Abstract EN:

ThiS work aims to design and evaluate a bioresorbable nerve guide channel in order to develop a novel strategy for peripheral nervous system repair. To find an altenative to the autologous nerve graft which is the current clinical Gold Standard, the nerve guide channel we developed is made of poly(D,L-Iactide-b-hydroxyethyl acrylate) (PLA-b-PHEA) block copolymer. The synthesis of the PLA-b-PHEA diblock copolymer combine Ring-Opening Polymerization (ROP) of D. L-Iactide and Nitroxyde-Mediated Polymerization (NMP) of HEA monomer. Our approach to obtain this block copolymer relies on the preparation of SG1-terminated PLA macro-alkoxyamine for further initiation of the NMP of HEA. More precisely, an acrylated end-capped PLA was flrst prepared by ROP of D,L-lactide using HEA monomer as initiator and tin (II) octanoate (Sn(Oct)2) as catalyst. The PLA α-acrylate was further in volved in intermolecular 1,2 radical addition (1,2 IRA) with the MAMA-SG1 macro-alkoxyamine (BlocBuilder) with a high functionnalization yield (90%). The NMP of HEA from this macro-alkoxyamine led to the block copolymers. The cytocompatibility of the PLA-b-PHEA diblock copolymer was checked by quantitative measurement of the Schwann cells adhesion and an increase of 25% of cell density was measured on the PLA-b-PHIEA 85/15 wt % copolymer compared to homo-PLA selected as reference (ANOVA, p = 0,069). Ln vitro and in vivo (rat) degradation studies showed that the increase of PHEA hydrophilic compound proportion in the copolymer accelerates the material weight loss of material and it was possible to tune the degradation kinetics of the biomaterial by varying the PLA/PHEA ratio. Finally, a experimental device to produce nanofibers by electrostatic way was used to prepare tridimensionnal tubular guide with 15 mm length, 1 mm diameter and 0. 1 mm thickness with a fibrous structure close to natural extra-cellular matrix.