Diagnosis and assessment of “pleural effusion” (extent, type, puncture site)
Diagnosis and differentiation of hemothorax, pleural empyema
Diagnosis and assessment pleurisy
Diagnostics pneumothorax
Diagnosis and assessment of pleural diseases and pleural space lesions (parietal,
visceral, including differentiation of solid, cystic, fluid)
Diagnosis and assessment of subpleural consolidations
Diagnostics and differentiation of artifacts
Direct ultrasound signs are superior to artifact assessment
Limits of sonography diagnostics
Introduction
The CME review presented here explains the significance of pleural sonography and
provides guidance in its application. Given the resolution of the devices used during
the early days of sonography, in the 1980 s, the pleura could only be perceived as
a white line. Due to the high impedance differences, the pleura can be particularly
well delineated. The advent of high-resolution devices of more than 10 MHz, allowed
even a normal pleura with a thickness of 0.2 mm to be assessed. This article presents
the specifics of the examination technique with knowledge of pretest probability and
describes the indications for pleural sonography. Pleural sonography is of great importance
in emergency and intensive care medicine, as well as prehospital, outpatient and inpatient
settings, the family practice and the specialty practice of the pulmonologist. Specific
pleural sonography pediatric [1 ]
[2 ]
[3 ] as well as geriatric features are described. The ability to identify pneumothorax,
even in difficult situations, and the evaluation of a pleural effusion are also presented.
Because of today's high-resolution technology, both the pleura itself and small subpleural
changes can be assessed and diagnosed. Direct and indirect sonographic signs and concomitants
symptoms are described, and the specific clinical value of sonography presented. The
significance and criteria of conventional brightness-encoded B-scan, color Doppler
ultrasound (CDS) with or without spectral analysis of the Doppler signal (SDS), and
contrast-enhanced ultrasound (CEUS) are outlined [4 ]
[5 ]
[6 ]
[7 ]
[8 ]
[9 ]
[10 ]
[11 ]. Elastography [12 ] and ultrasound-guided interventions are also mentioned. One related other paper
deals with the diseases of the lung parenchyma [13 ] and another paper deals with the diseases of the thoracic wall, diaphragm and mediastinum
[14 ].
A variety of sonographic techniques are available for diagnosis and intervention.
Pretest probability and questioning
Pretest probability and questioning
Pretest probability for pleural and lung ultrasound (LUS) describes the probability
of having a specific pleural or lung disease before performing an additional diagnostic
procedure such as LUS. Whether LUS can correctly identify pleural or pulmonary disease
in a patient depends on the probability of it being a pre-existing condition in the
patient examined (a priori probability), as well as the intrinsic advantages and disadvantages
of the test and therefore the pertinent questions to ask to allow an evidence-based
approach. Sonography with knowledge of symptomatology and medical history is not without
error, and certain findings may be misinterpreted as disease (false-positive result),
or disease may not be correctly identified (false-negative result).
Considering the pre-test probability and specific examination question is essential
for the success of LUS.
Advantages and disadvantages of sonography
Advantages and disadvantages of sonography
Advantages
Basically, LUS is the consistent imaging continuation of the percussion and auscultation
findings of the chest in the sense of “ultrasound the stethoscope of the future” [15 ]. Important advantages include real-time examination, bedside implementation repeatable
at any time, lack of radiation exposure, high spatial resolution in the near-field
region, conclusions about perfusion using CDS, spectral analysis, and CEUS, and safe
imaging guidance of interventions. Basically, sonography represents a “dialogic” examination
method [16 ].
In patients with dyspnea, lung and pleural ultrasonography is often sufficient for
treatment decisions.
In patients with oncologic issues, computed tomography is the method of choice for
staging, and ultrasound is used as an adjunct to address specific questions.
Disadvantages
Relevant disadvantages are limited imaging of pulmonary pathologies due to total reflection
at the lung surface resulting in artefacts, echoes triggered behind bony structures,
lack of overview, lack of imaging of central hilar pathologies and limited ability
to assess patients in the supine position. It is estimated that only about 70 percent
of the pleura can be seen due to its bony surroundings.
