Fully biocompatible, thermally drawn fiber supercapacitors for long-term bio-implantation
7.4
来源:
Nature
发布时间:
2025-09-03 03:36
摘要:
THBS fibers represent a significant advancement in biocompatible energy storage for implantable devices, integrating all components into a single fiber architecture. These fibers demonstrate exceptional electrochemical performance and biocompatibility, maintaining stability under physiological conditions. Successful in vivo applications include powering optogenetic devices for nerve stimulation, highlighting their potential in biomedical technology. The thermal drawing process used for fabrication supports scalability, making THBS fibers a promising solution for future implantable bioelectronics.
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关键证据
THBS fibers exhibited long-term functionality with minimal immune response in vivo.
The fibers maintained high electrochemical performance under dynamic physiological conditions.
The study emphasizes the scalability of the thermal drawing process for mass production.
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AI评分总结
THBS fibers represent a significant advancement in biocompatible energy storage for implantable devices, integrating all components into a single fiber architecture. These fibers demonstrate exceptional electrochemical performance and biocompatibility, maintaining stability under physiological conditions. Successful in vivo applications include powering optogenetic devices for nerve stimulation, highlighting their potential in biomedical technology. The thermal drawing process used for fabrication supports scalability, making THBS fibers a promising solution for future implantable bioelectronics.