Mechanical tolerance of cascade bioreactions via adaptive curvature engineering for epidermal bioelectronics
Epidermal bioelectronics that can monitor human health status noninvasively and in real time are core to wearable healthcare equipment. Achieving mechanically tolerant surface bioreactions that convert biochemical information to detectable signals is crucial for obtaining high sensing fidelity. In t...
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sg-ntu-dr.10356-1471242023-07-14T16:00:15Z Mechanical tolerance of cascade bioreactions via adaptive curvature engineering for epidermal bioelectronics Wang, Ting Lei, Qun-Li Wang, Ming Deng, Guoying Yang, Le Liu, Xijian Li, Chunlin Wang, Qi Liu, Zhihua Wang, Jianwu Cui, Zequn Kevin Goldio Utama Ni, Ran Chen, Xiaodong School of Materials Science and Engineering School of Chemical and Biomedical Engineering Institute of Material Research and Engineering, A*STAR Innovative Centre for Flexible Devices Science::Chemistry::Analytical chemistry Cascade Reaction Epidermal Biosensors Epidermal bioelectronics that can monitor human health status noninvasively and in real time are core to wearable healthcare equipment. Achieving mechanically tolerant surface bioreactions that convert biochemical information to detectable signals is crucial for obtaining high sensing fidelity. In this work, by combining simulations and experiments, a typical epidermal biosensor system is investigated based on a redox enzyme cascade reaction (RECR) comprising glucose oxidase/lactate oxidase enzymes and Prussian blue nanoparticles. Simulations reveal that strain-induced change in surface reactant flux is the key to the performance drop in traditional flat bioelectrodes. In contrast, wavy bioelectrodes capable of curvature adaptation maintain the reactant flux under strain, which preserves sensing fidelity. This rationale is experimentally proven by bioelectrodes with flat/wavy geometry under both static strain and dynamic stretching. When exposed to 50% strain, the signal fluctuations for wavy bioelectrodes are only 7.0% (4.9%) in detecting glucose (lactate), which are significantly lower than the 40.3% (51.8%) in flat bioelectrodes. Based on this wavy bioelectrode, a stable human epidermal metabolite biosensor insensitive to human gestures is further demonstrated. This mechanically tolerant biosensor based on adaptive curvature engineering provides a reliable bio/chemical-information monitoring platform for soft healthcare bioelectronics. Agency for Science, Technology and Research (A*STAR) Ministry of Education (MOE) National Research Foundation (NRF) The authors thank the financial support from the Agency for Science, Technology and Research (A*STAR) under its AME Programmatic Funding Scheme (Project #A18A1b0045) Cyber-Physiochemical Interfaces (CPI) Programme, the National Research Foundation (NRF), Prime Minister’s office, Singapore under its NRF Investigatorship (NRF-NRFI2017-07), Singapore Ministry of Education (MOE2017-T2-2-107), the Singapore Ministry of Education through the Academic Tier 1 Research Fund (M4011873.120), the Nanyang Technological University Start-Up Grant (NTU-SUG: M4081781.120), and the A*STAR Advanced Manufacturing and Engineering Young Individual Research Grant (A1784C0018). 