Pleura
Examination technique
Some diagnostic questions can be answered with a focused examination guided by localized
symptomatology, but the majority of indications for LUS require a systematic and fundamentally
bilateral comparative examination approach. The specific protocols depend on both
the specific question and the clinical patient situation. If an examination is only
possible in the supine position (e. g., for patients on ventilators) and if pneumothorax
or an interstitial syndrome is suspected, an 8-region protocol with bilateral examination
ventral-cranial, ventral-caudal, lateral-cranial, and lateral-caudal is recommended.
In contrast, for semi-quantification of the interstitial syndrome, examination of
28 intercostal spaces is preferred [17 ]
[18 ]
[19 ]
[20 ]. In patients with suspected (COVID-19) pneumonia and pulmonary artery embolism,
examination of the dorsal portions of the lungs is important, and consideration must
be given to the small size of peripheral lung consolidations. Therefore, a protocol
with 14 scan regions was proposed, including 3 dorsal-paravertebral regions on both
sides in addition to the mentioned 8 ventral and lateral lung regions [21 ]. Further modifications have been described: A 4-region protocol (ventral-cranial
+ lateral-caudal on both sides), a 6-region protocol (3 scan zones each from ventral-cranial
to median mid-chest to lateral-caudal on both sides), and a 12-region protocol with
3 cranial and 3 caudal scan zones each (parasternal, anterior axillary, and posterior
axillary), which takes into account the fact that COVID-19 patients and those with
ventilatory insufficiency can often only be examined in the supine position [8 ]
[22 ]. This diversity of protocols makes it difficult to compare study results, findings,
and scores. It is therefore recommended that the examination protocol used be indicated
in the report and, if possible, that only one standard protocol be used at any given
facility.
Another problem is that the expression of certain diagnostic artifacts of lung and
pleural sonography, especially vertical artifacts, depends on the selected transducer
(especially central frequency and bandwidth), instrument settings or presets, focus,
time-gain compensation (TGC), and the use of artifact minimizing technologies (harmonic
imaging, compounding). The available literature is limited and predominantly dates
from the last 3 years [23 ]
[24 ]
[25 ]
[26 ], which means that the International Consensus Guidelines published in 2012 were
not yet able to provide any concrete recommendations [17 ]. International consensus recommendations from 2023 address the issue in detail and
suggest the use of optimized LUS presets, but without detailing specifics [11 ]. It is known from experimental but not clinical studies that high mechanical index
examinations can induce subpleural pulmonary capillary hemorrhage [27 ]. Whilst a clinically adverse effect remains to be proven and may be particularly
apprehended in newborn examinations, capillary hemorrhaging involving the lung parenchyma
itself could be misinterpreted as the starting point of B lines and thus yield false-positive
results [11 ]. Therefore, the current consensus recommendations, following publications of the
safety committees of national and international ultrasound professional societies,
advise the use of a mechanical index of 0.4–1.0 (depending on age and thoracic wall
thickness) and a limitation of the exposure time [11 ]
[28 ].
Few conclusions worthy of generalization can be drawn from the published literature,
which were first summarized in the proposals for standardization of LUS for the examination
of COVID-19 patients [21 ] and have been summarized in [Table 1 ], with due consideration of current data.
Table 1
Proposals for the standardized imaging settings for LUS (after [11 ]
[21 ]
[23 ]
[24 ]
[25 ]
[26 ].
The choice of convex or linear transducers depending on the patient's height; for
detailed pleural imaging, high-frequency linear transducers are preferable.
Single focus with the focus set on the pleural line.
Turn off artifact suppression algorithms such as Tissue Harmonic Imaging, Frame Averaging
(Persistence) and Compounding.
Use the highest possible frame rate (i. e. no multi-focus, low persistence).
Use a dynamic range of at least 60 dB.
Avoid saturation phenomena (“white image”) by minimizing gain and MI.
Limit the mechanical index (MI) to 0.4–0.7 (for neonates rather 0.4, for children
and adults gradual reduction starting with 0.7 as long as image quality is maintained)
and minimize exposure time to what is diagnostically required.
