CASE 15251 Published on 16.11.2017

Cerebral venous thrombosis in a young female patient with nephroblastoma

Section

Neuroradiology

Case Type

Clinical Cases

Authors

Ana Coutinho Santos¹, Alexandra Borges²

¹Radiology Department, Centro Hospitalar de Lisboa Ocidental, Lisboa, Portugal
²Radiology Department, Instituto Português de Oncologia de Lisboa Francisco Gentil, Lisboa, Portugal

Patient

23 years, female

Categories

Area of Interest Abdomen, Thoracic wall, Thorax, Neuroradiology brain ; Imaging Technique CT, Conventional radiography, MR, MR-Diffusion/Perfusion, MR-Angiography

Procedure Diagnostic procedure, Contrast agent-intravenous ; Special Focus Neoplasia, Seizure disorders, Ischaemia / Infarction ;

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Clinical History

A 23-year-old female patient was admitted after a first seizure episode. She had a recent diagnosis of IV-stage nephroblastoma of the right kidney with pleuropulmonary metastatic disease (Fig. 1) and had started chemotherapy two weeks earlier. Metastatic CNS disease was suspected and CT and MR of the brain were requested.

Imaging Findings

Non-enhanced CT of the brain revealed a triangular-shaped left posterior temporal cortical and subcortical hypodensity-causing mass effect upon adjacent structures without midline displacement and a spontaneous hyperdensity in the ipsilateral sigmoid and transverse sinuses (Fig. 2). Contrast-enhanced CT showed mild cortico-pial enhancement with no further enhancement of the hypodense lesion and absent enhancement of the left jugular bulb (Fig. 3a and b).
On MR the lesion was hypointense on T1-weighted (T1W), hyperintense on T2-weighted (T2W) and FLAIR images (Fig. 4) and showed restricted diffusion of the cortex on diffusion-weighted images (DWI) (Fig. 5). Also noted was a spontaneous hyperintensity on plain T1W images in the left sigmoid and transverse sinuses and jugular bulb that showed absent flow on MR-venography (Fig. 6 and 7). There were no signs of haemorrhage. Post-gadolinium images demonstrated collateral cortico-pial hyperperfusion. No other anomalies were identified and metastatic disease was ruled out.

Discussion

Cerebral venous thrombosis (CVT) is a rare form of stroke (0.5-1% of all strokes) that mainly affects young adults, especially women. [1-3]
CVT involves two pathophysiological mechanisms: thrombosis of the major cerebral sinuses, which causes intracranial hypertension because of impaired absorption of cerebrospinal fluid, and thrombosis of the cortical veins, leading to parenchymal congestion and breakdown of the blood-brain barrier that can damage brain tissue. [2, 4] Haemorrhagic transformation occurs in 30-50% of cases. [2]
Risk factors for CVT include oral contraceptives, coagulation disorders, puerperium and pregnancy, malignancies, trauma, and chronic inflammation or infection. [2, 4, 5]
The clinical presentation of CVT is highly variable, depending on the extent and location of thrombosis and the availability of venous collaterals. [2, 6] The most common symptoms are headache (usually severe), seizures and focal neurological deficits. [7] The latter two are suggestive of parenchymal abnormalities. [2, 3, 5] Hence, the diagnosis is difficult and relies on imaging, specifically on the demonstration of thrombi in the cerebral veins and/or sinuses by MR, MR-venography or CT-venography. [5, 7]
CT can be normal in up to 25–30% of cases and is inferior to MR in depicting brain parenchymal lesions. [2, 8] Unenhanced CT can demonstrate a spontaneous hyperdensity within the affected vein or sinus (the cord sign) or indirect signs such as brain oedema or infarction (Fig. 2). The classic finding of sinus thrombosis on CT-venography is the empty delta sign, a central filling defect (thrombus) with peripheral enhancement due to collaterals. [3, 6, 7]
Unenhanced MR detects intraluminal thrombi with variable signal intensity on T1W and T2W images depending on the time of onset (Fig. 6). Susceptibility-weighted sequences are useful in acute-stage thrombosis. MR-venography with time-of-flight sequences or contrast-enhanced MR-venography confirms absence of flow (Fig. 7), the latter with higher sensitivity especially for small veins thrombosis. [6] Findings of parenchymal lesions secondary to venous occlusion are similar to those of CT and DWI imaging can be helpful in this setting in the demonstration of additional acute infarctions (Fig. 5). [6, 7]
Prompt diagnosis and timely anticoagulant therapy with heparin are essential to reduce morbidity. [6, 8] Decompressive surgery is recommended in severe cases with impending herniation. [9]
Approximately 80% of patients recover without functional disability and the risk of recurrence is low. [3] Mortality is about 5-10%, associated with underlying diseases, particularly malignancies. [2]
CVT is an uncommon disorder with nonspecific clinical symptoms. Definitive diagnosis relies on a high degree of suspicion and brain imaging by MR, MR-venography or CT-venography. Early diagnosis and treatment are associated with a favourable outcome.

