Nanostructures to Engineer 3D Neural‐Interfaces: Directing Axonal Navigation toward Successful Bridging of Spinal Segments

Neural interfaces are the core of prosthetic devices, such as implantable stimulating electrodes or brain–machine interfaces, and are increasingly designed for assisting rehabilitation and for promoting neural plasticity. Thus, beyond the classical neuroprosthetic concept of stimulating and/or recor...

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Veröffentlicht in:	Advanced functional materials 2018-03, Vol.28 (12), p.n/a
Hauptverfasser:	Aurand, Emily R., Usmani, Sadaf, Medelin, Manuela, Scaini, Denis, Bosi, Susanna, Rosselli, Federica B., Donato, Sandro, Tromba, Giuliana, Prato, Maurizio, Ballerini, Laura
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Sprache:	eng
Schlagworte:	3D X‐ray microtomography Axons Brain Carbon Carbon nanotubes elastomeric scaffolds Electrodes electrophysiology Materials science Microtomography Nanotubes organotypic cultures Polydimethylsiloxane Porosity Prostheses Rehabilitation Silicone resins spinal cord Substrates Surgical implants
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container_title	Advanced functional materials
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description	Neural interfaces are the core of prosthetic devices, such as implantable stimulating electrodes or brain–machine interfaces, and are increasingly designed for assisting rehabilitation and for promoting neural plasticity. Thus, beyond the classical neuroprosthetic concept of stimulating and/or recording devices, modern technology is pursuing toward ideal bio/electrode interfaces with improved adaptability to the brain tissue. Advances in material research are crucial in these efforts and new developments are drawing from engineering and neural interface technologies. Here, a microporous, self‐standing, 3D interface made of polydimethylsiloxane (PDMS) implemented at the interfacing surfaces with novel conductive nanotopographies (carbon nanotubes) is exploited. The scaffold porosity is characterized by 3D X‐ray microtomography. These structures are used to interface axons regenerated from cultured spinal explants and it is shown that engineering PDMS 3D interfaces with carbon nanotubes effectively changes the efficacy of regenerating fibers to target and reconnect segregated explant pairs. An improved electrophysiological performance is shown when the spinal tissue is interfaced to PDMS enriched by carbon nanotubes that may favor the use of our substrates as regenerative interfaces. The materials are implanted in the rat brain and a limited tissue reaction surrounding the implants at 2, 4, and 8 weeks from surgery is reported. A microporous, 3D interface made of polydimethylsiloxane implemented at the interfacing surfaces with novel conductive nanotopographies (carbon nanotubes) is created. Interfacing this structure to spinal explants changes the efficacy of regenerating fibers to reconnect segregated explant pairs. This 3D structure is tested for the first time in vivo and a limited brain reaction surrounding the implants is reported.
doi_str_mv	10.1002/adfm.201700550
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Thus, beyond the classical neuroprosthetic concept of stimulating and/or recording devices, modern technology is pursuing toward ideal bio/electrode interfaces with improved adaptability to the brain tissue. Advances in material research are crucial in these efforts and new developments are drawing from engineering and neural interface technologies. Here, a microporous, self‐standing, 3D interface made of polydimethylsiloxane (PDMS) implemented at the interfacing surfaces with novel conductive nanotopographies (carbon nanotubes) is exploited. The scaffold porosity is characterized by 3D X‐ray microtomography. These structures are used to interface axons regenerated from cultured spinal explants and it is shown that engineering PDMS 3D interfaces with carbon nanotubes effectively changes the efficacy of regenerating fibers to target and reconnect segregated explant pairs. An improved electrophysiological performance is shown when the spinal tissue is interfaced to PDMS enriched by carbon nanotubes that may favor the use of our substrates as regenerative interfaces. The materials are implanted in the rat brain and a limited tissue reaction surrounding the implants at 2, 4, and 8 weeks from surgery is reported. A microporous, 3D interface made of polydimethylsiloxane implemented at the interfacing surfaces with novel conductive nanotopographies (carbon nanotubes) is created. Interfacing this structure to spinal explants changes the efficacy of regenerating fibers to reconnect segregated explant pairs. 