AI Article Synopsis
- Soft conductive gels are crucial for epidermal electronics but struggle with uneven skin surfaces, especially where there's hair or mechanical stress.
- This study presents an in-situ biogel that can shift between liquid and solid states in just 3 minutes using a temperature change, featuring a strong design that enhances its performance.
- The biogel boasts impressive properties like high tensile strength, skin compatibility, and adhesive strength, making it suitable for applications like exercise data tracking, muscle recovery monitoring, and cardiac signal observation.
Article Abstract
Soft conductive gels are essential for epidermal electronics but often face challenges when interfacing with uneven surfaces or areas with extensive hair, especially under mechanical stress. In this study, we employed the concept of liquid-to-solid transformation to enhance integration at biointerfaces and designed an in-situ biogel capable of rapidly transitioning between liquid and solid states within 3 min via a temperature switch. The biogel features a semi-interpenetrating polymer network design and dual conduction pathways, resulting in high tensile strength (~1-3 MPa), a skin-compatible modulus (~0.3-1.1 MPa), strong skin adhesive strength (~1 MPa), and superior signal-to-noise ratio (SNR, ~30-40 dB). The biogel demonstrates significant performance in mechanically demanding environments, showing potential for accurately capturing outdoor exercise data, monitoring muscle recovery from sports-induced fatigue, and in vivo monitoring of cardiac physiological signals. The liquid-to-solid transformation concept, coupled with the design strategy for highly integrated and stable soft conductive materials, provides a basis for advancing conductive interface designs for high-fidelity signal acquisition.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11695986 | PMC |
| http://dx.doi.org/10.1038/s41467-024-55417-1 | DOI Listing |
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