Normal sonography findings
The pleura consists of the pleura parietalis and the pleura visceralis. The normal
pleura cannot be visualized by sonography. In the absence of pathology, neither pleural
sheets can be visualized as a single mesothelial cell layer of only a few micrometers
in diameter, even with high-frequency transducers. The pleural sheets can however
indirectly be visualized as hyperechoic interface echoes. The reflex band of the aerated
lung (lung interface line) can be seen as a fine line. Above this are intercostal
muscles and fatty tissue, followed as a fine anechoic line by the pleural cavity and
the hyperechoic visceral pleura, which cannot be delineated from the lung surface.
Only in pathological processes (inflammatory and or neoplastic) does the then thickened
pleura become directly visible as an anechoic structure that can be easily assessed,
particularly with high-frequency linear transducers. In pathologically altered pleural
sheets, there is usually increased fluid in the pleural cavity (often only locally),
so that these can be easily visualized as a result of the higher impedance differences
([Fig. 1 ]). In the real-time B-scan, both pleural layers shift synchronously (“lung sliding”).
This can be visualized in M-mode as well as in B-scan, better still with color Doppler
or power Doppler.
Fig. 1 Normal pleural line with high-resolution linear probe. The normal pleura cannot be
visualized by sonography. The reflex band of the aerated lung (lung interface line)
can be seen as a fine line. Above this are intercostal muscles and fatty tissue, followed
as a fine anechoic line by the pleural cavity and the hyperechoic visceral pleura,
which cannot be delineated from the lung surface.
When assessing the pleura, it is recommended to start with the abdominal convex probe.
In order to have the highest possible resolution of the pleura, the focus position
should be shifted to the level of the pleural line. Although spatial resolution is
limited with the convex probe, at least pleural sliding, regularity of pleural contour,
any effusions, and acoustic phenomena emanating from the pleura and subpleural lung
can be assessed ([Fig. 2 ]). Detailed assessment of the pleura should be performed with the high-resolution
linear array transducer. Again, it is important to move the focus to the height of
the pleural line to get the highest possible resolution. Regardless of the transducer
type, it is important to differentiate the hyperechoic interfacial phenomena of rib
cortices and pleura from each other in a section transverse to the rib process.
Fig. 2 Differentiation of the hyperechoic interfacial phenomena of rib cortices (*) and
pleura (arrows) in a section transverse to the rib process. If the hyperechoic interfaces
are connected with each other, a contour (yellow) is created, which is reminiscent
of the silhouette of a flying bat (“bat sign”).
Indication(s), description of the typical situation
Described pathologies include tumors, thickening, interruption of the pleural line
(fragmentation), and subpleural consolidations. Tumors are generally anechoic or hyperechoic,
round or flat-lying processes, which are evaluated based on their margins and perfusion.
Tumors can arise from both the parietal and visceral pleura. A pathologically altered
pleura is notable due to the comet tail artifacts emanating from it ([Fig. 3 ]). Depending on the disease (common in viral infections), small (2–3 mm) subpleural
consolidations may be apparent, also characterized by comet tail artifacts.
Fig. 3 Representation of different pleural artifacts. The left illustration A represents a normal Herring-Breuer inflation reflex with multiple A lines (arrows).
The right illustration B shows a pathological irregular Herring-Breuer inflation reflex with vertical artifacts
in terms of B lines. The underlying pathology of this localized interstitial syndrome
needs to be established clinically. In this particular case, it involved a right-sided
pleuropneumonia.
Pleurisy
The sonographic patterns of pleurisy are uncharacteristic and variable, and changes
in the pleural line are often not distinguished from normal findings. The formation
of a (minor) effusion is indicative ([Fig. 4 ]).
Fig. 4 Depicts different ultrasound findings in patients with a clinical diagnosis of pleurisy.
In addition to pleural thickening, evidence of a small pleural effusion, lesions of
varying sizes may be observed in the parietal pleura. The pathology underlying these
sonographic findings needs be established clinically.
Pleural effusion
A pleural effusion is characterized by the presence of fluid between the parietal
and visceral pleura. A small degree of effusion is physiological: 0.3 ml/kg [29 ]. A pleural effusion occurs when there is an imbalance between production and absorption.
An effusion may be found free or encapsulated between the two pleural sheets. Free
pleural effusion is found basally in the costophrenic angle. The effusion should be
sought laterally dorsally in the supine patient and dorsally in the seated patient.
