近年來,個人化健康監測系統於醫療復健領域已展現出高度潛力,尤其在運動傷害管理及預防方面。然而,傳統技術如肌電圖(Electromyography, EMG)和磁振造影(Magnetic Resonance Imaging, MRI)因成本高、無法持續監測等限制,難以廣泛應用。另一方面,穿戴式醫療電子技術雖可即時追蹤人體活動,但現有技術仍受限於檢測範圍狹窄、功能單一及供電永續性等問題。因此,本研究提出了一種基於層狀奈米材料之可拉伸感測系統。該奈米材料不僅具備可調變的電荷傳輸特性,更可有效識別人體複雜運動模式。我們相信本研究展示了一種低成本、自供電、可長時間檢測、以及高靈敏度的復健監測系統設計,能為下一代醫療電子產品的開發及高性能健康監測提供了新方向。;In recent years, personalized health monitoring systems have shown great potential in the field of medical rehabilitation, particularly in the management and prevention of sports injuries. However, conventional techniques such as electromyography (EMG) and magnetic resonance imaging (MRI) are difficult to apply widely due to their high cost and inability to provide continuous monitoring. On the other hand, although wearable medical electronics can track human activities in real time, existing technologies are still limited by narrow detection ranges, single functionality, and poor power sustainability. Therefore, this study proposes a stretchable sensing system based on layered nanomaterials. The nanomaterials not only exhibit tunable charge transport properties but also enable effective recognition of complex human motion patterns. We believe that this study demonstrates a low-cost, self-powered, long-term monitoring, and highly sensitive rehabilitation system design, offering new directions for the development of next-generation medical electronics and high-performance health monitoring technologies.
