossrefPubMedGoogle Scholar
• 526 Zheng RQ, Chen G, Xu EJ. et al. Evaluating Biliary Anatomy and Variations in Living Liver Donors by a New Technique: Three-Dimensional Contrast-Enhanced Ultrasonic Cholangiography. Ultrasound Med Biol 2010; 36: 1282-1287
  CrossrefPubMedGoogle Scholar
• 527 Velosa M, Lopes S, Castro R. et al. Cholecystoduodenal fistula diagnosed with contrast-enhanced endoscopic ultrasound. Endoscopy 2013; 45: E18-E19
  Article in Thieme ConnectPubMedGoogle Scholar
• 528 Zuber-Jerger I, Endlicher E, Schälmerich J. et al. Endoscopic retrograde cholangiography with contrast ultrasonography. Endoscopy 2008; 40 (Suppl. 02) E202
  Article in Thieme ConnectPubMedGoogle Scholar
• 529 Cui XW, Ignee A, Maros T. et al. Feasibility and Usefulness of Intra-cavitary Contrast-Enhanced Ultrasound in Percutaneous Nephrostomy. Ultrasound Med Biol 2016; 42: 2180-2188
  CrossrefPubMedGoogle Scholar
• 530 Chi T, Usawachintachit M, Mongan J. et al. Feasibility of Antegrade Contrast-enhanced US Nephrostograms to Evaluate Ureteral Patency. Radiology 2016; 283: 273-279
  PubMedGoogle Scholar
• 531 Zengel P, Berghaus A, Weiler C. et al. Intraductally applied contrast-enhanced ultrasound (IA-CEUS) for evaluating obstructive disease and secretory dysfunction of the salivary glands. Eur Radiol 2011; 21: 1339-1348
  CrossrefPubMedGoogle Scholar
• 532 Zengel P, Siedek V, Berghaus A. et al. Intraductally applied contrast-enhanced ultrasound (IA-CEUS) for improved visualization of obstructive diseases of the salivary glands, primary results. Clin Hemorheol Microcirc 2010; 45: 193-295
  PubMedGoogle Scholar
• 533 Chew SS, Yang JL, Newstead GL. et al. Analfistula: Levovist-enhanced endoanal ultrasound: a pilot study. Dis Colon Rectum 2003; 46: 377-384
  CrossrefPubMedGoogle Scholar
• 534 Chen YJ, Mao R, Xie XH. et al. Intracavitary Contrast-enhanced Ultrasonography to Detect Enterovesical Fistula in Crohns Disease. Gastroenterology 2016; 150: 315-317
  CrossrefPubMedGoogle Scholar
• 535 Volkmer BG, Nesslauer T, Kufer R. et al. Diagnostik von Harnblasen-Darm-Fisteln durch kontrastmittelunterstetzte 3D-Sonographie. Ultraschall in Med 2001; 22: 81-86
  Article in Thieme ConnectPubMedGoogle Scholar
• 536 Girlich C, Buttner R, Schacherer D. et al. Kontrastmittelsonografische Drainagenkontrolle: eine Feasibility-Studie. Z Gastroenterol 2011; 49: 1470-1474
  Article in Thieme ConnectPubMedGoogle Scholar
• 537 Muller T, Blank W, Leitlein J. et al. Endocavitary contrast-enhanced ultrasound: A technique whose time has come?. J Clin Ultrasound 2015; 43: 71-80
  CrossrefPubMedGoogle Scholar
• 538 Prantl L, Pfister K, Kubale R. et al. Value of high resolution ultrasound and contrast enhanced US pulse inversion imaging for teh evaluation of the vascular integrity of free-flap grafts. Clin Hemorheol Microcirc 2007; 36: 203-216
  PubMedGoogle Scholar
• 539 Gardiner MD, Nanchahal J. Strategies to ensure success of microvascular free tissue transfer. J Plast Reconstr Aesthet Surg 2010; 63: e665-e673
  CrossrefPubMedGoogle Scholar
