A wearable thin-film hydrogel laser for functional sensing on skin
Flexible photonics offers the possibility of realizing wearable sensors by bridging the advantages of flexible materials and photonic sensing elements. Recently, optical resonators have emerged as a tool to improve their oversensitivity by integrating with flexible photonic sensors. However, direct...
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sg-ntu-dr.10356-1792672024-07-24T01:31:25Z A wearable thin-film hydrogel laser for functional sensing on skin Nie, Ningyuan Gong, Xuerui Gong, Chaoyang Qiao, Zhen Wang, Ziyihui Fang, Guocheng Chen, Yu-Cheng School of Electrical and Electronic Engineering Engineering Wearable sensors Flexible photonics Flexible photonics offers the possibility of realizing wearable sensors by bridging the advantages of flexible materials and photonic sensing elements. Recently, optical resonators have emerged as a tool to improve their oversensitivity by integrating with flexible photonic sensors. However, direct monitoring of multiple psychological information on human skin remains challenging due to the subtle biological signals and complex tissue interface. To tackle the current challenges, here, we developed a functional thin film laser formed by encapsulating liquid crystal droplet lasers in a flexible hydrogel for monitoring metabolites in human sweat (lactate, glucose, and urea). The three-dimensional cross-linked hydrophilic polymer serves as the adhesive layer to allow small molecules to penetrate from human tissue to generate strong light--matter interactions on the interface of whispering gallery modes resonators. Both the hydrogel and cholesteric liquid crystal microdroplets were modified specifically to achieve high sensitivity and selectivity. As a proof of concept, wavelength-multiplexed sensing and a prototype were demonstrated on human skin to detect human metabolites from perspiration. These results present a significant advance in the fabrication and potential guidance for wearable and functional microlasers in healthcare. Agency for Science, Technology and Research (A*STAR) Nanyang Technological University This research is supported by A*STAR under its MTC IRG Grant (Project No. M21K2c0106). We would like to thank the lab support from Centre of Bio-Devices and Bioinformatics and Internal Grant from NTU. 2024-07-24T01:31:25Z 2024-07-24T01:31:25Z 2024 Journal Article Nie, N., Gong, X., Gong, C., Qiao, Z., Wang, Z., Fang, G. & Chen, Y. (2024). A wearable thin-film hydrogel laser for functional sensing on skin. Analytical Chemistry, 96(22), 9159-9166. https://dx.doi.org/10.1021/acs.analchem.4c00979 0003-2700 https://hdl.handle.net/10356/179267 10.1021/acs.analchem.4c00979 38726669 2-s2.0-85192798473 22 96 9159 9166 en M21K2c0106 Analytical Chemistry © 2024 American Chemical Society. All rights reserved. |
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Engineering Wearable sensors Flexible photonics Nie, Ningyuan Gong, Xuerui Gong, Chaoyang Qiao, Zhen Wang, Ziyihui Fang, Guocheng Chen, Yu-Cheng A wearable thin-film hydrogel laser for functional sensing on skin |
| description |
Flexible photonics offers the possibility of realizing wearable sensors by bridging the advantages of flexible materials and photonic sensing elements. Recently, optical resonators have emerged as a tool to improve their oversensitivity by integrating with flexible photonic sensors. However, direct monitoring of multiple psychological information on human skin remains challenging due to the subtle biological signals and complex tissue interface. To tackle the current challenges, here, we developed a functional thin film laser formed by encapsulating liquid crystal droplet lasers in a flexible hydrogel for monitoring metabolites in human sweat (lactate, glucose, and urea). The three-dimensional cross-linked hydrophilic polymer serves as the adhesive layer to allow small molecules to penetrate from human tissue to generate strong light--matter interactions on the interface of whispering gallery modes resonators. Both the hydrogel and cholesteric liquid crystal microdroplets were modified specifically to achieve high sensitivity and selectivity. As a proof of concept, wavelength-multiplexed sensing and a prototype were demonstrated on human skin to detect human metabolites from perspiration. These results present a significant advance in the fabrication and potential guidance for wearable and functional microlasers in healthcare. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Nie, Ningyuan Gong, Xuerui Gong, Chaoyang Qiao, Zhen Wang, Ziyihui Fang, Guocheng Chen, Yu-Cheng |
| format |
Article |
| author |
Nie, Ningyuan Gong, Xuerui Gong, Chaoyang Qiao, Zhen Wang, Ziyihui Fang, Guocheng Chen, Yu-Cheng |
| author_sort |
Nie, Ningyuan |
| title |
A wearable thin-film hydrogel laser for functional sensing on skin |
| title_short |
A wearable thin-film hydrogel laser for functional sensing on skin |
| title_full |
A wearable thin-film hydrogel laser for functional sensing on skin |
| title_fullStr |
A wearable thin-film hydrogel laser for functional sensing on skin |
| title_full_unstemmed |
A wearable thin-film hydrogel laser for functional sensing on skin |
| title_sort |
wearable thin-film hydrogel laser for functional sensing on skin |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/179267 |
| _version_ |
1814047417891291136 |