用于柔性仿生和生物电子界面的无线供电和数据传输技术:材料与应用

Massimo Mariello, Christopher M. Proctor
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引用次数: 0

摘要

下一代仿生学,更具体地说,可穿戴和植入式生物电子学,需要无线、无电池、长期运行和无缝生物集成。设计考虑因素、材料选择和高效架构的实施对无线设备的制造和部署至关重要,尤其是柔性或软性设备。无线供电和数据传输是为健康监测、先进疾病诊断和治疗以及个性化医疗开发稳健、高效和可靠系统的关键要素。本文回顾了用于生物集成柔性仿生和生物电子系统中的无线能量来源和遥测的材料和技术的最新进展。该研究探讨了与机械顺应性、低厚度、小尺寸、生物相容性、生物降解性和体内实施有关的各种挑战。研究还深入探讨了用于量化无线功率/数据传输性能的主要性能指标。最后,还总结了可穿戴和植入式无线仿生学/生物电子学的关键应用,如电刺激/记录、生理参数实时监测、光学接口光传输、通过超声波进行机电刺激等,强调了其未来实施的潜力及其商业化的相关挑战。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Wireless Power and Data Transfer Technologies for Flexible Bionic and Bioelectronic Interfaces: Materials and Applications

Wireless Power and Data Transfer Technologies for Flexible Bionic and Bioelectronic Interfaces: Materials and Applications
The next‐generation bionics and, more specifically, wearable and implantable bioelectronics require wireless, battery‐free, long‐term operation and seamless bio‐integration. Design considerations, materials choice, and implementation of efficient architectures have become crucial for the fabrication and deployment of wireless devices, especially if they are flexible or soft. Wireless power and data transfer represent key elements for the development of robust, efficient, and reliable systems for health monitoring, advanced disease diagnosis and treatment, personalized medicine. Here, the recent advances in materials and technologies used for wireless energy sourcing and telemetry in bio‐integrated flexible bionic and bioelectronic systems are reviewed. The study tackles different challenges related to mechanical compliance, low thickness, small footprint, biocompatibility, biodegradability, and in vivo implementation. The work also delves into the main figures of merit that are mostly adopted to quantify the wireless power/data transfer performances. Lastly, the pivotal applications of wearable and implantable wireless bionics/bioelectronics are summarized, such as electrical stimulation/recording, real‐time monitoring of physiological parameters, light delivery trough optical interfaces, electromechanical stimulation via ultrasounds, highlighting their potential for future implementation and the challenges related to their commercialization.
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