Mapping the Fascicular Morphology and Organization of the Human Sciatic Nerve via High-Resolution MicroCT Imaging
Journal:
bioRxiv
Published Date:
Feb 16, 2026
Abstract
Objective: Implanted neuroprostheses can restore standing and walking after spinal cord injury and somatosensation after limb loss. Yet current approaches often fail to reliably activate hamstring muscles crucial for upright stability and mobility or to target afferent fibers for sensory restoration. We developed a novel methodology using high-resolution micro-computed tomography (microCT) to visualize and track fascicle groups innervating distinct hamstring muscles along the human sciatic nerve. This approach provides a framework for mapping fascicular topography in complex neural pathways to optimize standing neuroprostheses. Methods: Bilateral sciatic nerves were dissected and excised from an embalmed human cadaver, annotated with branch names, and stained with phosphotungstic acid before undergoing microCT scanning at 11.4 m isotropic resolution. Images were segmented with a 3D U-Net convolutional neural network. Segmentation results were used to quantify morphological metrics and track fascicular organization along ~25 cm of the nerve. MicroCT reconstructions were validated against histological cross sections. Results: Gross dissection revealed matched proximal-to-distal branching between left and right sciatic nerves: branch to long head of the biceps femoris (lhBF), branch to hamstring part of the adductor magnus and semimembranosus (HAM/SM), and branch to semitendinosus (ST). All branches originated medially and followed an inferomedial trajectory. Branch-free lengths of the sciatic exhibited asymmetry, especially between the lumbosacral roots to the first branch (5.5 cm left vs. 1.5 cm right) and lhBF to the HAM/SM branch (9.0 cm left vs. 16.5 cm right). MicroCT analysis revealed bilateral symmetry in fascicle diameters (~0.4 mm) and total fascicle counts (~84) but asymmetry in hamstring-innervating fascicle counts (left ~7, right: ~9). The 3D fascicular maps revealed that hamstring fascicles were located in the anteromedial portion of the sciatic nerve cross section and remained separate for distances up to 15.9 cm proximal to their branching points. Significance: Our microCT-based approach enables efficient, high-resolution 3D mapping of fascicular organization within large, complex peripheral nerves like the sciatic nerve, overcoming previous technical limitations. This methodology informs development of neuroprostheses with improved hamstring muscle activation for enhanced standing function.
