CT and MRI Findings in Cerebral Aspergilloma

• Introduction
• Case series
• Results
• CT features
• MR imaging features
• Discussion
• References

Abstract

Purpose Invasive aspergillosis usually affects immunocompromised patients. It carries a high risk of morbidity and mortality and usually has a nonspecific clinical presentation. Early diagnosis is essential in order to start effective treatment and improve clinical outcome.

Materials and Methods In a retrospective search of the PACS databases from two medical centers, we identified 9 patients with histologically proven cerebral aspergilloma. We systematically analyzed CT and MRI imaging findings to identify typical imaging appearances of cerebral aspergilloma.

Results CT did not show a typical appearance of the aspergillomas. In 100 % (9/9) there was a rim-attenuated diffusion restriction on MRI imaging. Multiple hypointense layers in the aspergillus wall, especially on the internal side, were detected in 100 % on T2-weighted imaging (9/9). Aspergillomas were T1-hypointense in 66 % of cases (6/9) and partly T1-hyperintense in 33 % (3/9). In 78 % (7/9) of cases, a rim-attenuated diffusion restriction was detected after contrast agent application.

Conclusion Nine cases were identified. Whereas CT features were less typical, we observed the following imaging features on MRI: A strong, rim-attenuated diffusion restriction (9/9); onion layer-like hypointense zones, in particular in the innermost part of the abscess wall on T2-weighted images (9/9). Enhancement of the lesion border was present in the majority of the cases (7/9).

Key points 

• There are typical MRI imaging features of aspergillomas.

• However, these findings could be affected by the immune status of the patient.

• Swift identification of aspergilloma imaging patterns is essential to allow for adequate therapeutic decision making.

Citation Format

• Gärtner F, Forstenpointner J, Ertl-Wagner B et al. CT and MRI Findings in Cerebral Aspergilloma. Fortschr Röntgenstr 2018; 190: 967 – 970

Zusammenfassung

Ziel Zerebrale Aspergillose betrifft meist immunsupprimierte Patienten und weist aufgrund der oftmals unspezifischen Klinik ein hohes Morbiditäts- und Mortalitätsrisiko auf. Eine frühe Diagnosestellung ermöglicht die effektivere Einleitung der Therapiemaßnahmen und die Verbesserung des Outcome.

Material und Methoden Die CT- und MRT-Aufnahmen von neun Patienten aus zwei Zentren wurden ausgewertet. Die Diagnose der zerebralen Aspergillose wurde mittels Biopsie und histopathologischer Begutachtung verifiziert. Die MRT wurde an 1,5T- und 3T-Geräten durchgeführt, die Untersuchungsprotokolle enthielten jeweils DWI, T2- und T1-gewichtete Bilder mit und ohne Kontrastmittel.

Ergebnisse In der CT wiesen die Aspergillome kein typisches Erscheinungsbild auf. In der MRT waren die Aspergillome zu 100 % randständig diffusionsgestört (9/9). Mehrere hypointense Schichten in der Aspergilluswand, insbesondere an der Innenseite, waren typisch in den Aufnahmen mit T2-Wichtung (100 %, 9/9). Die Aspergillome waren sowohl T1-hypointens (66 %, 6/9), sowie in 33 % anteilig T1-hyperintens (3/9). In 78 % (7/9) der Fälle fand sich ein randständiges Enhancement nach Gadoliniumapplikation.

Schlussfolgerung Aspergillome weisen typischerweise eine kräftige, ringförmige Diffusionsrestriktion auf (9/9). Typische Befunde in Aufnahmen der T2-gewichteten Bilder sind zwiebelschalenartig angeordnete hypointense Schichten, die innere Zone der Aspergilluswand ist aufgrund paramagnetischer Effekte besonders signalarm (9/9). Der Großteil der Aspergillome weist nach Kontrastmittelapplikation ein ringförmiges Enhancement auf (7/9).

