Biocompatibility analysis of poly(glycerol sebacate) as a nerve guide material.

No satisfactory method currently exists for bridging neural defects. Autografts lead to inadequate functional recovery, and most available artificial neural conduits possess unfavorable swelling and pro-inflammatory characteristics. This study examined the biocompatibility of a novel biodegradable elastomer, poly(glycerol sebacate) (PGS), for neural reconstruction applications, as the material possesses favorable mechanical property and degradation characteristics. The effect of PGS on Schwann cell metabolic activity, attachment, proliferation, and apoptosis were examined in vitro in comparison with poly(lactide-co-glycolide) (PLGA), a biomaterial widely utilized for tissue engineering applications. The in vivo tissue response to PGS was compared with PLGA implanted juxtaposed to the sciatic nerve; the physical changes in the implant material were measured during the degradation process. PGS had no deleterious effect on Schwann cell metabolic activity, attachment, or proliferation, and did not induce apoptosis; the in vitro effects of PGS were similar to or superior to that of PLGA. In vivo, PGS demonstrated a favorable tissue response profile compared with PLGA, with significantly less inflammation and fibrosis and without detectable swelling during degradation. PGS is an excellent candidate material for neural reconstruction applications given its lack of in vitro Schwann cell toxicity and minimal in vivo tissue response.

[1]  C. Patrick,et al.  In vivo evaluation of poly(L-lactic acid) porous conduits for peripheral nerve regeneration. , 1999, Biomaterials.

[2]  J. Feijen,et al.  Copolymers of trimethylene carbonate and ε-caprolactone for porous nerve guides: Synthesis and properties , 2001 .

[3]  P. Caliceti,et al.  Peripheral nerve repair using a poly(organo)phosphazene tubular prosthesis. , 1995, Biomaterials.

[4]  R. Bareille,et al.  Study of a (trimethylenecarbonate-co-epsilon-caprolactone) polymer--part 2: in vitro cytocompatibility analysis and in vivo ED1 cell response of a new nerve guide. , 2001, Biomaterials.

[5]  Robert Langer,et al.  In vivo degradation characteristics of poly(glycerol sebacate). , 2003, Journal of biomedical materials research. Part A.

[6]  J. Vacanti,et al.  A polymer foam conduit seeded with Schwann cells promotes guided peripheral nerve regeneration. , 2000, Tissue engineering.

[7]  A. Mingotaud,et al.  Study of a (trimethylenecarbonate-co-epsilon-caprolactone) polymer part 1: preparation of a new nerve guide through controlled random copolymerization using rare earth catalysts. , 2001, Biomaterials.

[8]  W. D. den Dunnen,et al.  Biological performance of a degradable poly(lactic acid-epsilon-caprolactone) nerve guide: influence of tube dimensions. , 1995, Journal of biomedical materials research.

[9]  M. Raff,et al.  Studies on cultured rat Schwann cells. I. Establishment of purified populations from cultures of peripheral nerve , 1979, Brain Research.

[10]  A. Valero-Cabré,et al.  Superior muscle reinnervation after autologous nerve graft or poly‐L‐lactide‐ϵ‐caprolactone (PLC) tube implantation in comparison to silicone tube repair , 2001, Journal of neuroscience research.

[11]  Susan E. Mackinnon,et al.  Clinical Nerve Reconstruction with a Bioabsorbable Polyglycolic Acid Tube , 1990, Plastic and reconstructive surgery.

[12]  C. Patrick,et al.  Manufacture of porous biodegradable polymer conduits by an extrusion process for guided tissue regeneration. , 1998, Biomaterials.

[13]  X Navarro,et al.  Highly permeable polylactide-caprolactone nerve guides enhance peripheral nerve regeneration through long gaps. , 1999, Biomaterials.

[14]  B O Palsson,et al.  Chemical Decomposition of Glutamine in Cell Culture Media: Effect of Media Type, pH, and Serum Concentration , 1990, Biotechnology progress.

[15]  R. Langer,et al.  A tough biodegradable elastomer , 2002, Nature Biotechnology.

[16]  J F Orr,et al.  Processing, annealing and sterilisation of poly-L-lactide. , 2004, Biomaterials.

[17]  Patrick R. Griffin,et al.  Identification and inhibition of the ICE/CED-3 protease necessary for mammalian apoptosis , 1995, Nature.

[18]  S L Woo,et al.  An in vitro mechanical and histological study of acute stretching on rabbit tibial nerve , 1990, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[19]  U. Landegren Measurement of cell numbers by means of the endogenous enzyme hexosaminidase. Applications to detection of lymphokines and cell surface antigens. , 1984, Journal of immunological methods.

[20]  R. Sidman,et al.  Nerve regeneration through biodegradable polyester tubes , 1985, Experimental Neurology.

[21]  J. Feijen,et al.  Adhesion and growth of human Schwann cells on trimethylene carbonate (co)polymers. , 2003, Journal of biomedical materials research. Part A.

[22]  Göran Lundborg,et al.  Nerve Injury and Repair , 1988 .

[23]  P H Robinson,et al.  Nerve regeneration through a two‐ply biodegradable nerve guide in the rat and the influence of ACTH4‐9 nerve growth factor , 1991, Microsurgery.

[24]  J. Feijen,et al.  Copolymers of trimethylene carbonate and epsilon-caprolactone for porous nerve guides: synthesis and properties. , 2001, Journal of biomaterials science. Polymer edition.

[25]  P H Robinson,et al.  Poly(DL‐lactide‐ϵ‐caprolactone) nerve guides perform better than autologous nerve grafts , 1996, Microsurgery.

[26]  K. O. Elliston,et al.  A novel heterodimeric cysteine protease is required for interleukin-1βprocessing in monocytes , 1992, Nature.

[27]  M. Spector,et al.  Optimal Degradation Rate for Collagen Chambers Used for Regeneration of Peripheral Nerves over Long Gaps , 2004, Cells Tissues Organs.