骨关节炎
生物医学工程
压力传感器
膝关节
体内
接头(建筑物)
生物相容性
生物相容性材料
材料科学
无线
计算机科学
离体
软骨
关节软骨
全膝关节置换术
医学
无线传感器网络
再生(生物学)
滑膜关节
康复
膝关节软骨
远程病人监护
作者
Jinyoung Park,Nidhi Sharma,Aseno Sakhrie,Yuhui Zhu,Gülşah Erel‐Akbaba,Nitu Bhaskar,Zhiming Li,Somasundaram Prasadh,Parbeen Singh,Feifei Huang,Cao-Sang Truong,Kishan Angadi,Achal Duhoon,Thinh T. Le,Tra Vinikoor,Dong Chen,Bonnie Plickert,Ramaswamy M. Chidambaram,Thanh D. Nguyen
出处
期刊:Science Advances
[American Association for the Advancement of Science]
日期:2026-06-26
卷期号:12 (26): eaec8210-eaec8210
标识
DOI:10.1126/sciadv.aec8210
摘要
Knee joint loading regulates cartilage regeneration and degeneration, influencing both healing and osteoarthritis (OA) progression. Although defining the optimal range of loading is essential, in vivo measurement remains challenging because current nonbiodegradable sensors require removal surgeries, and computational models provide only indirect estimates. Here, we report a fully biodegradable, implantable piezoelectric pressure sensor composed of biocompatible materials and designed with a single-ended configuration, consisting of only one electrode. This configuration maintained stable performance for more than 2 months, which, to our knowledge, is among the longest functional lifetimes reported for biodegradable pressure sensors. Ex vivo studies simulating the in vivo environment demonstrated accurate monitoring of intracranial pressure and knee movement, while in vivo implantation in a rabbit model confirmed both robust biocompatibility and reliable monitoring of joint loading during natural activities. This platform could enable feedback-guided, personalized rehabilitation regimes for OA management by identifying optimal joint loading conditions.
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