Bioresorbable glass fibres facilitate peripheral nerve regeneration

S Bunting; L DiSilvio; S Deb; S Hall

doi:10.1016/j.jhsb.2004.11.003

Bioresorbable glass fibres facilitate peripheral nerve regeneration

S Bunting, L DiSilvio, S Deb, S Hall

Research output: Contribution to journal › Article › peer-review

77 Citations (Scopus)

Abstract

This is a proof of principle report showing that fibres of Bioglass((R)) 45S5 can form a biocompatible scaffold to guide regrowing peripheral axons in vivo. We demonstrate that cultured rat Schwann cells and fibroblasts grow on Bioglass((R)) fibres in vitro using SEM and immunohistochemistry, and provide qualitative and quantitative evidence of axonal regeneration through a Silastic conduit filled with Bioglass((R)) fibres in vivo (across a 0.5cm interstump gap in the sciatic nerves of adult rats). Axonal regrowth at 4 weeks is indistinguishable from that which occurs across an autograft. Bioglass((R)) fibres are not only biocompatible and bioresorbable, which are absolute requirements of successful devices, but are also amenable to bioengineering, and therefore have the potential for use in the most challenging clinical cases, where there are long inter-stump gaps to be bridged.

Original language	English
Pages (from-to)	242 - 247
Number of pages	6
Journal	Journal of Hand Surgery British Volume
Volume	30
Issue number	3
DOIs	https://doi.org/10.1016/j.jhsb.2004.11.003
Publication status	Published - Jun 2005

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10.1016/j.jhsb.2004.11.003

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title = "Bioresorbable glass fibres facilitate peripheral nerve regeneration",

abstract = "This is a proof of principle report showing that fibres of Bioglass((R)) 45S5 can form a biocompatible scaffold to guide regrowing peripheral axons in vivo. We demonstrate that cultured rat Schwann cells and fibroblasts grow on Bioglass((R)) fibres in vitro using SEM and immunohistochemistry, and provide qualitative and quantitative evidence of axonal regeneration through a Silastic conduit filled with Bioglass((R)) fibres in vivo (across a 0.5cm interstump gap in the sciatic nerves of adult rats). Axonal regrowth at 4 weeks is indistinguishable from that which occurs across an autograft. Bioglass((R)) fibres are not only biocompatible and bioresorbable, which are absolute requirements of successful devices, but are also amenable to bioengineering, and therefore have the potential for use in the most challenging clinical cases, where there are long inter-stump gaps to be bridged.",

author = "S Bunting and L DiSilvio and S Deb and S Hall",

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T1 - Bioresorbable glass fibres facilitate peripheral nerve regeneration

AU - Bunting, S

AU - DiSilvio, L

AU - Deb, S

AU - Hall, S

PY - 2005/6

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N2 - This is a proof of principle report showing that fibres of Bioglass((R)) 45S5 can form a biocompatible scaffold to guide regrowing peripheral axons in vivo. We demonstrate that cultured rat Schwann cells and fibroblasts grow on Bioglass((R)) fibres in vitro using SEM and immunohistochemistry, and provide qualitative and quantitative evidence of axonal regeneration through a Silastic conduit filled with Bioglass((R)) fibres in vivo (across a 0.5cm interstump gap in the sciatic nerves of adult rats). Axonal regrowth at 4 weeks is indistinguishable from that which occurs across an autograft. Bioglass((R)) fibres are not only biocompatible and bioresorbable, which are absolute requirements of successful devices, but are also amenable to bioengineering, and therefore have the potential for use in the most challenging clinical cases, where there are long inter-stump gaps to be bridged.

AB - This is a proof of principle report showing that fibres of Bioglass((R)) 45S5 can form a biocompatible scaffold to guide regrowing peripheral axons in vivo. We demonstrate that cultured rat Schwann cells and fibroblasts grow on Bioglass((R)) fibres in vitro using SEM and immunohistochemistry, and provide qualitative and quantitative evidence of axonal regeneration through a Silastic conduit filled with Bioglass((R)) fibres in vivo (across a 0.5cm interstump gap in the sciatic nerves of adult rats). Axonal regrowth at 4 weeks is indistinguishable from that which occurs across an autograft. Bioglass((R)) fibres are not only biocompatible and bioresorbable, which are absolute requirements of successful devices, but are also amenable to bioengineering, and therefore have the potential for use in the most challenging clinical cases, where there are long inter-stump gaps to be bridged.

U2 - 10.1016/j.jhsb.2004.11.003

DO - 10.1016/j.jhsb.2004.11.003

M3 - Article

VL - 30

SP - 242

EP - 247

JO - Journal of Hand Surgery British Volume

JF - Journal of Hand Surgery British Volume

IS - 3

ER -

Bioresorbable glass fibres facilitate peripheral nerve regeneration

Abstract

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