A Photosealed Cap Prevents Disorganized Axonal Regeneration and Neuroma following Nerve Transection in Rats

Neuroma is a common sequela of traumatic peripheral nerve injury that can result in pain and decreased quality of life for patients. Neuromas result from axonal outgrowth in an attempt to reestablish continuity with the disrupted distal nerve end. Photosealing is a light-activated technique whereby tissues can be securely isolated in a strong and secure manner. This study investigated whether photosealing of autologous vein and crosslinked human amniotic membrane (xHAM) to cap the proximal stump of transected sciatic nerve would prevent disorganized axonal regeneration and neuroma in a rat model. METHODS: The right sciatic nerve of Lewis rats (n = 27, 300–350 g) was transected 1 cm proximal to the trifurcation. Animals were randomized to one of three groups (n = 9): no further intervention (Group 1), photosealing with xHAM (Group 2), or photosealing with vein (Group 3). After 60 days, rats were euthanized and their right hindlimbs were re-explored for evidence of disorganized axonal regeneration and/or bulbous neuroma. RESULTS: All untreated control animals were found to have protruding nerve fibers, often invading the adjacent muscle, and 33% of these control animals exhibited a bulbous neuroma. Photosealing with xHAM successfully capped 100% of nerves, with no observable axonal outgrowth. Photosealing with vein prevented axonal outgrowth in eight of nine nerves. No bulbous neuroma was found in any photosealed nerves. CONCLUSION: Nerve capping with photosealed xHAM or autologous vein can prevent axonal outgrowth in transected nerves, therefore decreasing the likelihood of symptomatic neuroma formation following nerve transection injury or surgical intervention.