Sylvian fissure lipoma associated with fusiform aneurysm in the middle cerebral artery trifurcation: A case report and literature review

Intracranial lipomas are rare congenital malformations. They are usually pericallosal asymptomatic midline lesions. Other brain malformations are often seen in association with intracranial lipomas. We describe the findings of imaging studies, including computed tomography (CT), magnetic resonance (MR) imaging, and MR angiography, along with a brief review of the literature. The frequency and the spectrum of the associated brain malformations are also discussed. We retrospectively reviewed CT and MR findings of 24 patients (14 female, 10 male, mean age 38.6 years) diagnosed with intracranial lipoma between December 2000 and June 2004 in two different radiology departments. Seventeen of the patients were diagnosed using cranial MR and seven with cranial CT. The CT density of all lesions was measured. Imaging characteristics of lipomas, morphological findings and associated malformations were described. The intracranial locations of the lipomas were left-sided quadrigeminal cistern (n=3), right-sided quadrigeminal cistern (n=4), interpeduncular cistern (n=1), sylvian fissure (n=3), interhemispheric fissure (n=3), choroid plexus (n=2), intercerebellar fissure (n=3), corpus fornicis (n=1) and the periphery of the corpus callosum (n=4). Eighteen of the intracranial lipomas were tubulonodular; six were curvilinear. Associated anomalies were observed in six patients. All of the patients with sylvian fissure lipoma had seizures. The two preferential sites of intracranial lipomas were pericallosal and dorsal mesencephalic. Most intracranial lipomas are found incidentally during neuroradiological investigations. CT and MR examination usually lead to the diagnosis, because of the very low attenuation values of lipomas on CT and the short T1 and T2 on MR. Midline anomalies and other malformations such as aneurysms are frequently associated with intracranial lipomas. Careful radiologic evaluation is therefore necessary to evaluate associated pathologies. Sylvian fissure lipomas should be considered in the differential diagnosis of patients with epilepsy.

Intracranial lipomas are uncommon lesions whose development remains poorly understood. To clarify the anatomic and embryologic features of intracranial lipomas, we retrospectively reviewed the MR scans of 42 patients with 44 intracranial lipomas. Interhemispheric lipomas were the most common, accounting for 45% of cases. The remainder of the lesions were clustered in the quadrigeminal/superior cerebellar (25%), suprasellar/interpeduncular (14%), cerebellopontine angle (9%), and sylvian (5%) cisterns. Fifty-five percent of the lesions were associated with brain malformations of varying degrees. Intracranial vessels and nerves were noted to course through 16 (36%) of the lesions. The relative frequencies of the locations of the lipomas correspond to the temporal sequence of dissolution of the meninx primitiva, the mesenchymal anlage of the meninges. This finding supports the concept of lipoma formation as a result of abnormal persistence and maldifferentiation of the meninx. This embryologic concept of the development of intracranial lipomas explains the high frequency of callosal and other brain hypoplasias. Intracranial lipomas are neither hamartomas nor true neoplasms; rather, they are congenital malformations.

The common complaint of headache usually has a benign cause, most often a primary headache syndrome. The history and neurologic and general physical examinations usually permit a definitive diagnosis. When in doubt, diagnostic testing is indicated. Certain historical and examination findings increase the likelihood of a secondary headache disorder and the need for diagnostic testing. These include (1) recent head or neck injury; (2) a new, worse, worsening, or abrupt onset headache; (3) headache brought on by Valsalva maneuver or cough; (4) headache brought on by exertion; (5) headache associated with sexual activity; (6) pregnancy; (7) headache in the patient over the age of ~50; (8) neurologic findings and/or symptoms; (9) systemic signs and/or symptoms; (10) secondary risk factors, such as cancer or human immunodeficiency virus (HIV) infection. Less worrisome are headaches that wake the patient from sleep at night, always occur on the same side, or show a prominent effect of change in posture on the patient's pain. Diagnostic studies include neuroimaging, cerebrospinal fluid (CSF) examination, and blood tests, which are selected depending on the patient's history and findings. For most patients, the diagnostic test of choice is a magnetic resonance imaging (MRI) brain scan. Computed tomography (CT) of the brain is usually obtained in the setting of trauma or the abrupt onset of headache. CSF examination is useful in diagnosing subarachnoid bleeding, infection, and high and low CSF pressure syndromes.