Active-Sensing Epidermal Stretchable Bioelectronic Patch for Noninvasive, Conformal, and Wireless Tendon Monitoring.
Sheng ShuJie AnPengfei ChenDi LiuZiming WangChengyu LiShuangzhe ZhangYuan LiuJianzhe LuoLulu ZuWei TangZhong Lin WangPublished in: Research (Washington, D.C.) (2021)
Sensors capable of monitoring dynamic mechanics of tendons throughout a body in real time could bring systematic information about a human body's physical condition, which is beneficial for avoiding muscle injury, checking hereditary muscle atrophy, and so on. However, the development of such sensors has been hindered by the requirement of superior portability, high resolution, and superb conformability. Here, we present a wearable and stretchable bioelectronic patch for detecting tendon activities. It is made up of a piezoelectric material, systematically optimized from architectures and mechanics, and exhibits a high resolution of 5.8 × 10-5 N with a linearity parameter of R 2 = 0.999. Additionally, a tendon real-time monitoring and healthcare system is established by integrating the patch with a micro controller unit (MCU), which is able to process collected data and deliver feedback for exercise evaluation. Specifically, through the patch on the ankle, we measured the maximum force on the Achilles tendon during jumping which is about 16312 N, which is much higher than that during normal walking (3208 N) and running (5909 N). This work not only provides a strategy for facile monitoring of the variation of the tendon throughout the body but also throws light on the profound comprehension of human activities.
Keyphrases
- high resolution
- endothelial cells
- anterior cruciate ligament reconstruction
- rotator cuff
- skeletal muscle
- physical activity
- high intensity
- induced pluripotent stem cells
- mental health
- autism spectrum disorder
- machine learning
- quantum dots
- healthcare
- blood pressure
- resistance training
- big data
- wound healing
- social media
- deep learning