Muscle Fatigue Sensor Based on Ti3C2Tx MXene Hydrogel

MXene‐based hydrogels have received significant attention due to several promising properties that distinguish them from conventional hydrogels. In this study, it is shown that both strain and pH level can be exploited to tune the electronic and ionic transport in MXene‐based hydrogel (M‐hydrogel),...

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Published in:Small methods 2021-12, Vol.5 (12), p.n/a
Main Authors: Lee, Kang Hyuck, Zhang, Yi‐Zhou, Kim, Hyunho, Lei, Yongjiu, Hong, Seunghyun, Wustoni, Shofarul, Hama, Adel, Inal, Sahika, Alshareef, Husam N.
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Language:English
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muscle fatigue sensors
MXene hydrogel
wearable sensors
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creator Lee, Kang Hyuck
Zhang, Yi‐Zhou
Kim, Hyunho
Lei, Yongjiu
Hong, Seunghyun
Wustoni, Shofarul
Hama, Adel
Inal, Sahika
Alshareef, Husam N.
description MXene‐based hydrogels have received significant attention due to several promising properties that distinguish them from conventional hydrogels. In this study, it is shown that both strain and pH level can be exploited to tune the electronic and ionic transport in MXene‐based hydrogel (M‐hydrogel), which consists of MXene (Ti3C2Tx)‐polyacrylic acid/polyvinyl alcohol hydrogel. In particular, the strain applied to the M‐hydrogel changes MXene sheet orientation which leads to modulation of ionic transport within the M‐hydrogel, due to strain‐induced orientation of the surface charge‐guided ionic pathway. Simultaneously, the reorientation of MXene sheets under the axial strain increases the electronic resistance of the M‐hydrogel due to the loss of the percolative network of conductive MXene sheets during the stretching process. The iontronic characteristics of the M‐hydrogel can thus be tuned by strain and pH, which allows using the M‐hydrogel as a muscle fatigue sensor during exercise. A fully functional M‐hydrogel is developed for real‐time measurement of muscle fatigue during exercise and coupled it to a smartphone to provide a portable or wearable digital readout. This concept can be extended to other fields that require accurate analysis of constantly changing physical and chemical conditions, such as physiological changes in the human body. An MXene‐based hydrogel sensor has been developed with strain and pH‐dependent electromechanical properties. These features are exploited to develop a wearable muscle fatigue sensor that can be used during exercise. The physical fatigue of the muscle produces strains and pH changes that are readily detected by the sensor.
doi_str_mv 10.1002/smtd.202100819
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subjects muscle fatigue sensors
MXene hydrogel
wearable sensors
title Muscle Fatigue Sensor Based on Ti3C2Tx MXene Hydrogel
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