Abstract
Automated methods for quantitation of tissue and CSF volumes by MR imaging are available for the cranial but not the spinal compartment. We developed an iterative method for delineation of the spinal CSF spaces for automated measurements of CSF and cord volumes and applied it to study craniospinal CSF redistribution following lumbar withdrawal in patients with idiopathic intracranial hypertension. MR imaging data were obtained from 2 healthy subjects and 8 patients with idiopathic intracranial hypertension who were scanned before, immediately after, and 2 weeks after diagnostic lumbar puncture. Imaging included T1-weighted and T2-weighted sequences of the brain and T2-weighted scans of the spine. Repeat scans in 4 subjects were used to assess measurement reproducibility. Whole CNS CSF volumes measured prior to and following lumbar puncture were compared with the withdrawn amounts of CSF. CSF and cord volume measurements were highly reproducible with mean variabilities of -0.7% ± 1.4% and -0.7% ± 1.0%, respectively. Mean spinal CSF volume was 77.5 ± 8.4 mL. The imaging-based pre- to post-CSF volume differences were consistently smaller and strongly correlated with the amounts removed (R = 0.86, P = .006), primarily from the lumbosacral region. These differences are explained by net CSF formation of 0.41 ± 0.18 mL/min between withdrawal and imaging. Automated measurements of the craniospinal CSF redistribution following lumbar withdrawal in idiopathic intracranial hypertension reveal that the drop in intracranial pressure following lumbar puncture is primarily related to the increase in spinal compliance and not cranial compliance due to the reduced spinal CSF volume and the nearly unchanged cranial CSF volume.
Highlights
BACKGROUND AND PURPOSEAutomated methods for quantitation of tissue and CSF volumes by MR imaging are available for the cranial but not the spinal compartment
CSF and cord volume measurements were highly reproducible with mean variabilities of Ϫ0.7% Ϯ 1.4% and Ϫ0.7% Ϯ 1.0%, respectively
The total amount of CSF and its craniospinal distribution are important for understanding of CSF-related brain and spinal cord disorders and CSF physiology in general
Summary
MR imaging data were obtained from 2 healthy subjects and 8 patients with idiopathic intracranial hypertension who were scanned before, immediately after, and 2 weeks after diagnostic lumbar puncture. Segmentation of Intracranial CSF Volume Delineation of the ventricles was obtained from T1-weighted sequences with the FreeSurfer software,[9] which uses an atlas-based method as prior information in a Bayesian parameter estimation framework to identify several brain regions, including the ventricular system. Intracranial CSF was obtained with the New Segment tool in SPM8 software, which allows multitechnique segmentation by using both T1-weighted and T2-weighted images and incorporates a priori spatial information by using tissue probability maps.[10] Regions outside the cranium with image intensity like CSF (eg, vitreous humor) were removed from the final segmentation by using a skull mask generated by the FSL Brain Extraction Tool (http://fsl.fmrib.ox.ac.uk/fsl/fslwiki/BET).[15] The coordinates of the most inferior axial section containing CSF segmentation are automatically determined and used to initialize the automated segmentation of the spinal CSF
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