Jill E Shea1, Jared W Garlick2, Mohamed E Salama3, Shaun D Mendenhall4, Linh A Moran2, Jayant P Agarwal5. 1. Department of Surgery, Division of General Surgery, University of Utah School of Medicine, Salt Lake City, Utah. 2. University of Utah School of Medicine, Salt Lake City, Utah. 3. University of Utah School of Medicine, Salt Lake City, Utah; ARUP Reference Laboratory Research Institute, Salt Lake City, Utah. 4. The Institute for Plastic Surgery, Southern Illinois University School of Medicine, Springfield, Illinois. 5. Department of Surgery, Division of Plastic and Reconstructive Surgery, University of Utah School of Medicine, Salt Lake City, Utah. Electronic address: jay.agarwal@hsc.utah.edu.
Abstract
BACKGROUND: Peripheral nerve injury can result in muscle atrophy and long-term disability. We hypothesize that creating a side-to-side bridge to link an injured nerve with a healthy nerve will reduce muscle atrophy and improve muscle function. METHODS: Sprague-Dawley rats were divided into four groups (n = 7 per group). Group 1: transection only--a 10-mm gap was created in the proximal tibial nerve; group 2: transected plus repaired--the transected tibial nerve was repaired; group 3: transected plus repaired plus nerve bridge--transected nerve repaired with a distal nerve bridge between the tibial and peroneal nerves via epineurial windows; and group 4: transected plus nerve bridge--transected tibial nerve left unrepaired and distal bridge added. Gait was assessed every 2 wk. At 90 d the following measures were determined: gastrocnemius mass, muscle and nerve nuclear density, and axonal infiltration into the nerve bridge. RESULTS: Groups 3 and 4 had greater improvements in walking track recovery than groups 1 and 2. Group 3's gastrocnemius muscles exhibited the least amount of atrophy. Groups 1, 2, and 4 exhibited greater histologic appearance of muscle breakdown compared with group 3 and control muscle. Finally, most bridges in groups 3 and 4 had neuronal sprouting via the epineurial windows. CONCLUSIONS: Our study demonstrated reduced muscle atrophy with a side-to-side nerve bridge in the setting of peripheral nerve injury. These results support the application of novel side-to-side bridges in combination with traditional end-to-end neurorrhaphy to preserve muscle viability after peripheral nerve injuries.
BACKGROUND:Peripheral nerve injury can result in muscle atrophy and long-term disability. We hypothesize that creating a side-to-side bridge to link an injured nerve with a healthy nerve will reduce muscle atrophy and improve muscle function. METHODS:Sprague-Dawley rats were divided into four groups (n = 7 per group). Group 1: transection only--a 10-mm gap was created in the proximal tibial nerve; group 2: transected plus repaired--the transected tibial nerve was repaired; group 3: transected plus repaired plus nerve bridge--transected nerve repaired with a distal nerve bridge between the tibial and peroneal nerves via epineurial windows; and group 4: transected plus nerve bridge--transected tibial nerve left unrepaired and distal bridge added. Gait was assessed every 2 wk. At 90 d the following measures were determined: gastrocnemius mass, muscle and nerve nuclear density, and axonal infiltration into the nerve bridge. RESULTS: Groups 3 and 4 had greater improvements in walking track recovery than groups 1 and 2. Group 3's gastrocnemius muscles exhibited the least amount of atrophy. Groups 1, 2, and 4 exhibited greater histologic appearance of muscle breakdown compared with group 3 and control muscle. Finally, most bridges in groups 3 and 4 had neuronal sprouting via the epineurial windows. CONCLUSIONS: Our study demonstrated reduced muscle atrophy with a side-to-side nerve bridge in the setting of peripheral nerve injury. These results support the application of novel side-to-side bridges in combination with traditional end-to-end neurorrhaphy to preserve muscle viability after peripheral nerve injuries.
Authors: Ngan Pan Bennett Au; Gajendra Kumar; Pallavi Asthana; Chung Tin; Yim Ling Mak; Leo Lai Chan; Paul Kwan Sing Lam; Chi Him Eddie Ma Journal: Sci Rep Date: 2016-05-27 Impact factor: 4.379