Non-invasive biomarkers for spontaneous intracranial hypotension (SIH) through phase-contrast MRI

All participants were scanned on a 3 Tesla MRI scanner (3 T, SIEMENS MAGNETOM Prisma, SIEMENS Healthineers, Erlangen) using a 64-channel head–neck coil. Phase-contrast MRI was performed as part of the standard diagnostic workup in SIH that also includes contrast-enhanced MRI of the head to assess the Bern score, and T2 fat-saturated images of the entire spine to screen for SLEC, prior to dynamic myelograms [26]. Standard T2 3D sequence of the cervical spine (spatial resolution 0.6 mm × 0.6 mm × 1.0 mm) was used to derive anatomical data of the CSF space and the spinal cord cross-sectional areas (CSA) (Fig. 1). The phase-contrast imaging protocol comprised two axial, cardiac-gated 2D phase-contrast MRI sequences that were administered during free, steady breathing for through-plane cranio-caudal velocities (prospective ECG-triggering, spatial resolution 0.9 mm × 0.9 mm x 5 mm). The sequences were set perpendicular to the spinal canal at the cervical segment C2/C3 with velocity-encoding parameter 5 cm/s for spinal cord velocities and velocity-encoding parameter 10 cm/s for CSF velocities. A minimum of 20 time points per cardiac cycle was assessed per sequence. The average time of the individual’s heartbeat duration was recorded per sequence allowing further analysis of the time-resolved velocity data (about 1.5 min). Further technical MRI details are summarized in Supplement 1.

Data segmentation and processing were performed using a fully automated pipeline implied within the in-house platform NORA (ww.nora-imaging.org [27]) that uses trained 3D hierarchical deep convolutional neural networks for segmentation (Fig. 1). The training procedures and the further processing steps have been described in detail before [24, 25], and are summarized in Supplement 1. MRI data curation involved exclusion of datasets with typical MRI artifacts (e.g., movement, metal, infolding), and/or exclusion of velocity curves that did not follow a typical pattern of CSF- or spinal cord motion as displayed in Fig. 1 (examples in Supplement 1). Data validity of the methods regarding test–test and test–retest reliability has been investigated and reported before (Supplement 1) [24, 25]. The Intra-class correlation coefficient was > 0.9 for any value.

The following parameter were assessed: sex, age (years), height (cm), body mass index (BMI) (kg/m²), duration of symptoms (months), and prior treatment with epidural lumbar bloodpatch (EBP), targeted fibrin patch, and surgery. Among patients, the Bern score [23] and presence of SLEC were recorded. Bern score was additionally stratified into low (≤ 2 points), intermediate (3–4 points), and high probability (5–9 points) [23]. The type of the CSF leak [20‐22] was diagnosed on subsequent dynamic myelogram (digital subtraction myelogram and/or dynamic CT-myelogram).

For anatomical data of the cervical spine, the spinal cord cross-sectional area (CSA) (mm²) and the subarachnoid space CSA (mm²) were generated per segment using the T2-weighted images.

For quantitative analysis of the time-resolved velocity curves, two main values were calculated (Fig. 1): the maximum craniocaudal peak-to-peak amplitude that comprises the velocity range (mm/s), and the total displacement (mm) that refers to the absolute distance that the chosen voxels are moved up and down per heart cycle. In addition, the maximum range of the CSF flow rate in ml/s and the CSF stroke volume (ml) was generated. As significant influences of age (negative effect), sex (increased values in males), and for CSF space narrowing of the spinal canal at the level C2/C3 (positive effect for CSF only) have been evident in healthy cohorts [25], dynamic data was additionally adjusted accordingly and reported in arbitrary units.

Statistical analysis was performed using IBM SPSS Statistics® (IBM Corporation, Released 2020. IBM SPSS Statistics for Macintosh, Version 27.0. Armonk, New York, USA).

Data are presented as mean and standard deviation (SD), unless stated otherwise.

Data of (1) all patients with SIH and confirmed spinal CSF leak, (2) subgroups divided by spinal CSF leak type, and (3) of all SIH patients with confirmed spinal CSF leak and Bern score of 0–4 points were compared to healthy controls by Mann–Whitney U test. Distribution of categorical data was compared via χ² fisher exact test. Furthermore, subgroups stratified by spinal CSF leak types were compared using the Kruskal–Wallis test, requiring a minimum of ten cases per leak type.