• 540 Prantl L, Schmitt S, Geis S. et al. Contrast harmonic ultrasound and indocyanine-green fluorescence video angiography for evaluation of dermal and subdermal microcirculation in free parascapular flaps. Clin Hemorheol Microcirc 2016; 38: 105-118
  PubMedGoogle Scholar
• 541 Prantl L, Schremi S, Walter M. et al. Evaluation of microcirculation of free flaps of the lower leg by contrast harmonic imaging (CHI) with time intensity curve (TIC) analysis. Clin Hemorheol Microcirc 2008; 39: 343-350
  PubMedGoogle Scholar
• 542 Geis S, Prantl L, Dolderer J. et al. Postoperative Monitoring of Local and Free Flaps with Contrast-Enhanced Ultrasound (CEUS) – Analysis of 112 Patients. Ultraschall in Med 2013; 34: 550-558
  Article in Thieme ConnectPubMedGoogle Scholar
• 543 Jung EM, Prantl L, Schreyer AG. et al. New perfusion imaging of tissue transplants with contrast harmonic ultrasound imaging (CHI) and magnetic resonance imaging (MRI) in comparison with laser-induced indocyanine green (ICG) fluorescence angiography. Clin Hemorheol Microcirc 2009; 43: 19-33
  PubMedGoogle Scholar
• 544 Geis S, Prantl L, Gehmert S. et al. TTP (time to peak) and RBV (regional blood volume) as valuable parameters to detect early flap failure. Clin Hemorheol Microcirc 2011; 48: 81-94
  PubMedGoogle Scholar
• 545 Lamby P, Prantl L, Schreml S. et al. Improvements in high resolution ultrasound for postoperative investigation of capillary microperfusion after free tissue transfer. Clin Hemorheol Microcirc 2009; 43: 35-49
  PubMedGoogle Scholar
• 546 Prantl L, Fellner C, Jung ME. Evaluation of Free Flap Perfusion with Dynamic Contrast-Enhanced Magnetic Resonance Imaging. Plastic and Reconstructive Surgery 2010; 126: 100e-1011e
  CrossrefPubMedGoogle Scholar
• 547 Lamby P, Prantl L, Fellner C. et al. Post-operative monitoring of tissue transfers: advantages using contrast enhanced ultrasound(CEUS) and contrastMRI (ceMRI) with dynamic perfusion analysis?. Clin Hemorheol Microcirc 2011; 48: 105-117
  PubMedGoogle Scholar
• 548 Selber JC, Garvey PB, Clemens MW. et al. A Prospective Study of Transit-Time Flow Volume Measurement for Intraoperative Evaluation and Optimization of Free Flaps. Plast Reconstr Surg 2013; 131: 270-281
  CrossrefPubMedGoogle Scholar
• 549 Mirzabeigi MN, Wang T, Kovach SJ. et al. Free Flap Take-Back following Postoperative Microvascular Compromise: Predicting Salvage versus Failure. Plast Reconstr Surg 2012; 130: 579-589
  CrossrefPubMedGoogle Scholar
• 550 Reissig A, Copetti R, Mathis G. et al. Lung Ultrasound in the Diagnosis and Follow-up of Community-Acquired Pneumonia: A Prospective, Multicenter, Diagnostic Accuracy Study. Chest 2012; 142: 965-972
  CrossrefPubMedGoogle Scholar
• 551 Nazerian P, Vanni S, Volpicelli G. et al. Accuracy of Point-of-Care Multiorgan Ultrasonography for the Diagnosis of Pulmonary Embolism. Chest 2014; 145: 950-957
  CrossrefPubMedGoogle Scholar
• 552 Volpicelli G, Silva F, Radeos M. Real-time lung ultrasound for the diagnosis of alveolar consolidation and interstitial syndrome in the emergency department. Eur J Emerg Med 2010; 17: 63-72
  CrossrefPubMedGoogle Scholar