Occasionally, a subcostal transhepatic scan is helpful when the patient is in a supine
position ([Fig. 5 ]).
Fig. 5 Patient with right-sided chambered effusion, this can be visualized by intercostal
(left) and subcostal transhepatic coupling (right).
Encapsulated pleural effusions are localized at the margins of various pleural pathologies
([Fig. 6 ]), but may also persist as residuals after interventional therapy for extensive pleural
effusions. The encapsulated pleural effusion is assessed with the small part linear
probe. A free pleural effusion needs to be located with the abdominal convex probe
for a better overview. Particularly in overweight individuals with poor supine acoustic
conditions, it is not always easy to determine whether the anechoic region above the
diaphragm consists of fluid. The spine sign [30 ]
[31 ] may help to confirm the diagnosis. The adjustment of the costophrenic angle must
be done in such a way that the transverse processes of the spine are detected with
their acoustic shadow. If these are only visible below the diaphragm and the lung
and the lung extinguishes them during breathing like a curtain, the spine sign is
negative; there is no pleural effusion. However, if the transverse processes are also
visible above the diaphragm, there is pleural effusion ([Fig. 7 ]). If B lines resp. comet tail artifacts seen emanating from the pleura near the
diaphragm, this represents lung tissue and a pleural effusion can be ruled out.
Fig. 6 Patients with localized effusion formation and different pathologies such as pleurisy
(left), parainfectious pleural empyema (middle), and a pleural carcinomatosis (right)
presenting with a pleural metastasis (m) (arrow).
Fig. 7 Showing the costophrenic angle to exclude and detect a small leaking pleural effusion;
in the absence of effusion, the liver is reflected on the diaphragm (left). Detection
of comet tail artifacts from the pleura adjacent to the diaphragm ensures that no
pleural effusion is present (center). In the right illustration, the costophrenic
angle is anechoic. The positive spine sign confirms that it is a pleural effusion.
The transverse processes of the vertebral bodies are always seen in the abdominal
region, but in the thoracic region they are only observed in the presence of pleural
effusion or lobar pneumonia. An inflated lung leads to total reflection of the sound
waves.
Volume determination
An accurate quantification of pleural effusions is often inadequate due to the complex
spatial geometry and the often poorly defined position of the patient. Nevertheless,
there are various formulas for estimating the volume [32 ]
[33 ]. The simplest method is to multiply the lateral height extent of the effusion in
centimeters measured from the costophrenic angle in the sitting position by a factor
of 100 (volume in cubic centimeters) ([Fig. 8 ]). In another method [29 ], patients are examined lying down with the trunk slightly elevated by 15°. The probe
is moved upward into the posterior axillary line. In cross-section to the body axis,
the distance between pleura parietalis and pleura visceralis is measured at the base
of the lung, at the end of expiration. The amount of pleural fluid is evaluated with
the formula: Volume (ml) = 20 × distance between both pleural sheets (mm).
Fig. 8 Semiquantitative volume estimation in a patient with right-sided pleural effusion.
A lateral effusion height of 7 cm is measured; multiplied by 10, this results in an
effusion of approximately 700 ml.
However, determining the volume as accurately as possible is of little clinical relevance,
although it is frequently performed. The indication for effusion puncture or drainage
arises either for diagnostic reasons, due to a complicated effusion or empyema, or
due to the patient's shortness of breath symptomatology. The severity of a patient's
shortness of breath caused by a pleural effusion is not determined by the effusion
volume alone, but is also determined by the patient's height, body mass index, and
preexisting cardiopulmonary diseases, among other factors. In pre-existing heart failure
with additional chronic obstructive pneumopathy, relief of as little as 300 mL may
provide a clinical benefit to the patient. We therefore prefer a general classification
such as angular, low basal, moderate, or marked pleural effusion and to establish
the indication for puncture according to clinical criteria.
Type of effusion
Conclusions regarding the nature of the pleural effusion based on sonomorphology alone
are limited. Fibrous changes as well as septations often occur in a chronic effusion;
echogenic internal structures indicate hemorrhage or infection, but must be differentiated
from artifacts. Echogenicity (anechoic, homogenous, or heterogenous echogenicity)
can only give an indication of the cause of the effusion in conjunction with the clinical
situation [34 ]
[35 ]. While cardiogenic effusions or even a fresh hemothorax are often anechoic, echogenic
effusions or those with internal echogenic reflexes may indicate an inflammatory or
malignant etiology ([Fig. 9 ]), although many malignant effusions are also anechoic.