Kernaussagen 

• Es gibt typische Bildbefunde in der Darstellung intrakranieller Aspergillome in der MRT, diese variieren jedoch in Abhängigkeit des Immunstatus des Patienten.

• Die Kenntnis der MR-Morphologie der Aspergillome ermöglicht die zügige Einleitung adäquater Therapien.

Introduction

Candida ssp (subspecies), Aspergillus ssp and Cryptococcus ssp are the most common pathogens to cause fungal infections of the central nervous system (CNS) [1]. The source of infection is either a local process such as paranasal sinusitis, otogenic or odontogenic sources, or results from hematogenous spread, usually from the lung or the intestine [2]. A fungal infection of the CNS is rare in immunocompetent persons and is mostly observed in immunosuppressed patients, e. g. with AIDS or patients under medical immunosuppression after organ or bone marrow transplantation [3]. Another risk factor for acquiring cerebral fungal infections is long-standing diabetes.

The CNS manifestation is usually part of a disseminated infection [4]. Patients are often afebrile or only have a low-grade fever and present with nonspecific neurological symptoms such as stroke-like symptoms or seizures [5]. Cerebrospinal fluid (CSF) analysis typically shows a moderate elevation of CSF proteins and pleocytosis (600/mm), although CSF analysis can be normal as well. Blood cultures are frequently negative [6]. The nonspecific clinical presentation delays the diagnosis of a mycotic CNS infection and impairs the clinical outcome by a late initiation of effective treatment strategies. To increase knowledge of cerebral aspergilloma, we analyzed the imaging features of patients with this disease, which might facilitate earlier diagnosis in the future.

Case series

CT and MRI imaging data of nine patients with cerebral aspergillosis from two university hospitals were retrospectively analyzed in order to identify common imaging patterns. Diagnosis was confirmed by intraoperative biopsy by the neurosurgical department followed by histopathological analysis.

MR imaging examinations were performed on different MRI systems using 1.5- and 3-Tesla systems. The imaging protocols always included axial diffusion-weighted imaging (DWI), axial T2w images, axial and coronal T1w images and sagittal FLAIR images.

Results

Aspergillomas appeared as intra- or extra-axial mass lesions. The imaging findings in CT and MRI are summarized in [Table 1], [2].

CT features

CT image datasets were available in 8 cases. Overall, CT did not demonstrate a characteristic appearance of the aspergillomas. The lesions were slightly hyperdense in 4 of 8 cases (50 %). In a single case the aspergilloma was strongly hyperdense due to hemorrhage (13 %). In 3 of 8 cases (38 %) the lesions were hypodense. In the majority of the cases, slight surrounding edema was observed.

MR imaging features

MR imaging datasets were available for all 9 patients. DWI showed rim-attenuated diffusion restriction in all patients (n = 9/9). Typical findings on T2w images were a hyperintense abscess wall, containing onion-layer-like hypointense zones, in particular on the inner part of the wall in 9/9 patients (100 %). After contrast media application, the majority (n = 7/9) of aspergillomas showed strong rim enhancement (78 %). ([Fig. 1]).

Discussion

Patients with an intracranial manifestation of aspergillosis have a poor prognosis. Therefore, fast diagnosis is essential to initiate rapid, targeted medical and surgical treatment [7]. In our case series, we describe the typical imaging patterns of this rare cerebral infection to facilitate early diagnostic decision-making and improve the patients’ outcome ([Fig. 2]).

Mycotic infections of the CNS are usually transmitted hematogenously. Lesions are therefore most commonly found in a subcortical location. Another means of infection is the transdural spread of an underlying paranasal sinus or mastoid infection [8].