• 553 Mathis G, Blank W, Reissig A. et al. Thoracic Ultrasound for Diagnosing Pulmonary Embolism: A Prospective Multicenter Study of 352 Patients. Chest 2005; 128: 1531-1538
  CrossrefPubMedGoogle Scholar
• 554 Sartori S, Postorivo S, Vece FD. et al. Contrast-enhanced ultrasonography in peripheral lung consolidations: Whats its actual role?. World J Radiol 2013; 5: 372-380
  CrossrefPubMedGoogle Scholar
• 555 Bartelt S, Trenker C, Gorg C. et al. Contrast-enhanced ultrasound of embolic consolidations in patients with pulmonary embolism: A pilot study. J Clin Ultrasound 2016; 44: 129-135
  CrossrefPubMedGoogle Scholar
• 556 Gorg C, Bert T, Kring R. et al. Transcutaneous contrast enhanced sonography of the chest for evaluation of pleural based pulmonary lesions: experience in 137 patients. Ultraschall in Med 2006; 27: 437-444
  Article in Thieme ConnectPubMedGoogle Scholar
• 557 Linde HN, Holland A, Greene BH. et al. Kontrastunterstzte Sonografie (CEUS) bei Pneumonie: Darstellungsmuster und prognostische Bedeutung eine retrospektive Studie bei 50 Patienten. Ultraschall in Med 2012; 33: 146-151
  Article in Thieme ConnectPubMedGoogle Scholar
• 558 Sartori S, Nielsen I, Trevisani L. et al. Contrast-Enhanced Sonography as Guidance for Transthoracic Biopsy of a Peripheral Lung Lesion With Large Necrotic Areas. J Ultrasound Med 2004; 23: 133-136
  CrossrefPubMedGoogle Scholar
• 559 Gorg C, Bert T, Kring R. Contrast-Enhanced Sonography of the Lung for Differential Diagnosis of Atelectasis. J Ultrasound Med 2006; 25: 35-39
  CrossrefPubMedGoogle Scholar
• 560 Tozer GM. Measuring tumour vascular response to antivascular and antiangiogenic drugs. Br J Radiol 2003; 76: S23-S35
  CrossrefPubMedGoogle Scholar
• 561 Eisenhauer EA, Therasse P, Bogaerts J. et al. New response evaluation criteria in solid tumours: Revised RECIST guideline (version 1.1). Eur J Cancer 2009; 45: 228-247
  CrossrefPubMedGoogle Scholar
• 562 Zhu AX, Holalkere NS, Muzikansky A. et al. Early Antiangiogenic Activity of Bevacizumab Evaluated by Computed Tomography Perfusion Scan in Patients with Advanced Hepatocellular Carcinoma. Oncologist 2008; 13: 120-125
  CrossrefPubMedGoogle Scholar
• 563 Dietrich CF, Averkiou MA, Correas JM. et al. An introduction into dynamic contrast-enhanced ultrasound (DCE-US) for quantification of tissue perfusion. Ultraschall in Med 2012; 33: 344-351
  Article in Thieme ConnectPubMedGoogle Scholar
• 564 Peronneau P, Lassau N, Leguerney I. et al. Contrast Ultrasonography: Necessity of Linear Data-áProcessing for the Quantification of Tumor Vascularization. Ultraschall in Med 2010; 31: 370-378
  Article in Thieme ConnectPubMedGoogle Scholar
• 565 Averkiou M, Lampaskis M, Kyriakopoulou K. et al. Quantification of Tumor Microvascularity with Respiratory Gated Contrast Enhanced Ultrasound for Monitoring Therapy. Ultrasound Med Biol 2010; 36: 68-77
  CrossrefPubMedGoogle Scholar
• 566 Williams R, Hudson JM, Lloyd BA. et al. Dynamic Microbubble Contrast-enhanced US to Measure Tumor Response to Targeted Therapy: A Proposed Clinical Protocol with Results from Renal Cell Carcinoma Patients Receiving Antiangiogenic Therapy. Radiology 2011; 260: 581-590
