# A Wearable System Featuring Biomimetic Spatially Distributed Iontronic Sensing Array for Dynamic Monitoring of Deep Tissue Modulus

**Authors:** Zhenning Wang, Chaohua Fang, Ruoyu Sun, Chenghao Feng, Xiaoyuan Wang, Hao Bi, Yidan Wu, Jiangdong Gong, Yuyang Wang, Jiahao Guo, Yu Chang, Huizhi Wang, Tingrui Pan

PMC · DOI: 10.1002/advs.202519009 · Advanced Science · 2025-11-25

## TL;DR

This paper introduces a wearable system that can dynamically monitor deep tissue stiffness, offering potential for home-based health tracking and injury prevention.

## Contribution

The novel wearable system uses a biomimetic iontronic sensing array to enable real-time, dynamic modulus monitoring of deep muscle tissues.

## Key findings

- The system achieves high accuracy (>93%) in measuring tissue modulus and is robust to sweat and mechanical fatigue.
- It correlates strongly with clinical edema indicators in postoperative patients and tracks muscle hardness during various physical activities.
- The device supports dynamic operation and minimizes discomfort through a simulation-informed indentation strategy.

## Abstract

Assessing soft tissue hardness is critical for disease diagnosis and motion monitoring. However, existing technologies are confined to skin‐level and quasi‐static measurements, leaving the dynamic behavior of deeper tissues, such as muscle, inaccessible. This study introduces a wearable system that enables dynamic monitoring of Young's modulus in multilayer tissues containing deep muscle (DMYD). Inspired by the spatial encoding strategy of human mechanoreceptors, DMYD integrates spatially distributed, high‐resolution, low‐detection‐limit iontronic sensing arrays with a load sensor to continuously capture the contact radius and contact force between a hemispherical indenter and the tissue, allowing real‐time and accurate modulus estimation based on Hertz contact theory. A simulation‐informed indentation strategy optimizes the accuracy of measurements in deep, multilayer tissues while minimizing wearing discomfort. In vitro experiments demonstrate that DMYD achieves high accuracy (>93%), supports dynamic operation, and remains robust to signal drift, sweat, and mechanical fatigue. In postoperative patients, its measurements correlate strongly with clinical edema indicators, while in healthy users, it tracks task‐dependent muscle hardness dynamics during rest, loaded elbow flexion, rope skipping, and stretching. Collectively, these results highlight DMYD as a promising platform for personalized and home‐based disease management, performance evaluation, injury‐risk warning, and training strategy optimization.

A fully wearable system enables real‐time, dynamic, and accurate monitoring of Young's modulus in multilayer tissues containing deep muscle. It demonstrates high accuracy and robustness across simulations, benchtop validations, and human testing. It quantifies edema severity and tracks muscle stiffness during rest, loaded elbow flexion, rope skipping, and stretching, showing strong potential for personalized, home‐based health monitoring and performance optimization.

## Full-text entities

- **Diseases:** edema (MESH:D004487)
- **Species:** Homo sapiens (human, species) [taxon 9606]

## Full text

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## Figures

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## References

50 references — full list in the complete paper: https://tomesphere.com/paper/PMC12884733/full.md

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Source: https://tomesphere.com/paper/PMC12884733