In our study, all cerebral aspergillomas demonstrated pronounced diffusion restriction, in particular at the edge of the lesions. This finding is consistent with the fact that mycotic mass lesions have a peripheral fungal cell wall [9]. In contrast, intracerebral abscesses due to a bacterial infection are characterized by a strong diffusion restriction in the center of the abscess [10]. This diffusion restriction is caused by limited water diffusion as a result of the high cellularity of the pus. In T1w imaging, aspergillomas were mainly hypointense as a result of the cellular edema. T1w-hyperintense aspergillomas were seen in our study in three cases, most likely due to hemorrhage. After contrast media application, the majority of aspergillomas (78 %) showed strong enhancement in the rim. However, in two cases no enhancement was seen at all. This observation was already made in prior studies, suggesting that strongly immunosuppressed patients are not able to induce a sufficient inflammatory response at the blood-brain barrier to allow passage of the contrast agent [11]. The observation that aspergillomas are characterized by diverging hypointense layers in T2-weighted images was also made before [12]. The T2-hypointensities correlate with the grade of fungal proliferation. Since it is essential for fungal growth, the hyphae accumulate iron and magnesium, leading to a paramagnetic effect. It can be assumed that the strongly hypointense layers correlate with areas of active proliferation in the interior part of the abscess wall where the fungal proliferation encounters less host immune defense [13].

Differential diagnoses of ring enhancing intracranial mass tumors include metastases, primary or secondary brain tumors and abscesses caused by different types of infection. Anamnesis, as well as further extracranial examination with ultrasound, X-ray or CT helps to identify metastases. Typical image patterns have been described for various intracranial infections, which help to discriminate between the types of infection. Differential diagnoses for the cases examined in this study are bacterial abscesses, which are characterized by a typical general diffusion restriction, as well as tuberculomas or toxoplasmosis [14]. Cerebral blood volume maps obtained by CT and MR perfusion are useful to identify primary brain tumors or lymphomas. The latter is characterized by the typical leakage in MR perfusion due to higher vascular permeability [15].

In summary, our case series demonstrates typical MR imaging, while CT features were less typical. There was generally a strong diffusion restriction in the rim. On T2-weighted images the abscess wall was typically hyperintense with onion-layer-like hypointense zones, which were particularly prominent at the innermost part of the abscess wall. Rim enhancement was seen in the majority of the cases. However, these findings can vary, e. g. due to the immuno-status of the patient.

No conflict of interest has been declared by the author(s).

• References

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• 8 Smirniotopoulos JG, Murphy FM, Rushing EJ. et al. Patterns of Contrast Enhancement in the Brain and Meninges. RadioGraphics 2007; 27: 525-551
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• 9 Dichtl K, Samantaray S, Wagener J. Cell wall integrity signaling in human pathogenic fungi. Cellular microbiology 2016; DOI: 10.1111/cmi.12612.
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• 10 Ebisu T, Tanaka C, Umeda M. et al. Discrimination of brain abscess from necrotic or cystic tumors by diffusion-weighted echo planar imaging. Magnetic resonance imaging 1996; 14: 1113-1116
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• 11 Ionita C, Wasay M, Balos L. et al. MR imaging in toxoplasmosis encephalitis after bone marrow transplantation: paucity of enhancement despite fulminant disease. American journal of neuroradiology 2004; 25: 270-273
  PubMedGoogle Scholar
• 12 Fellows DW, King VD, Conturo T. et al. In vitro evaluation of MR hypointensity in Aspergillus colonies. American journal of neuroradiology 1994; 15: 1139-1144
  PubMedGoogle Scholar
• 13 Yamada K, Zoarski HG, Rothman IM. et al. An intracranial aspergilloma with low signal on T2-weighted images corresponding to iron accumulation. Neuroradiology 2001; 43: 559-561
  CrossrefPubMedGoogle Scholar
• 14 Foerster BR, Thurnher MM, Malani PN. et al. Intracranial infections: clinical and imaging characteristics. Acta Radiologica 2007; 48: 875-893
  CrossrefPubMedGoogle Scholar
• 15 Kickingereder P, Sahm F, Wiestler B. et al. Evaluation of microvascular permeability with dynamic contrast-enhanced MRI for the differentiation of primary CNS lymphoma and glioblastoma: radiologic-pathologic correlation. American journal of neuroradiology 2014; 35: 1503-1508
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Correspondence

