Skull Base CSF Leaks: Potential Underlying Pathophysiology and Evaluation of Brain MR Imaging Findings Associated with Spontaneous Intracranial Hypotension

DISCUSSION

Our study used a validated brain MRI scoring system to assess for SIH in patients with skull base CSF leaks. Previously, skull base CSF leaks have been seen as distinct from SIH based on a single study that evaluated patients with SIH and did not find any with skull base CSF leaks. Patients with skull base CSF leaks have not previously been studied for brain MRI findings of SIH. Of the 31 patients included in our study, the mean Bern score was less than 1, and only 1 patient had dural enhancement. Only 4 had headaches with orthostatic features. Our findings provide further evidence of the distinct underlying pathophysiology of skull base and spinal CSF leaks.

The initial work from Dobrocky et al⁸ described a probabilistic brain MRI scoring method (0–9, 9 representing the highest probability) to measure the likelihood of a spinal CSF leak, frequently referred to as the Bern score, and reported an 83% rate of dural thickening/enhancement in patients with SIH. Subsequent studies have described a similar rate of dural enhancement in SIH of 79%¹⁰ and 81%.¹¹ Our study population largely did not demonstrate findings of SIH, with a mean Bern score of less than 1 and only 1 case (3%) with dural enhancement. Kranz et al¹² found that increasing symptom duration is associated with decreased rate of dural enhancement and that patients with SIH without dural enhancement had a mean symptom duration of 45.3 weeks. In our study, 22 patients had symptom duration of 1 year or less (1 had dural enhancement), including 10 with symptom duration of 6 months or less (none had dural enhancement).

The major prior study that separated skull base CSF leaks from spinal CSF leaks causing SIH was performed by Schievink et al,⁵ who reviewed 273 patients with SIH from a single institution and did not find any cases with a skull base CSF leak. Schievink et al¹³ later reported a single case of SIH caused by a skull base leak from the posterior fossa. Tai et al¹⁴ reported on the treatment and outcomes in patients with spontaneous versus nonspontaneous CSF leaks, and included 6 patients with spontaneous sphenoid sinus leaks. They stated that all 6 patients had MRI findings of intracranial hypotension, but did not use a validated scoring system for MRI results, nor did they list what imaging findings were abnormal. Their methodology included focal dural enhancement as a sign of SIH, which in a different study has been described as an SIH mimicker,¹⁵ and is likely distinct from the diffuse dural enhancement that is widely associated with SIH. Our study evaluated the MR imaging findings in skull base CSF leaks by using a validated scoring system and did not find brain MR imaging results associated with SIH.

Spinal and skull base CSF leaks both result in CSF loss, but they are differentiated by the leak location. Why would the location of the CSF leak cause such different symptoms and brain imaging findings? It is likely that brain MRI in SIH is related to downward CSF shift in the cranial-to-caudal direction from a sump effect of the spinal CSF leak. Wolf et al¹⁶ recently used phase-contrast MRI in patients with SIH (spinal leaks) to show that CSF flow was increased at C2–C3 compared with normal controls. They also found that patients with SIH had larger craniocaudal spinal cord motion at C2–C3. Comparatively, in our study, skull base CSF leaks would theoretically have preserved physiologic CSF flow at the skull base, without resultant downward sump effect that would cause brain sag or venous engorgement (Fig 2).

• Download figure
• Open in new tab
• Download powerpoint

FIG 2.

Illustration of a patient with a spontaneous supratentorial skull base CSF leak in the middle cranial fossa (A) with preserved CSF flow at the foramen magnum (B). This is in contrast to a patient with a spinal CSF leak (C) that could include a ventral dural tear or CSF-venous fistula, and potential sump effect with craniocaudal CSF flow at the foramen magnum (D) that contributes to findings associated with SIH including brain sag and pituitary engorgement shown here.

Most interesting, the 1 patients with skull base CSF leaks in our cohort with dural enhancement had an infratentorial CSF leak. Before surgical repair of the skull base CSF leak, the patient underwent a conventional CT myelogram that did now show extradural fluid. Three years later, the patient was found to have a ventral spinal CSF leak from a calcified disk osteophyte complex. It is unknown whether the patient’s symptoms were due to an occult spinal CSF leak or if this occurred after the skull base leak repair. All other patients in this study without dural enhancement had supratentorial CSF leaks, suggesting that supra- versus infratentorial leak location could contribute to the brain MRI findings. One prior case report described a cranial CSF leak presenting with orthostatic headache and brain MRI findings that included diffuse dural enhancement, and this patient also had a posterior fossa CSF leak into the mastoid air cells.¹⁷ Bonomo et al¹⁸ reported a single case of a small spheno-ethmoidal meningoencephalocele causing SIH symptoms and brain MRI findings, but no other studies have described similar findings. Therefore, the notion that SIH is caused by a spinal CSF leak might possibly be extended to leaks from the infratentorial skull base, however the current data are insufficient to fully support this claim.

Our study has limitations, starting with the retrospective nature and small sample size. Spontaneous skull base leaks are rare, but to our knowledge, we present the largest study focusing on brain MRI findings. Our theory, building on what Wolf et al¹⁶ reported in patients with SIH, requires testing. Further studies evaluating upper cervical CSF flow and cord motion in skull base CSF leaks could help to validate our hypothesis. Nonetheless, it has been suggested that skull base CSF leaks do not present with SIH, and our study largely supports this claim. One of the 2 patients with an intermediate Bern score of 4 in our study had brain sag and low-lying cerebellar tonsils that were unchanged 1 year after surgical repair of the CSF leak. The lack of improvement of the brain MRI findings, if the causative leak site was repaired, would be unexpected based on prior work by Dobrocky et al¹⁹ studying postoperative brain MRI findings in patients with surgically repaired spinal CSF leaks. It is possible that our patient’s findings represented a Chiari type I malformation rather than sequela of a CSF leak. Additionally, outside of the infratentorial CSF leak, none of the patients with headache in our study were evaluated for a spinal CSF leak, and therefore a spinal cause was not excluded.