Biocompatible Optical Fibers Made of Regenerated Cellulose and Recombinant Cellulose-Binding Spider Silk

Martin Reimer; Kai Mayer; Daniel Van Opdenbosch; Thomas Scheibel; Cordt Zollfrank

doi:10.3390/biomimetics8010037

Biocompatible Optical Fibers Made of Regenerated Cellulose and Recombinant Cellulose-Binding Spider Silk

Martin Reimer
, Kai Mayer
, Daniel Van Opdenbosch
, Thomas Scheibel
, Cordt Zollfrank

Chair of Biogenic Polymers

Technical University of Munich
Universität Bayreuth
University of Bayreuth

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

10 Scopus citations

Abstract

The fabrication of green optical waveguides based on cellulose and spider silk might allow the processing of novel biocompatible materials. Regenerated cellulose fibers are used as the core and recombinantly produced spider silk proteins eADF4(C16) as the cladding material. A detected delamination between core and cladding could be circumvented by using a modified spider silk protein with a cellulose-binding domain-enduring permanent adhesion between the cellulose core and the spider silk cladding. The applied spider silk materials were characterized optically, and the theoretical maximum data rate was determined. The results show optical waveguide structures promising for medical applications, for example, in the future.

Original language	English
Article number	37
Journal	Biomimetics
Volume	8
Issue number	1
DOIs	https://doi.org/10.3390/biomimetics8010037
State	Published - Mar 2023

Keywords

attenuation
data rate
light guiding
optogenetic stimulation
photodynamic therapy
transmission

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title = "Biocompatible Optical Fibers Made of Regenerated Cellulose and Recombinant Cellulose-Binding Spider Silk",

abstract = "The fabrication of green optical waveguides based on cellulose and spider silk might allow the processing of novel biocompatible materials. Regenerated cellulose fibers are used as the core and recombinantly produced spider silk proteins eADF4(C16) as the cladding material. A detected delamination between core and cladding could be circumvented by using a modified spider silk protein with a cellulose-binding domain-enduring permanent adhesion between the cellulose core and the spider silk cladding. The applied spider silk materials were characterized optically, and the theoretical maximum data rate was determined. The results show optical waveguide structures promising for medical applications, for example, in the future.",

keywords = "attenuation, data rate, light guiding, optogenetic stimulation, photodynamic therapy, transmission",

author = "Martin Reimer and Kai Mayer and \{Van Opdenbosch\}, Daniel and Thomas Scheibel and Cordt Zollfrank",

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AU - Reimer, Martin

AU - Mayer, Kai

AU - Van Opdenbosch, Daniel

AU - Scheibel, Thomas

AU - Zollfrank, Cordt

PY - 2023/3

Y1 - 2023/3

N2 - The fabrication of green optical waveguides based on cellulose and spider silk might allow the processing of novel biocompatible materials. Regenerated cellulose fibers are used as the core and recombinantly produced spider silk proteins eADF4(C16) as the cladding material. A detected delamination between core and cladding could be circumvented by using a modified spider silk protein with a cellulose-binding domain-enduring permanent adhesion between the cellulose core and the spider silk cladding. The applied spider silk materials were characterized optically, and the theoretical maximum data rate was determined. The results show optical waveguide structures promising for medical applications, for example, in the future.

AB - The fabrication of green optical waveguides based on cellulose and spider silk might allow the processing of novel biocompatible materials. Regenerated cellulose fibers are used as the core and recombinantly produced spider silk proteins eADF4(C16) as the cladding material. A detected delamination between core and cladding could be circumvented by using a modified spider silk protein with a cellulose-binding domain-enduring permanent adhesion between the cellulose core and the spider silk cladding. The applied spider silk materials were characterized optically, and the theoretical maximum data rate was determined. The results show optical waveguide structures promising for medical applications, for example, in the future.

KW - attenuation

KW - data rate

KW - light guiding

KW - optogenetic stimulation

KW - photodynamic therapy

KW - transmission

UR - https://www.scopus.com/pages/publications/85151337312

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DO - 10.3390/biomimetics8010037

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VL - 8

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JF - Biomimetics

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M1 - 37

ER -

Biocompatible Optical Fibers Made of Regenerated Cellulose and Recombinant Cellulose-Binding Spider Silk

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Keywords

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