Among all SIH patients with confirmed spinal CSF leak, the relation of duration of symptoms and of the Bern score (0–9 points) with adjusted phase-contrast MRI measurements were analyzed by multiple linear regression upon validation of standard premises applying bootstrapping to adjust for optimism. As the duration of symptoms showed a right skew, data were converted to a logarithmic scale beforehand. P < 0.05 was considered significant.

Receiver operating characteristics (AUROC) analysis was conducted for all SIH patients with confirmed spinal CSF leaks to assess the diagnostic potential of phase-contrast MRI analysis in SIH. Thresholds were selected to achieve ≥ 90% specificity. Additionally, sensitivity and specificity of these thresholds were separately analyzed in all patients with CSF–venous fistulas.

Descriptive reporting was provided for patients’ results in these cases where the diagnosis remained unclear or no spinal CSF leak was found at the time of the analysis.

SIH patients with confirmed leaks exhibited elevated spinal cord and CSF velocity ranges, increased total spinal cord and CSF displacements, and increased ranges of CSF flow rates compared to healthy controls (Table 2, e.g., spinal cord velocity range 7.6 ± 3 mm/s vs. 5.6 ± 1.4 mm/s, p = 0.001; CSF velocity range 56 ± 21 mm/s, vs. 42 ± 10 mm/s, p < 0.001). These findings were further supported by adjusted data analysis. CSF stroke volume remained consistent (2.2 ± 0.8 ml vs. 2.2 ± 0.7, p = 0.992, adjusted data: 3.8 ± 0.8 vs. 3.7 ± 0.7, p = 0.063).

Subgroup analysis stratified by the type of spinal CSF leak revealed the most pronounced increase in spinal cord motion among patients with lateral leaks and CSF–venous fistulas, e.g., spinal cord velocity range 8.4 ± 3.3 mm/s and 8.2 ± 3.1 mm/s, respectively, vs. 5.6 ± 1.4 mm/s in healthy controls, p < 0.001, respectively (Table 2, Fig. 2). When adjusted for age and sex, spinal cord velocity range was even larger in lateral leaks and CSF–venous fistulas than in ventral leaks (p = 0.023, p = 0.049, respectively; Fig. 3).

All CSF velocity data was highest in patients with lateral leaks.

Higher Bern scores correlated with larger adjusted spinal cord velocity range and total displacement with moderate goodness of fit (correlation coefficient (95%CI) 0.44 (0.23–0.66, adjusted R² = 0.16, correlation coefficient (95%CI) 0.068 (0.03–0.10), adjusted R² = 0.13, p < 0.002, respectively, Supplement 2). Correlation analysis with CSF data showed only weak goodness of fit (adjusted R² < 0.06, Supplement 2). Higher segmental narrowing at C2/C3 (aSCOR) as potential surrogate of brain sagging correlated with the extent of spinal cord velocities and displacement with a poor to moderate goodness of fit (correlation coefficient (95%CI) 0.25 (0.15–0.34), adjusted R² = 0.20, correlation coefficient (95%CI) 0.03 (0.01–0.05), adjusted R² = 0.01, p < 0.002, respectively). The duration of symptoms did not correlate to any dynamic data.

For all 117 patients with confirmed CSF leak, encompassing all different leak types, acceptable differentiation between these patients and healthy cohorts was achieved using CSF velocity range and by adjusted CSF velocity range (AUROC 0.740, 0.747, respectively, Table 3). Discrimination by spinal cord velocity range was nearly acceptable (AUROC 0.699). Thresholds were chosen at the lowest value achieving a specificity of ≥ 90% (Table 3). Given these thresholds, discrimination was favorable across all spinal cord measurements in patients with CSF–venous fistulas (> 0.74) (Fig. 4) with sensitivity ranging between 53 and 77%, and specificity between 85 and 93%. If spinal cord velocity range was adjusted for age and sex, an excellent discrimination was achieved (AUROC 0.826, sensitivity 58%, specificity 91%).

Table 4 contains the history and data of the remaining cases admitted due to suspected SIH (7 cases), or formerly confirmed SIH (1 case). Dynamic data was rated as positive/negative ( ±) according to the thresholds (Supplement 2).