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Integrated dynamic wet spinning of core-sheath hydrogel fibers for optical-to-brain/tissue communications

Guoyin Chen, Gang Wang, Xinrong Tan, Kai Hou, Qingshuo Meng, Peng Zhao, Shun Wang, Jiayi Zhang, Zhan Zhou, Tao Chen, Yanhua Cheng, Benjamin S. Hsiao, Elsa Reichmanis, Meifang Zhu

2020National Science Review99 citationsDOIOpen Access PDF

Abstract

Abstract Hydrogel optical light-guides have received substantial interest for applications such as deep-tissue biosensors, optogenetic stimulation and photomedicine due to their biocompatibility, (micro)structure control and tissue-like Young's modulus. However, despite recent developments, large-scale fabrication with a continuous synthetic methodology, which could produce core-sheath hydrogel fibers with the desired optical and mechanical properties suitable for deep-tissue applications, has yet to be achieved. In this study, we report a versatile concept of integrated light-triggered dynamic wet spinning capable of continuously producing core-sheath hydrogel optical fibers with tunable fiber diameters, and mechanical and optical propagation properties. Furthermore, this concept also exhibited versatility for various kinds of core-sheath functional fibers. The wet spinning synthetic procedure and fabrication process were optimized with the rational design of the core/sheath material interface compatibility [core = poly(ethylene glycol diacrylate-co-acrylamide); sheath = Ca-alginate], optical transparency, refractive index and spinning solution viscosity. The resulting hydrogel optical fibers exhibited desirable low optical attenuation (0.18 ± 0.01 dB cm−1 with 650 nm laser light), excellent biocompatibility and tissue-like Young's modulus (<2.60 MPa). The optical waveguide hydrogel fibers were successfully employed for deep-tissue cancer therapy and brain optogenetic stimulation, confirming that they could serve as an efficient versatile tool for diverse deep-tissue therapy and brain optogenetic applications.

Topics & Concepts

Materials scienceOptical fiberBiocompatibilityFabricationTissue engineeringCore (optical fiber)NanotechnologyBiomedical engineeringComposite materialOpticsPathologyAlternative medicinePhysicsMetallurgyMedicinePhotoreceptor and optogenetics researchAdvanced Sensor and Energy Harvesting MaterialsLaser Applications in Dentistry and Medicine
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