Optimizing Filter-Probe Diffusion Weighting in the Rat Spinal Cord for Human Translation

Budde, Matthew D.; Skinner, Nathan P.; Muftuler, L. Tugan; Schmit, Brian D.; Kurpad, Shekar N.

doi:10.3389/fnins.2017.00706

Cited by 12 publications

(14 citation statements)

References 62 publications

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“…2). In addition, diffusion models that account for the effects of edema 12 or filter out signal contributions from the extra-cellular space 36 may improve predictions of nerve recovery within the first few weeks.…”

Section: Discussionmentioning

confidence: 99%

Probabilistic Assessment of Nerve Regeneration with Diffusion MRI in Rat Models of Peripheral Nerve Trauma

Esteve

Farinas

Pollins

et al. 2019

Sci Rep

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Nerve regeneration after injury must occur in a timely fashion to restore function. Unfortunately, current methods (e.g., electrophysiology) provide limited information following trauma, resulting in delayed management and suboptimal outcomes. Herein, we evaluated the ability of diffusion MRI to monitor nerve regeneration after injury/repair. Sprague-Dawley rats were divided into three treatment groups (sham = 21, crush = 23, cut/repair = 19) and ex vivo diffusion tensor imaging (DTI) and diffusion kurtosis imaging (DKI) was performed 1–12 weeks post-surgery. Behavioral data showed a distinction between crush and cut/repair nerves at 4 weeks. This was consistent with DTI, which found that thresholds based on the ratio of radial and axial diffusivities (RD/AD = 0.40 ± 0.02) and fractional anisotropy (FA = 0.53 ± 0.01) differentiated crush from cut/repair injuries. By the 12th week, cut/repair nerves whose behavioral data indicated a partial recovery were below the RD/AD threshold (and above the FA threshold), while nerves that did not recover were on the opposite side of each threshold. Additional morphometric analysis indicated that DTI-derived normalized scalar indices report on axon density (RD/AD: r = −0.54, p < 1e-3; FA: r = 0.56, p < 1e-3). Interestingly, higher-order DKI analyses did not improve our ability classify recovery. These findings suggest that DTI may provide promising biomarkers for distinguishing successful/unsuccessful nerve repairs and potentially identify cases that require reoperation.

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Section: Discussionmentioning

confidence: 99%

Probabilistic Assessment of Nerve Regeneration with Diffusion MRI in Rat Models of Peripheral Nerve Trauma

Esteve

Farinas

Pollins

et al. 2019

Sci Rep

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“…fADC || maps in the 1D-fDWI scheme had a clear decrease of fADC || in an area of intact cord (uninjured C3) as rotation angle increased. The underestimation of fADC || followed the expected cos 2 ( ) dependence, 10 assuming straight and coherent fibers in the white matter (Supporting Information Figure S3). Therefore, the 2D-fDWI maintained lesion-to-healthy contrast and was generally unaffected by in-plane deviations of the cord axis from the diffusion-encoding directions.…”

Section: Orientation Dependencementioning

confidence: 66%

“…The derived fADC || had an expected cos 2 dependence on the angle between the underlying axonal fibers and the diffusion-weighted direction (as in 1D-fDWI). 10 As a compromise, this study evaluated a 2D "in-plane" orientationally invariant diffusion encoding scheme that was more tolerant of orientation than the 1D scheme. Out-of-plane rotations, although not explicitly evaluated here, are likely to result in similar orientational dependent behavior.…”

Section: Discussionmentioning

confidence: 99%

“…Initial experiments used a single 2D slice and 2 images with b = 0 s/mm 2 image and 2000 s/mm 2 perpendicular to the spinal cord axis (left-right in animal coordinates) because the cord has the least curvature in this direction, and the white matter retains high signal with a perpendicular diffusion gradient. 10 For each condition, TEs of the diffusion preparation (TE prep ) module were minimized. TE prep times with a b value of 2000 s/mm 2 were 15.6, 24.4, and 27.6 ms for m0, m1, and m2, respectively.…”

Section: Motion-compensation Diffusion Encodingmentioning

confidence: 99%

“…2 To minimize the confounding effects of edema, filtered DWI (fDWI) was used for the spinal cord to attenuate signals from extra-axonal components using a high-strength diffusion filter perpendicular to the cord. 4,10 This approach reduced the signal contribution from edema and CSF, while diffusion encoding parallel to the cord probed filtered axial diffusivity (fADC || ), which predominantly reflects intra-axonal diffusivity. Despite improved detection of injury in preclinical SCI, several prominent barriers remain.…”

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confidence: 99%

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Diffusion‐prepared fast spin echo for artifact‐free spinal cord imaging

Lee

Meyer

Kurpad

et al. 2021

Magnetic Resonance in Med

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Purpose: Diffusion MRI provides unique contrast important for the detection and examination of pathophysiology after acute neurologic insults, including spinal cord injury. Diffusion weighted imaging of the rodent spinal cord has typically been evaluated with axial EPI readout. However, Diffusion weighted imaging is prone to motion artifacts, whereas EPI is prone to susceptibility artifacts. In the context of acute spinal cord injury, diffusion filtering has previously been shown to improve detection of injury by minimizing the confounding effects of edema. We propose a diffusion-preparation module combined with a rapid acquisition with relaxation enhancement readout to minimize artifacts for sagittal imaging. Methods: Sprague-Dawley rats with cervical contusion spinal cord injury were scanned at 9.4 Tesla. The sequence optimization included the evaluation of motioncompensated encoding diffusion gradients, gating strategy, and different spinal cordspecific diffusion-weighting schemes. Results: A diffusion-prepared rapid acquisition with relaxation enhancement achieved high-quality images free from susceptibility artifacts with both second-order motioncompensated encoding and gating necessary for reduction of motion artifacts. Axial diffusivity obtained from the filtered diffusion-encoding scheme had greater lesionto-healthy tissue contrast (52%) compared to the similar metric from DTI (25%). Conclusion: This work demonstrated the feasibility of high-quality diffusion sagittalimaging in the rodent cervical cord with diffusion-prepared relaxation enhancement.The sequence and results are expected to improve injury detection and evaluation in acute spinal cord injury. K E Y W O R D Sartifact reduction, diffusion imaging, motion preparation, spinal cord | INTRODUCTIONTraumatic spinal cord injury (SCI) is a catastrophic event that can permanently impair sensorimotor function, but accurate diagnosis and prognosis of injury severity are limited. There remains a medical need for improved prognostic metrics that can stratify early injury severity to guide clinical treatment and enrollment in clinical trials. Diffusion weighted imaging How to cite this article: Lee S-Y, Meyer BP, Kurpad SN, Budde MD. Diffusion-prepared fast spin echo for artifact-free spinal cord imaging.

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