Fig. 9 Patients with anechoic (left), hyperechoic (middle) and polyseptated pleural effusion
(right). Sonographic evaluation of the effusion in terms of echogenicity is not useful
for the benign/malignant classification.
More important than echogenicity are: laterality, the absence of an encapsulation,
local or diffuse pleural and pulmonary changes, and concomitant disease and age of
the patient. Therefore, in addition to the effusion, the entire visible pleural cavity,
the diaphragm, and the pleura itself should always be assessed ([Fig. 10 ], [11 ]).
Fig. 10 Patients with pleural effusion and sonographic imaging of lung pathologies: A confirmed lung metastases, B clinically confirmed pneumonia with air bronchogram and polyseptated effusion, C peripheral lung consolidations with pulmonary artery embolism confirmed on the CT
scan, D pleural effusion with atelectasis and fluid bronchogram in confirmed central bronchial
carcinoma (bottom right).
Fig. 11 Patients with malignant pleural effusions and pathologies involving the pleural region,
the arrows indicate tumor structures: confirmed pleural metastasis from the right
costodiaphragm angle of a bronchial carcinoma (top left), confirmed diaphragm metastasis
imaged from a subcostal/transdiaphragm radiographic angle in a patient with a primary
breast carcinoma (top right), visceral pleural metastasis in a bronchial carcinoma
(bottom left), extensive pleural tumor structure in a mesothelioma (bottom right).
This allows the detection and also the ultrasound-guided biopsy of centrally located
tumors, metastases on the diaphragm or pleural tumors, which elude ultrasound imaging
when the lung is unfolded and filled with air. Unless there is a clinically clear
reason for the pleural effusion (e. g., cardiogenic bilateral effusion in heart failure
or unilateral effusion in chest trauma with rib fractures), the effusion must be punctured
for diagnostic reasons and examined both biochemically and cytologically, and possibly
also microbiologically [36 ].
Primarily, a transudate must be differentiated from an exudate in the case of non-traumatic
effusion [37 ]. A usually bilaterally detectable transudate is due to volume overload as in heart
failure and/or low oncotic pressure in albumin deficiency (e. g., liver cirrhosis,
renal or intestinal loss). Exudates, on the other hand, are usually caused by pleural
disease and thus are present only on the affected side. The differentiation can be
made according to the Light criteria, published in 1972 [38 ]
[39 ].
A threefold increase in the LDH concentration in pleural fluid compared to the norm
occurs in the presence of an infection (incl. tuberculosis), rheumatological diseases,
or neoplasia. The Light criteria are highly sensitive for the diagnosis of exudate,
but misclassify up to 25 % of all transudates as exudates. Numerous additional details
and alternatives have therefore been published. In particular, the determination of
serum pleural gradient, cholesterol concentration and gradient, and tumor markers
[40 ]
[41 ]
[42 ]
[43 ]
[44 ] must always be interpreted in the context of the patient's clinical picture. Effusion
cytology has an overall sensitivity of only 50 %–80 % [45 ], but this increases with the volume of effusion sent for analysis and with repeat
punctures.
Pneumothorax
Pneumothorax is air in the interspace between the parietal pleura and visceral pleura.
Pneumothorax must be included in the differential diagnosis of any patient with dyspnea.
Pneumothorax may occur spontaneously (for example, in patients with chronic obstructive
pulmonary disease and emphysema, congenital connective tissue weakness, e. g., in
Marfan syndrome, or cystic lung disease). Pneumothorax often occurs as part of trauma
(stab injury causing an air bridge from the pleural cavity to the exterior or rib
fracture causing an air bridge from the pleural cavity to the injured bronchi). Iatrogenic
pneumothorax can occur both during external thoracentesis or by bronchial injury via
bronchoscopy. Because of the elasticity of the lung, which collapses in the absence
of negative pressure in the pleural cavity (estimated to be about 8 cm of water column),
pneumothorax tends to increase with time. This is counteracted by natural pleural
air reabsorption. The most sensitive method for detecting pneumothorax is computed
tomography, which is considered the reference standard. In trauma patients, pneumothorax
can be diagnosed by sonography with a sensitivity of 90 %, whereas chest radiography
achieves a sensitivity of only 69 % [46 ]. However, only pleural sliding was assessed in this study and other sonographic
criteria of pneumothorax ([Table 2 ]) which can be used to further increase diagnostic accuracy, were not included.