• References

• 1 Honda H, Warren DK. Central Nervous System Infections: Meningitis and Brain Abscess. Infectious Disease Clinics of North America 2009; 23: 609-623
  CrossrefPubMedGoogle Scholar
• 2 Sofianou D, Selviarides P, Sofianos E. et al. Etiological agents and predisposing tors of intracranial abscesses in a Greek university hospital. Infection 1996; 24: 144-146
  CrossrefPubMedGoogle Scholar
• 3 Coley SC, JÄGer HR, Szydlo RM. et al. CT and MRI Manifestations of Central Nervous System Infection following Allogeneic Bone Marrow Transplantation. Clinical Radiology 54: 390-397
  PubMedGoogle Scholar
• 4 Walsh TJ, Hier DB, Caplan LR. Aspergillosis of the central nervous system: clinicopathological analysis of 17 patients. Annals of neurology 1985; 18: 574-582
  CrossrefPubMedGoogle Scholar
• 5 Beal MF, O'Carroll CP, Kleinman GM. et al. Aspergillosis of the nervous system. Neurology 1982; 32: 473-479
  CrossrefPubMedGoogle Scholar
• 6 Sharma RR, Gurusinghe NT, Lynch PG. Cerebral infarction due to Aspergillus arteritis following glioma surgery. British journal of neurosurgery 1992; 6: 485-490
  CrossrefPubMedGoogle Scholar
• 7 Artico M, Pastore F, Polosa M. et al. Intracerebral Aspergillus abscess: Case report and review of the literature. Neurosurg Rev 1997; 20: 135-138
  CrossrefPubMedGoogle Scholar
• 8 Smirniotopoulos JG, Murphy FM, Rushing EJ. et al. Patterns of Contrast Enhancement in the Brain and Meninges. RadioGraphics 2007; 27: 525-551
  CrossrefPubMedGoogle Scholar
• 9 Dichtl K, Samantaray S, Wagener J. Cell wall integrity signaling in human pathogenic fungi. Cellular microbiology 2016; DOI: 10.1111/cmi.12612.
  PubMedGoogle Scholar
• 10 Ebisu T, Tanaka C, Umeda M. et al. Discrimination of brain abscess from necrotic or cystic tumors by diffusion-weighted echo planar imaging. Magnetic resonance imaging 1996; 14: 1113-1116
  CrossrefPubMedGoogle Scholar
• 11 Ionita C, Wasay M, Balos L. et al. MR imaging in toxoplasmosis encephalitis after bone marrow transplantation: paucity of enhancement despite fulminant disease. American journal of neuroradiology 2004; 25: 270-273
  PubMedGoogle Scholar
• 12 Fellows DW, King VD, Conturo T. et al. In vitro evaluation of MR hypointensity in Aspergillus colonies. American journal of neuroradiology 1994; 15: 1139-1144
  PubMedGoogle Scholar
• 13 Yamada K, Zoarski HG, Rothman IM. et al. An intracranial aspergilloma with low signal on T2-weighted images corresponding to iron accumulation. Neuroradiology 2001; 43: 559-561
  CrossrefPubMedGoogle Scholar
• 14 Foerster BR, Thurnher MM, Malani PN. et al. Intracranial infections: clinical and imaging characteristics. Acta Radiologica 2007; 48: 875-893
  CrossrefPubMedGoogle Scholar
• 15 Kickingereder P, Sahm F, Wiestler B. et al. Evaluation of microvascular permeability with dynamic contrast-enhanced MRI for the differentiation of primary CNS lymphoma and glioblastoma: radiologic-pathologic correlation. American journal of neuroradiology 2014; 35: 1503-1508
  CrossrefPubMedGoogle Scholar