Differential Diagnosis List

Dural venous sinus thrombosis

Cerebral metastasis

Arterial ischaemic stroke

Brain abscess

Final Diagnosis

Dural venous sinus thrombosis

References

[1] Weimar C, Masuhr F, Hajjar K (2012) Diagnosis & treatment of cerebral venous thrombosis. Expert Rev. Cardiovasc. Ther 10(12), 1545–1553 (PMID: 23253278)

[2] Coutinho JM (2015) Cerebral venous thrombosis. J Thromb Haemost 13 (Suppl. 1): S238–S44 (PMID: 26149030)

[3] Bushnell C, Saposnik G (2014) Evaluation and Management of Cerebral Venous Thrombosis. Continuum (Minneap Minn) 20(2):335–351 (PMID: 24699485)

[4] Ho M, Rojas R, Eisenberg RL (2012) Cerebral Edema. AJR 199:W258–W273 (PMID: 22915416)

[5] Ferro JM, Canhão P (2014) Cerebral Venous Sinus Thrombosis: Update on Diagnosis and Management. Curr Cardiol Rep 16:523 (PMID: 25073867)

[6] Leach JL, Fortuna RB, Jones BV, Gaskill-Shipley MF (2006) Imaging of Cerebral Venous Thrombosis: Current Techniques, Spectrum of Findings, and Diagnostic Pitfalls. RadioGraphics 26:S19–S43 (PMID: 17050515)

[7] Poon CS, Chang J, Swarnkar A, Johnson MH, Wasenko J (2007) Radiologic Diagnosis of Cerebral Venous Thrombosis: Pictorial Review. AJR 189: S64-S75 (PMID: 18029905)

[8] Sadigh G, Mullins ME, Saindane AM (2016) Diagnostic Performance of MRI Sequences for Evaluation of Dural Venous Sinus Thrombosis. AJR 206:1298–1306 (PMID: 27010526)

[9] Ferro JM, Bousser MG, Canhão P, et al. (2017) European Stroke Organization guideline for the diagnosis and treatment of cerebral venous thrombosis – endorsed by the European Academy of Neurology. European Journal of Neurology 24: 1203–1213 (PMID: 28833980)

Case information

URL:	https://www.eurorad.org/case/15251
DOI:	10.1594/EURORAD/CASE.15251
ISSN:	1563-4086

License

This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.

Figure 1

Non-enhanced CT of the brain after a first seizure episode

Axial non-enhanced CT image shows a left posterior temporal hypodensity-causing mass effect (long arrow) with no midline displacement and a spontaneous hyperdensity in the ipsilateral transverse sinus (dashed arrows).

Figure 2

Young female patient with IV-stage nephroblastoma with pleuropulmonary metastatic disease

A. Axial enhanced CT demonstrating a heterogeneous and hypodense mass of the right kidney with invasion and thrombosis of the right renal vein and inferior vena cava.

B. Chest radiograph depicting several oval and well-defined pleural-based opacities on the right side and a ipsilateral hilar mass with no silhouette sign with the right heart border.

Figure 3

Contrast-enhanced CT of the brain after a first seizure episode

A. At contrast-enhanced CT, the lesion does not enhance (short white arrow) and cerebral arteries are patent (white arrowheads).

B. At contrast-enhanced CT, there is absent enhancement of the left jugular bulb (short black arrow) and normal enhancement on the right side (long black arrow).

Figure 4

Axial T1W, T2W and coronal FLAIR MR images

A. Lesion in the left posterior cortico-subcortical temporo-occipital region with hypointensity on T1W images (white arrow).

B. Lesion in the left posterior cortico-subcortical temporo-occipital region with hyperintensity on T2W images (black arrow).

C. Lesion in the left posterior cortico-subcortical temporo-occipital region with hyperintensity on FLAIR images (short arrow) consistent with brain oedema.

Figure 5

Diffusion-weighted MR images

A. b=1000 s/mm2. High signal on DWI (arrows, A) and low signal on ADC images (dashed arrows, B) in the cortex consistent with restricted diffusion, suggesting the presence of cytotoxic oedema.

B. ADC map. High signal on DWI (arrows, A) and low signal on ADC images (dashed arrows, B) in the cortex consistent with restricted diffusion, suggesting the presence of cytotoxic oedema.

Figure 6

T1W MR images before and after intravenous gadolinium administration

A. There is spontaneous hyperintensity in the left sigmoid sinus and ipsilateral jugular bulb (white arrows) indicating loss of normal flow void and raising suspicion of subacute dural venous sinus thrombosis.

B. Post-contrast image confirms absence of flow in the transverse sinus (black arrows) and the hypointense lesion is suggestive of cerebral infarction in the corresponding territory (short white arrow).

Figure 7

MR venography

A. T1-weighted post-gadolinium three-dimensional sagittal image depicting lack of flow in left transverse (white arrow) which confirmed the suspicion of left dural venous sinus thrombosis.

B. Coronal time-of-flight MR-venography depicting lack of flow in left sigmoid sinus and ipsilateral jugular bulb (dashed arrows) which confirmed the suspicion of left dural venous sinus thrombosis.