Table 2
Sonographic signs of pneumothorax.
Absence of lung sliding
Detection of the lung point
Missing comet tail artifacts and B lines
Absence of lung pulse (M-mode or color Doppler)
In 2012, a diagnostic algorithm was proposed in a consensus conference [17 ]. In a slightly revised version, lung and pleural sliding are evaluated first ([Fig. 12 ], [13 ]). Direct signs (absence of lung sliding, evidence of lung point) have a higher value
than indirect signs (absence of artifacts, absence of lung pulse (M-mode or color
Doppler) ([Fig. 14 ]). The absence of lung sliding is typically found in the supine patient at the highest
point approximately one hand width below the clavicle. However, this is only the case
if there are no adhesions between the visceral pleura and the parietal pleura.
Fig. 12 Pneumothorax algorithm according to Volpicelli et al 2012, slightly modified by placing
the lung pulse before the lung point. The lung pulse can almost always be detected
in an inflated lung, but the lung point often cannot be found in a large pneumothorax.
Fig. 13 The left image shows the normal findings with normally aerated lungs (top B-mode,
bottom M-mode). The M-mode image resembles a sandy beach (seashore sign). The right
image shows the pleura with a transverse rib at the top. In color Doppler sonography,
pleural sliding is apparent as a positive color sign (bottom right).
Fig. 14 Patient with pneumothorax and evidence of a lung point (arrows): Patient with right-sided
mantle pneumothorax and evidence of a single lung point, the extent of the pneumothorax
cannot be determined by sonography (left image). A small pneumothorax as evidenced
by 2 lung points following the US guided puncture of a small pleural metastasis (M)
(right image). The absence of a pleural effusion, increases the risk of a puncture-related
pneumothorax.
Direct signs of pneumothorax are superior to indirect signs.
On lung ultrasound, the skin, subcostal fatty tissue, musculature, and parietal pleura
are visible as immobile, parallel lines (“waves”) in healthy individuals. The visceral
pleura and lungs move so that they resemble a sandy beach with their grainy pattern
(“seashore”) ([Fig. 15 ]). The presence of lung sliding or the seashore sign proves that there is no pneumothorax
at this site. The skin layers, thoracic musculature, and parietal pleural line (“pleura
parietalis”) are delineated as static (immobile) and parallel lines (“seashore”) as
opposed to the visceral pleural line (pleura visceralis) and lung parenchyma (“waves”)
which move with the respiratory cycle. The presence of comet tail artifacts and B
lines, which originate from the visceral pleura, also excludes pneumothorax. If neither
lung sliding nor B lines/comet tail artifacts are present, the lung pulse is sought.
This shows the cardiac action transmitted, through the mediastinum and an inflated
lung, all the way to the pleural line. A synchronous heartbeat pulsation is indicative
of an inflated lung. It can be visualized in M-mode (regular warping of the horizontal
lines to the pleural line) or by color or power Doppler ([Fig. 16 ], [17 ]).
Fig. 15 Patient with pneumothorax: In M-mode only horizontal lines are displayed (only “water
without sand”) = stratosphere sign or barcode sign.
Fig. 16 The lung pulse is shown in M-mode. Recorded along with the ECG, there is a pleural
line displacement at each QRS complex on the ECG. Evidence of a lung pulse means that
the lung is inflated at that location.
Fig. 17 The lung pulse is shown in color. A color sign below the pleura results from both
respiratory motion and lung pulse. Thus, a positive color sign means that the lungs
are unfolded at this point.
A positive color sign in the color or power Doppler, caused either by the lung pulse
or by pleural sliding, excludes pneumothorax.
On sonography, the size of the pneumothorax can only be estimated by means of the
position of the lung point. The lung point is the site of transition of the pneumothorax
into the lung which is normally adjacent to the thoracic wall. Accurate assessment
of the extent of a pneumothorax is reserved for radiography or computed tomography.