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Thus, beyond the classical neuroprosthetic concept of stimulating and/or recording devices, modern technology is pursuing toward ideal bio/electrode interfaces with improved adaptability to the brain tissue. Advances in material research are crucial in these efforts and new developments are drawing from engineering and neural interface technologies. Here, a microporous, self‐standing, 3D interface made of polydimethylsiloxane (PDMS) implemented at the interfacing surfaces with novel conductive nanotopographies (carbon nanotubes) is exploited. The scaffold porosity is characterized by 3D X‐ray microtomography. These structures are used to interface axons regenerated from cultured spinal explants and it is shown that engineering PDMS 3D interfaces with carbon nanotubes effectively changes the efficacy of regenerating fibers to target and reconnect segregated explant pairs. An improved electrophysiological performance is shown when the spinal tissue is interfaced to PDMS enriched by carbon nanotubes that may favor the use of our substrates as regenerative interfaces. The materials are implanted in the rat brain and a limited tissue reaction surrounding the implants at 2, 4, and 8 weeks from surgery is reported. A microporous, 3D interface made of polydimethylsiloxane implemented at the interfacing surfaces with novel conductive nanotopographies (carbon nanotubes) is created. Interfacing this structure to spinal explants changes the efficacy of regenerating fibers to reconnect segregated explant pairs. This 3D structure is tested for the first time in vivo and a limited brain reaction surrounding the implants is reported.</description><subject>3D X‐ray microtomography</subject><subject>Axons</subject><subject>Brain</subject><subject>Carbon</subject><subject>Carbon nanotubes</subject><subject>elastomeric scaffolds</subject><subject>Electrodes</subject><subject>electrophysiology</subject><subject>Materials science</subject><subject>Microtomography</subject><subject>Nanotubes</subject><subject>organotypic cultures</subject><subject>Polydimethylsiloxane</subject><subject>Porosity</subject><subject>Prostheses</subject><subject>Rehabilitation</subject><subject>Silicone resins</subject><subject>spinal cord</subject><subject>Substrates</subject><subject>Surgical implants</subject><issn>1616-301X</issn><issn>1616-3028</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2018</creationdate><recordtype>article</recordtype><recordid>eNqFkLtOwzAUQC0EEqWwMltiTvErdcJW-oBKpQwFic1yHTtylTrFTiiVGPgEvpEvIVFRGZnuHc65ujoAXGLUwwiRa5mZdY8gzBGKY3QEOriP-xFFJDk-7PjlFJyFsEINxinrgI-5dGWofK2q2usAqxKOXW6d1h7SEZzr2svi-_Nr6irtjVQ63MCR9VpV1uVw8F46WcC5fLO5rGzpGn8rfQYXtWrQYOoC3nqb5S1cGrjY2JZf6HytXRXOwYmRRdAXv7MLnifjp-F9NHu8mw4Hs0jRlKEIY8JMYjBLMm2WKY8px0tjDMNpu2bMpCTjSGK15InhKZaUxSbhjMokJYrQLrja39348rXWoRKrsvbNJ0G0vTghMaYN1dtTypcheG3Extu19DuBkWgLi7awOBRuhHQvbG2hd__QYjCaPPy5PxrPgYM</recordid><startdate>20180321</startdate><enddate>20180321</enddate><creator>Aurand, Emily R.</creator><creator>Usmani, Sadaf</creator><creator>Medelin, Manuela</creator><creator>Scaini, Denis</creator><creator>Bosi, Susanna</creator><creator>Rosselli, Federica B.</creator><creator>Donato, Sandro</creator><creator>Tromba, Giuliana</creator><creator>Prato, Maurizio</creator><creator>Ballerini, Laura</creator><general>Wiley Subscription Services, Inc</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7SP</scope><scope>7SR</scope><scope>7U5</scope><scope>8BQ</scope><scope>8FD</scope><scope>JG9</scope><scope>L7M</scope><orcidid>https://orcid.org/0000-0001-8420-0787</orcidid></search><sort><creationdate>20180321</creationdate><title>Nanostructures to Engineer 3D Neural‐Interfaces: Directing Axonal Navigation toward Successful Bridging of Spinal Segments</title><author>Aurand, Emily R. ; 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subjects	3D X‐ray microtomography Axons Brain Carbon Carbon nanotubes elastomeric scaffolds Electrodes electrophysiology Materials science Microtomography Nanotubes organotypic cultures Polydimethylsiloxane Porosity Prostheses Rehabilitation Silicone resins spinal cord Substrates Surgical implants
title	Nanostructures to Engineer 3D Neural‐Interfaces: Directing Axonal Navigation toward Successful Bridging of Spinal Segments
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