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SilkBridge™: a novel biomimetic and biocompatible silk-based nerve conduit

Silk fibroin ( Bombyx mori ) was used to manufacture a nerve conduit (SilkBridge™) characterized by a novel 3D architecture. The wall of the conduit consists of two electrospun layers (inner and outer) and one textile layer (middle), perfectly integrated at the structural and functional level. The m...

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Published in:	Biomaterials science 2019-10, Vol.7 (1), p.4112-413
Main Authors:	Alessandrino, A, Fregnan, F, Biagiotti, M, Muratori, L, Bassani, G. A, Ronchi, G, Vincoli, V, Pierimarchi, P, Geuna, S, Freddi, G
Format:	Article
Language:	English
Subjects:	Animals Biocompatibility Biocompatible Materials Biological properties Biomechanics Biomimetics Biotechnology Blood vessels Cell Adhesion Cell Line Cell Proliferation Compressive properties Compressive strength Contact stresses Female Fibroins Median nerve Median Nerve - physiology Mice Morphology Myelin Nerve Regeneration Nerve Tissue Rats, Wistar Sheaths Silk fibroin Substrates
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cited_by	cdi_FETCH-LOGICAL-c414t-4489f713748a2a9f88b2ce870c2ee5dcb514132be950aa1f3280a053faede9ac3
cites	cdi_FETCH-LOGICAL-c414t-4489f713748a2a9f88b2ce870c2ee5dcb514132be950aa1f3280a053faede9ac3
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container_title	Biomaterials science
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creator	Alessandrino, A Fregnan, F Biagiotti, M Muratori, L Bassani, G. A Ronchi, G Vincoli, V Pierimarchi, P Geuna, S Freddi, G
description	Silk fibroin ( Bombyx mori ) was used to manufacture a nerve conduit (SilkBridge™) characterized by a novel 3D architecture. The wall of the conduit consists of two electrospun layers (inner and outer) and one textile layer (middle), perfectly integrated at the structural and functional level. The manufacturing technology conferred high compression strength on the device, thus meeting clinical requirements for physiological and pathological compressive stresses. In vitro cell interaction studies were performed through direct contact assays with SilkBridge™ using the glial RT4-D6P2T cells, a schwannoma cell line, and a mouse motor neuron NSC-34 cell line. The results revealed that the material is capable of sustaining cell proliferation, that the glial RT4-D6P2T cells increased their density and organized themselves in a glial-like morphology, and that NSC-34 motor neurons exhibited a greater neuritic length with respect to the control substrate. In vivo pilot assays were performed on adult female Wistar rats. A 10 mm long gap in the median nerve was repaired with 12 mm SilkBridge™. At two weeks post-operation several cell types colonized the lumen. Cells and blood vessels were also visible between the different layers of the conduit wall. Moreover, the presence of regenerated myelinated fibers with a thin myelin sheath at the proximal level was observed. Taken together, all these results demonstrated that SilkBridge™ has an optimized balance of biomechanical and biological properties, being able to sustain a perfect cellular colonization of the conduit and the progressive growth of the regenerating nerve fibers. SilkBridge™: off-the-shelf nerve conduit with a novel hybrid textile-electrospun tubular architecture, highly biocompatible, and effective at sustaining the in vivo regeneration of nerve fibers.
