From smartwatches to fitness trackers, wearable devices are becoming part of everyday life. Hence, their sensors must remain reliable as they bend and stretch with the body. Many conductive hydrogels-soft, water-rich materials well suited for skin-contact sensors—face a "toughnes-conductivity" trade-off: they may stretch easily but lose electrical signal stability, or conduct well but lack the mechanical durability needed for repeated use.

In a study published in the KeAi journal Wearable Electronics, researchers from China developed hydrogels with a robust branched architecture (RBA) by introducing a highly branched polymer into a PEDOT:PSS-based hydrogel system. This created a denser web of molecular connections, allowing the materials to stay intact under strain while preserving pathways for electrical signals.

"Wearable sensors must move with the body while keeping signals stable," says corresponding author Baoyang Lu, a professor at Jiangxi Science & Technology Normal University. "By building a denser branched network, we made the hydrogels more resistant to deformation while preserving pathways for electrical signals."

The RBA hydrogels can stretch to more than three times their original length while remaining mechanically stable. The hydrogels were sandwiched between protective layers to reduce water loss and maintain stable electrical responses during repeated use. When used as strain sensors, the resulting devices detected subtle facial movements such as smiling, as well as larger motions of the fingers, elbows and knees. They also distinguished walking, jogging and running in real time.

Beyond motion tracking, the sensors were also used in a non-verbal communication system. When attached to a finger, they converted movements into Morse-code-like electrical patterns. With a lightweight machine-learning model, the system recognized commands such as "YES," "NO," "HELP" and "SOS" with 96.26% accuracy.

"This approach could support future wearable systems for health monitoring, rehabilitation and human–machine interaction, especially when speech or movement is limited," Lu adds. "Our study offers a simple route to tougher, more reliable hydrogel sensors."

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References

DOI

10.1016/j.wees.2026.03.002

Original Source URL

https://doi.org/10.1016/j.wees.2026.03.002

Funding information

National Natural Science Foundation of China (22565016, 52473179); State Key Lab of Mechanical System and Vibration (MSV202013); Jiangxi Provincial Key Lab of Flexible Electronics (20242BCC32010); Jiangxi Provincial Talent Project (20244BCE52249); Doctoral Start-up Fund of JXSTNU (2024BSQD14); Graduate Innovation Fund of JXSTNU (YC2025-X02).

About Wearable Electronics

Wearable Electronics is a peer-reviewed open access journal covering all aspects of wearable electronics. The journal invites the submission of research papers, reviews, and rapid communications, aiming to present innovative directions for further research and technological advancements in this significant field. It encompasses both applied and fundamental aspects, including wearable electronic materials, wearable electronic devices, and manufacturing technologies of such devices. By incorporating the expertise of scientists, engineers, and industry professionals, the journal strives to address the pivotal challenges that shape the field of wearable science and its core technologies.