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朝向一种有效的传感技术以监测生物电子植入物的微观界面松动。

Towards an effective sensing technology to monitor micro-scale interface loosening of bioelectronic implants.

机构信息

Centre for Mechanical Technology & Automation, TEMA, University of Aveiro, 3810-193, Aveiro, Portugal.

Department of Mechanical Engineering, University of Aveiro, 3810-193, Aveiro, Portugal.

出版信息

Sci Rep. 2021 Feb 10;11(1):3449. doi: 10.1038/s41598-021-82589-3.

DOI:10.1038/s41598-021-82589-3
PMID:33568680
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7876021/
Abstract

Instrumented implants are being developed with a radically innovative design to significantly reduce revision surgeries. Although bone replacements are among the most prevalent surgeries performed worldwide, implant failure rate usually surpasses 10%. High sophisticated multifunctional bioelectronic implants are being researched to incorporate cosurface capacitive architectures with ability to deliver personalized electric stimuli to peri-implant target tissues. However, the ability of these architectures to detect bone-implant interface states has never been explored. Moreover, although more than forty technologies were already proposed to detect implant loosening, none is able to ensure effective monitoring of the bone-implant debonding, mainly during the early stages of loosening. This work shows, for the first time, that cosurface capacitive sensors are a promising technology to provide an effective monitoring of bone-implant interfaces during the daily living of patients. Indeed, in vitro experimental tests and simulation with computational models highlight that both striped and circular capacitive architectures are able to detect micro-scale and macro-scale interface bonding, debonding or loosening, mainly when bonding is weakening or loosening is occurring. The proposed cosurface technologies hold potential to implement highly effective and personalized sensing systems such that the performance of multifunctional bioelectronic implants can be strongly improved. Findings were reported open a new research line on sensing technologies for bioelectronic implants, which may conduct to great impacts in the coming years.

摘要

正在开发具有激进创新设计的仪器植入物,以显著减少翻修手术。尽管骨置换是全球最常见的手术之一,但植入物的失败率通常超过 10%。正在研究高度复杂的多功能生物电子植入物,将共面电容结构与向植入物周围目标组织提供个性化电刺激的能力相结合。然而,这些结构检测骨-植入物界面状态的能力从未被探索过。此外,尽管已经提出了超过四十种技术来检测植入物松动,但没有一种能够确保有效监测骨-植入物脱粘,主要是在松动的早期阶段。这项工作首次表明,共面电容传感器是一种很有前途的技术,可以在患者的日常生活中对骨-植入物界面进行有效监测。事实上,体外实验测试和计算模型模拟表明,条纹和圆形电容结构都能够检测微尺度和宏观尺度的界面结合、脱粘或松动,主要是在结合减弱或松动发生时。所提出的共面技术具有实现高效和个性化传感系统的潜力,从而可以大大提高多功能生物电子植入物的性能。研究结果为生物电子植入物的传感技术开辟了一个新的研究领域,这可能在未来几年产生重大影响。

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