doi_str_mv	10.1039/c9bm00783k
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A ; Ronchi, G ; Vincoli, V ; Pierimarchi, P ; Geuna, S ; Freddi, G</creator><creatorcontrib>Alessandrino, A ; Fregnan, F ; Biagiotti, M ; Muratori, L ; Bassani, G. A ; Ronchi, G ; Vincoli, V ; Pierimarchi, P ; Geuna, S ; Freddi, G</creatorcontrib><description>Silk fibroin ( Bombyx mori ) was used to manufacture a nerve conduit (SilkBridge™) characterized by a novel 3D architecture. The wall of the conduit consists of two electrospun layers (inner and outer) and one textile layer (middle), perfectly integrated at the structural and functional level. The manufacturing technology conferred high compression strength on the device, thus meeting clinical requirements for physiological and pathological compressive stresses. In vitro cell interaction studies were performed through direct contact assays with SilkBridge™ using the glial RT4-D6P2T cells, a schwannoma cell line, and a mouse motor neuron NSC-34 cell line. The results revealed that the material is capable of sustaining cell proliferation, that the glial RT4-D6P2T cells increased their density and organized themselves in a glial-like morphology, and that NSC-34 motor neurons exhibited a greater neuritic length with respect to the control substrate. In vivo pilot assays were performed on adult female Wistar rats. A 10 mm long gap in the median nerve was repaired with 12 mm SilkBridge™. At two weeks post-operation several cell types colonized the lumen. Cells and blood vessels were also visible between the different layers of the conduit wall. Moreover, the presence of regenerated myelinated fibers with a thin myelin sheath at the proximal level was observed. Taken together, all these results demonstrated that SilkBridge™ has an optimized balance of biomechanical and biological properties, being able to sustain a perfect cellular colonization of the conduit and the progressive growth of the regenerating nerve fibers. 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In vitro cell interaction studies were performed through direct contact assays with SilkBridge™ using the glial RT4-D6P2T cells, a schwannoma cell line, and a mouse motor neuron NSC-34 cell line. The results revealed that the material is capable of sustaining cell proliferation, that the glial RT4-D6P2T cells increased their density and organized themselves in a glial-like morphology, and that NSC-34 motor neurons exhibited a greater neuritic length with respect to the control substrate. In vivo pilot assays were performed on adult female Wistar rats. A 10 mm long gap in the median nerve was repaired with 12 mm SilkBridge™. At two weeks post-operation several cell types colonized the lumen. Cells and blood vessels were also visible between the different layers of the conduit wall. Moreover, the presence of regenerated myelinated fibers with a thin myelin sheath at the proximal level was observed. 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A</au><au>Ronchi, G</au><au>Vincoli, V</au><au>Pierimarchi, P</au><au>Geuna, S</au><au>Freddi, G</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>SilkBridge™: a novel biomimetic and biocompatible silk-based nerve conduit</atitle><jtitle>Biomaterials science</jtitle><addtitle>Biomater Sci</addtitle><date>2019-10-01</date><risdate>2019</risdate><volume>7</volume><issue>1</issue><spage>4112</spage><epage>413</epage><pages>4112-413</pages><issn>2047-4830</issn><eissn>2047-4849</eissn><abstract>Silk fibroin ( Bombyx mori ) was used to manufacture a nerve conduit (SilkBridge™) characterized by a novel 3D architecture. The wall of the conduit consists of two electrospun layers (inner and outer) and one textile layer (middle), perfectly integrated at the structural and functional level. The manufacturing technology conferred high compression strength on the device, thus meeting clinical requirements for physiological and pathological compressive stresses. In vitro cell interaction studies were performed through direct contact assays with SilkBridge™ using the glial RT4-D6P2T cells, a schwannoma cell line, and a mouse motor neuron NSC-34 cell line. The results revealed that the material is capable of sustaining cell proliferation, that the glial RT4-D6P2T cells increased their density and organized themselves in a glial-like morphology, and that NSC-34 motor neurons exhibited a greater neuritic length with respect to the control substrate. In vivo pilot assays were performed on adult female Wistar rats. A 10 mm long gap in the median nerve was repaired with 12 mm SilkBridge™. At two weeks post-operation several cell types colonized the lumen. Cells and blood vessels were also visible between the different layers of the conduit wall. Moreover, the presence of regenerated myelinated fibers with a thin myelin sheath at the proximal level was observed. 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subjects	Animals Biocompatibility Biocompatible Materials Biological properties Biomechanics Biomimetics Biotechnology Blood vessels Cell Adhesion Cell Line Cell Proliferation Compressive properties Compressive strength Contact stresses Female Fibroins Median nerve Median Nerve - physiology Mice Morphology Myelin Nerve Regeneration Nerve Tissue Rats, Wistar Sheaths Silk fibroin Substrates
title	SilkBridge™: a novel biomimetic and biocompatible silk-based nerve conduit
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