Nerve transfer is an emerging treatment to restore upper limb function in people with tetraplegia. The objective of this study is to examine if a flexible collage sheet (FCS) can act as epineurial-like substitute to promote nerve repair in nerve transfer. A preclinical study using FCS was conducted in a rat model of sciatic nerve transection. A prospective case series study of nerve transfer was conducted in patients with C5-C8 tetraplegia who received nerve transfer to restore upper limb function. Motor function in the upper limb was assessed pre-treatment, and at 6-,12-, and 24-months post-treatment. Macroscopic assessment in preclinical model showed nerve healing by FCS without encapsulation or adhesions. Microscopic examination revealed that a new, vascularised epineurium-like layer was observed at the FCS treatment sites, with no evidence of inflammatory reaction or nerve compression. Treatment with FCS resulted in well-organised nerve fibres with dense neurofilaments distal to the coaptation site. Axon counts performed proximal and distal to the coaptation site showed that 97% of proximal axon count of myelinated axons regenerated across the coaptation site after treatment with CND. In the proof of concept clinical study 17 nerve transfers were performed in five patients. Nerve transfers included procedures to restore triceps function (N=4), wrist/finger/thumb extension (N=6) and finger flexion (N=7). Functional motor recovery (MRC ≥3) was achieved in 76% and 88% of transfers at 12 and 24 months, respectively. The preclinical study showed that FCS mimics epineurium and enable to repair nerve resembled to normal nerve tissue. Clinical study showed that patients received nerve transfer with FCS experienced consistent and early return of motor function in target muscles. These results provide proof of concept evidence that CND functions as an epineurial substitute and is promising for use in nerve transfer surgery

After big loos of substances of peripheral nerves, in order to connect proximal with distal stump, it is possible to use, in alternative to autologous grafting, different kind of conduits. The chitosan conduit and the muscle in vein technique showed very good results in pre clinical and clinical settings. We compared in this study the efficacy of empty chitosan conduit versus chitosan conduit enriched with fresh muscle fibbers (MIT) to improve peripheral nerve regeneration. The median nerve of rat was repaired by means of empty chitosan conduit or MIT (nerve gam 6mm, conduit length 10 mm). As control group we used auto grafting technique. We performed analysis at short term (7,14,28 days) and at long term (12 weeks) in order to register bimolecular modification (quantitative real time PCRand western blot), morphological modification (optic and electronic microscope) and functional changing (grasping test). Bimolecular analysis showed that muscle fibbers produced and released Neuregulin1, needed for regeneration and activity of Schwann cells. Otherwise also the autograft product Neuregulin1, instead no production was observed in empty conduit. So muscle fibbers compensate this fact. Morphological analysis showed that the first myelinc fibbers appear in MIT after 14 days, but not in empty tube. The results of our work are very interesting because can merge the easiness of the implantation of chitosan tube and the efficacy of fresh muscle fibbers, as previously demonstrated by muscle in vein technique. From a clinical point of view this procedure could be an alternative to auto grafting that is nowadays the gold standard for nerve repair, but present soma disadvantages