In extensive pneumothorax, the lung point is often not visible.
Solid pleural lesions and subpleural parenchymal changes (diffuse, circumscribed)
Solid pleural lesions and subpleural parenchymal changes (diffuse, circumscribed)
Pleural tumors usually occur in a localized fashion. They can be subdivided into primary
pleural tumors or metastases [47 ]. The most common primary pleural tumor is a malignant pleural mesothelioma ([Fig. 18 ]). All other primary tumors such as solid fibrous pleural tumor ([Fig. 19 ]), sarcoma, and hemangioendothelioma are very rare. Malignant pleural mesothelioma
is caused by asbestos exposure in 87 % of men and 65 % of women. The median survival
after diagnosis is short [47 ]. Pleural mesothelioma may manifest in various forms, as plaques or planar structures
and may involve the visceral or parietal pleura [48 ]. Pleural metastases occur in a large variety of tumors; frequently, the primary
tumor is a lung or breast carcinoma ([Fig. 10 ], [11 ]).
Fig. 18 CT scan (Source: Prof. Dr. Andreas H. Mahnken, Direktor der Diagnostischen und Interventionellen
Radiologie am Universitätsklinikum Marburg) and ultrasound of a patient with malignant
pleural mesothelioma: A markedly thickened parietal pleura is seen in the apical region
of the lung (upper images), and in the caudal diaphragm region the tumor (TU) breaches
the diaphragm (lower images).
Fig. 19 Patient with a histologically confirmed solid fibrous pleural tumor: CT scan (Source:
Prof. Dr. Andreas H. Mahnken, Direktor der Diagnostischen und Interventionellen Radiologie
am Universitätsklinikum Marburg) and B-scan ultrasound.
Tumors may involve the visceral or the parietal pleura ([Fig. 20 ]). In pleural tumors, a biopsy is usually necessary so that histologic diagnosis
and appropriate therapy can be initiated. Ultrasound-guided biopsy has a very high
diagnostic accuracy and a low complication rate [49 ], as a puncture route can be chosen to avoid the interposition of ribs and intercostal
vessels. It is best to biopsy a parietal pleural lesion at a site where pleural effusion
is present to reduce the risk of pneumothorax ([Fig. 11 ], [14 ]).
Fig. 20 Top row: CT scan (Source: Prof. Dr. Andreas H. Mahnken, Direktor der Diagnostischen
und Interventionellen Radiologie am Universitätsklinikum Marburg) and ultrasound,
of a patient with a small visceral pleura/ lung metastasis (M), showing that the lesion
slides with the respiratory cycle of the lung. US guided puncture (top right) resulted
in the diagnosis of lung metastases from a primary malignant melanoma. The risk of
pneumonia tends to be reduced in the case of lung metastases. Bottom row: Patient
with squamous cell carcinoma and small parietal pleural metastasis, the lung slides
over the pleural lesion (arrows) (lower left). US guided puncture (bottom center)
resulted in the diagnosis of a lung metastasis. Post-intervention, a small pneumothorax
was detected (see also Fig. 14) (bottom right).
Subpleural parenchymal changes may be diffuse or circumscribed. Diffuse changes include
pulmonary diseases that lead to changes in the pleural reflex (pulmonary fibrosis
with various causes such as sarcoidosis, amiodarone induced pulmonary fibrosis, systemic
lupus erythematosus, and others) ([Fig. 21 ]). However, sarcoidosis and amiodarone induced pulmonary fibrosis are not primary
pleural diseases, but diseases that extend from the lung to the pleura. Localized
changes may include pleural scars after radiation therapy, inflammation, trauma, lung
metastases, or tumors in contact with the visceral pleura ([Fig. 22 ]). Diffuse pleural changes also include less common causes such as IgG4 associated
diseases that affect the pleura and correspondingly lead to pleural effusion. These
may be suspected if lymphoplasmacytic infiltration is present in the pleural effusion
or pleural biopsy [50 ]
[51 ]. By sonography, pulmonary fibrosis presents with a picture of a severely altered
pleura, which is thickened and fragmented, with partial subpleural small consolidations,
and an interstitial syndrome with many comet tail artifacts.