  CrossrefPubMedGoogle Scholar
• 567 Lassau N, Lamuraglia M, Vanel D. et al. Doppler US with perfusion software and contrast medium injection in the early evaluation of isolated limb perfusion of limb sarcomas: prospective study of 49 cases. Ann Oncol 2005; 16: 1054-1060
  CrossrefPubMedGoogle Scholar
• 568 Cosgrove D, Lassau N. Imaging of perfusion using ultrasound. Eur J Nucl Med Mol Imaging 2010; 37: 65-85
  CrossrefPubMedGoogle Scholar
• 569 Lamuraglia M, Escudier B, Chami L. et al. To predict progression-free survival and overall survival in metastatic renal cancer treated with sorafenib: Pilot study using dynamic contrast-enhanced Doppler ultrasound. Eur J Cancer 2006; 42: 2472-2479
  CrossrefPubMedGoogle Scholar
• 570 Lassau N, Lamuraglia M, Chami L. et al. Gastrointestinal Stromal Tumors Treated with Imatinib: Monitoring Response with Contrast-Enhanced Sonography. Am J Roentgenol 2006; 187: 1267-1273
  CrossrefPubMedGoogle Scholar
• 571 De Giorgi U, Aliberti C, Benea G. et al. Effect of Angiosonography to Monitor Response During Imatinib Treatment in Patients with Metastatic Gastrointestinal Stromal Tumors. Clin Cancer Res 2005; 11: 6171-6176
  CrossrefPubMedGoogle Scholar
• 572 Escudier B, Lassau N, Angevin E. et al. Phase I trial of sorafenib in combination with IFN alpsh-2a in patients with unresectable and/or metastatic renal cell carcinoma or malgnant melanoma. Clin Cancer Res 2007; 15: 1801-1809
  PubMedGoogle Scholar
• 573 Lassau N, Koscielny S, Albiges L. et al. Metastatic Renal Cell Carcinoma Treated with Sunitinib: Early Evaluation of Treatment Response Using Dynamic Contrast-Enhanced Ultrasonography. Clin Cancer Res 2010; 16: 1216-1225
  CrossrefPubMedGoogle Scholar
• 574 Lassau N, Chami L, Koscielny S. et al. Quantitative functional imaging by Dynamic Contrast Enhanced Ultrasonography (DCE-US) in GIST patients treated with masatinib. Invest New Drugs 2012; 30: 765-771
  CrossrefPubMedGoogle Scholar
• 575 Lassau N, Koscienly S, Chami L. et al. Advanced hepatocellular carcinoma: early evaluation of response to bevacizumab therapy at dynamic contrast-enhanced US with quantification – preliminary results. Radiology 2011; 258: 291-300
  CrossrefPubMedGoogle Scholar
• 576 Lassau N, Chapotot L, Benatsou B. et al. Standardization of Dynamic Contrast-Enhanced Ultrasound for the Evaluation of Antiangiogenic Therapies: The French Multicenter Support for Innovative and Expensive Techniques Study. Invest Radiol 2012; 47: 711-716
  CrossrefPubMedGoogle Scholar
• 577 Lassau N, Bonastre J, Kind M. et al. Validation of Dynamic Contrast-Enhanced Ultrasound in Predicting Outcomes of Antiangiogenic Therapy for Solid Tumors: The French Multicenter Support for Innovative and Expensive Techniques Study. Invest Radiol 2014; 49: 794-800
  CrossrefPubMedGoogle Scholar
• 578 Casali PG, Blay JY. On behalf of the ESMO/CONTICANET/EUROBONET Consensus Panel of Experts. Gastrointestinal stromal tumours: ESMO Clinical Practice Guidelines for diagnosis, treatment and follow-up. Ann Oncol 2010; 21: v98-v102
  CrossrefPubMedGoogle Scholar