Acellular nerve allograft promotes selective regeneration

Acellular nerve ailograft preserves the basilar membrane tube and extracellular matrix, which promotes selective regeneration of neural defects via bridging. In the present study, a Sprague Dawley rat sciatic nerve was utilized to prepare acellular nerve allografts through the use of the chemical extraction method. Subsequently, the allograft was transplanted into a 10-mm sciatic nerve defect in Wistar rats, while autologous nerve grafts from Wistar rats served as controls. Compared with autologous nerve grafts, the acellular nerve allografts induced a greater number of degenerated nerve fibers from sural nerves, as well as a reduced misconnect rate in motor fibers, fewer acetylcholine esterase-positive sural nerves, and a greater number of carbonic anhydrase-positive sensory nerve fibers. Results demonstrated that the acellular nerve allograft exhibited significant neural selective regeneration in the process of bridging nerve defects.

Various changes in cryopreserved acellular nerve allografts at-80°C

The experimental design evaluated histological,mechanical,and biological properties of allogeneic decellularized nerves after cryopreservation in a multi-angle,multi-directional manner to provide evidence for long-term preservation.Acellular nerve allografts from human and rats were cryopreserved in a cryoprotectant（10% fetal bovine serum,10% dimethyl sulfoxide,and 5% sucrose in RPMI1640 medium） at-80°C for 1 year,followed by thawing at 40°C or 37°C for 8 minutes.The breaking force of acellular nerve allografts was measured using a tensile test.Cell survival was determined using L-929 cell suspensions.Acellular nerve allografts were transplanted into a rat model with loss of a 15-mm segment of the left sciatic nerve.Immunohistochemistry staining was used to measure neurofilament 200 expression.Hematoxylin-eosin staining was utilized to detect relative muscle area in gastrocnemius muscle.Electron microscopy was applied to observe changes in allograft ultrastructure.There was no obvious change in morphological appearance or ultrastructure,breaking force,or cytotoxicity of human acellular nerve allografts after cryopreservation at-80°C.Moreover,there was no remarkable change in neurofilament 200 expression,myelin sheath thickness,or muscle atrophy when fresh or cryopreserved rat acellular nerve allografts were applied to repair nerve injury in rats.These results suggest that cryopreservation can greatly extend the storage duration of acellular nerve tissue allografts without concomitant alteration of the physiochemical and biological properties of the engineered tissue to be used for transplantation.

Limited recovery following acellular nerve allograft reconstruction in major peripheral nerve injuries

Recent studies suggest that acellular nerve allografts(ANA)have similar efficacy as nerve autografts in certain applications of nerve surgery.However,multiple studies also demonstrate the limitations of nerve allografts,resulting in poor patient outcomes.This submission discusses a recent case series of patients who failed allograft use with subsequent histologic analyses of these allografts.Recommendations on the treatment of nerve gaps are presented,drawing from our current understanding of allograft and autograft utility in reconstruction.Factors taken into account include recipient critical nerve function,existent nerve gap,and nerve diameter.