Fig. 21 Patients with confirmed pulmonary fibrosis: in the upper row A , CT scan (Source: Prof. Dr. Andreas H. Mahnken, Direktor der Diagnostischen und Interventionellen
Radiologie am Universitätsklinikum Marburg) shows dorsal fibrotic changes; on the
right side, the corresponding ultrasound image shows multiple small nodular visceral
lesions (arrows). In the lower row B , CT scan (provided by *BLINDED*, Marburg) depicts distinct changes, ultrasound shows
nodular foci (arrows). Sonography is not suitable to show the extent of computer tomography
fibrotic changes.
Fig. 22 Patients with confirmed pleural pathologies: change due to scarring (A ), scleroderma (B ); GvHD of the lung (C ), tuberculosis (D ), Mediterranean fever (E ), neurofibroma (F ); B-scan sonography of lesions is nonspecific with no characteristic features, a
clinical classification is essential.
A differential diagnosis is not possible based on the sonographic appearance alone.
However, sonography helps in certain diseases. Thus, pathologic lymph nodes may be
found in sarcoidosis, which are readily accessible by biopsy, if superficial.
Fibrothorax
Fibrothorax is a scarring change of the pleura. Other terms include diffuse pleural
thickening, pleural rind, and pleural fibrosis. Adhesion of both pleural layers can
lead to respiratory distress due to the resulting restriction. The causes are diverse.
More common, however, are benign changes such as a post pleurisy status (infection,
tuberculous, drug-induced, uremic, rheumatism) or a post hemothorax status. If the
parietal pleura is thickened and has focal calcifications, this indicates asbestos-induced
fibrothorax [52 ]
[53 ].
Important differential diagnoses are pleural calcifications after previous hemothorax
or specific pleurisy. Biopsy is often necessary to force a differentiation of malignant
from benign disease. However, histological confirmation of the diagnosis is often
not very easy [54 ].
Interstitial syndrome – vertical reverberation artifacts
Interstitial syndrome – vertical reverberation artifacts
Based on clinical and experimental studies, vertical reverberation artifacts are heterogeneous
artifacts with characteristics closely related to pleural and subpleural tissue composition.
These artifacts may be short or long, bright, smooth, well or poorly defined, narrow
or wide, and of varying shapes [55 ]. Isolated vertical artifacts are also observed in healthy, often older individuals
(mostly in basal lung sections). A positive finding is considered to be present when
an examined region displays three or more vertical reverberation artifacts between
two ribs on a sagittal section (“interstitial syndrome”). The interstitial syndrome
may be focal, unilateral, bilateral or ubiquitous. Ubiquitous means that in the supine
patient at least 2 regions are positive for vertical repeating artifacts on both sides
ventrally and laterally [17 ].
Adjustment
The vertical reverberation artifacts can in principle be visualized with all probe
types, but in adults typically a convex probe with a frequency range between about
3 and 6 MHz should be used. Since the new ultrasound devices often have artifact suppression
programmed into the presets, it is imperative that these settings be turned off, otherwise
they also suppress reverberation artifacts. The vertical reverberation artifacts can
be assigned to different diseases based on their presentation. They are divided into
B lines and comet tail artifacts. To make this distinction, the pleura must be assessed
with a high-frequency probe (10 MHz and above).
B-lines
B-lines are hyperechoic reverberation artifacts that originate from a smooth pleural
line (assessed with a high-frequency probe) and extend to the lower edge of the image
(more than 10 cm) without attenuation. They are always the same width, overshadow
everything, and move with the lung sliding. If ubiquitous, this corresponds to pulmonary
edema. They typically occur in cardiogenic pulmonary edema.
Comet tail artifacts
Comet tail artifacts are strongly echogenic reverberation artifacts that originate
from an irregular, fragmented pleural line which often appears thickened (assessed
with a high-frequency probe). They arise at a pathologically altered pleura, originate
from subpleural consolidations or from the edge of lung consolidations. They vary
in width, and end at different depths (less than 10 cm). If ubiquitous, they may be
indicative of pulmonary fibrosis (e. g., sarcoidosis, pneumonitis, and others). Focal
comet tail artifacts occur in pulmonary contusion, pleurisy, and other pleural diseases.