2021-03-23T09:17:01Z 2021-03-23T09:17:01Z 2020 Journal Article Wang, T., Lei, Q., Wang, M., Deng, G., Yang, L., Liu, X., Li, C., Wang, Q., Liu, Z., Wang, J., Cui, Z., Kevin Goldio Utama, Ni, R. & Chen, X. (2020). Mechanical tolerance of cascade bioreactions via adaptive curvature engineering for epidermal bioelectronics. Advanced Materials, 32(22), 2000991-. https://dx.doi.org/10.1002/adma.202000991 1521-4095 https://hdl.handle.net/10356/147124 10.1002/adma.202000991 22 32 2000991 en Advanced Materials This is the peer reviewed version of the following article: Wang, T., Lei, Q., Wang, M., Deng, G., Yang, L., Liu, X., Li, C., Wang, Q., Liu, Z., Wang, J., Cui, Z., Kevin Goldio Utama, Ni, R. & Chen, X. (2020). Mechanical tolerance of cascade bioreactions via adaptive curvature engineering for epidermal bioelectronics. Advanced Materials, 32(22), 2000991-. https://dx.doi.org/10.1002/adma.202000991, which has been published in final form at https://doi.org/10.1002/adma.202000991. This article may be used for non-commercial purposes in accordance with Wiley Terms and Conditions for Use of Self-Archived Versions. application/pdf |
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Science::Chemistry::Analytical chemistry Cascade Reaction Epidermal Biosensors Wang, Ting Lei, Qun-Li Wang, Ming Deng, Guoying Yang, Le Liu, Xijian Li, Chunlin Wang, Qi Liu, Zhihua Wang, Jianwu Cui, Zequn Kevin Goldio Utama Ni, Ran Chen, Xiaodong Mechanical tolerance of cascade bioreactions via adaptive curvature engineering for epidermal bioelectronics |
| description |
Epidermal bioelectronics that can monitor human health status noninvasively and in real time are core to wearable healthcare equipment. Achieving mechanically tolerant surface bioreactions that convert biochemical information to detectable signals is crucial for obtaining high sensing fidelity. In this work, by combining simulations and experiments, a typical epidermal biosensor system is investigated based on a redox enzyme cascade reaction (RECR) comprising glucose oxidase/lactate oxidase enzymes and Prussian blue nanoparticles. Simulations reveal that strain-induced change in surface reactant flux is the key to the performance drop in traditional flat bioelectrodes. In contrast, wavy bioelectrodes capable of curvature adaptation maintain the reactant flux under strain, which preserves sensing fidelity. This rationale is experimentally proven by bioelectrodes with flat/wavy geometry under both static strain and dynamic stretching. When exposed to 50% strain, the signal fluctuations for wavy bioelectrodes are only 7.0% (4.9%) in detecting glucose (lactate), which are significantly lower than the 40.3% (51.8%) in flat bioelectrodes. Based on this wavy bioelectrode, a stable human epidermal metabolite biosensor insensitive to human gestures is further demonstrated. This mechanically tolerant biosensor based on adaptive curvature engineering provides a reliable bio/chemical-information monitoring platform for soft healthcare bioelectronics. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Wang, Ting Lei, Qun-Li Wang, Ming Deng, Guoying Yang, Le Liu, Xijian Li, Chunlin Wang, Qi Liu, Zhihua Wang, Jianwu Cui, Zequn Kevin Goldio Utama Ni, Ran Chen, Xiaodong |
| format |
Article |
| author |
Wang, Ting Lei, Qun-Li Wang, Ming Deng, Guoying Yang, Le Liu, Xijian Li, Chunlin Wang, Qi Liu, Zhihua Wang, Jianwu Cui, Zequn Kevin Goldio Utama Ni, Ran Chen, Xiaodong |
| author_sort |
Wang, Ting |
| title |
Mechanical tolerance of cascade bioreactions via adaptive curvature engineering for epidermal bioelectronics |
| title_short |
Mechanical tolerance of cascade bioreactions via adaptive curvature engineering for epidermal bioelectronics |
| title_full |
Mechanical tolerance of cascade bioreactions via adaptive curvature engineering for epidermal bioelectronics |
| title_fullStr |
Mechanical tolerance of cascade bioreactions via adaptive curvature engineering for epidermal bioelectronics |
| title_full_unstemmed |
Mechanical tolerance of cascade bioreactions via adaptive curvature engineering for epidermal bioelectronics |
| title_sort |
mechanical tolerance of cascade bioreactions via adaptive curvature engineering for epidermal bioelectronics |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/147124 |
| _version_ |
1773551218230034432 |