POLYMERS AND POLYMER MATRIX COMPOSITES |
|
|
|
|
|
A Short Review on Bio-signals Acquisition and Feedback via Soft and Stretchable Conductive Materials |
SUN Jing1,2,, LI Hanfei1,2,, GUO Peizhi1, LI Guanglin2, LIU Zhiyuan2
|
1 School of Materials Science and Engineering, Qingdao University, Qingdao 266071, China 2 Soft Bio-interface Electronics Lab, Shenzhen Institute of Advanced Technology, Chinese Academy of Sciences, Shenzhen 518055, China |
|
|
Abstract Bio-interface flexible conductive materials is a new and basic component of electronic circuit for bio-interface physiological signal collection and feedback. Due to the intrinsic softness of human tissues, the integrated electronic circuits need to be flexible and deformable to achieve the most basic mechanical matching. When the circuit becomes soft, it is more likely to deform under the same force. How to realize the conductivity of the conductive film under large deformation is particularly important. This review not only briefly introduces the commonly used elastomers in the preparation of flexible stretchable conductive materials, including chemical cross-linked elastomers, physical cross-linked elastomers, but also introduces several conductive materials such as carbon-based conductive materials, metals, conductive polymers, etc. This paper summarizes and analyzes several methods to realize the stretchable conductive film and its application in the body surface attachment and in-vivo implantation, analyzes and evaluates the existing methods and introduces the possible development direction in the future.
|
Published: 12 March 2021
|
|
Fund:National Natural Science Foundation of China under grants (#U1613222, 81960419, 81760416), Guangdong-Hong Kong-Macao Joint Laboratory of Human-Machine Intelligence-Synergy Systems(#2019B121205007). |
About author:: Jing Sun received her B.E. degree in applied chemistry from Qingdao University in June 2016. She is currently pursuing her master degree at the School of Materials Science and Engineering, Qingdao University under the supervision of Prof. Peizhi Guo. She started the joint training program at Shenzhen Institute of Advanced Technology (SIAT) supervised by Dr. Zhiyuan Liu in August 2019. Her research interest focuses on flexible sensors. Hanfei Li, graduated from Qingdao University in 2018, is now a postgraduate student in School of Materials Science and Engineering of Qingdao University, and a guest postgraduate in Shenzhen Institute of Advanced Technology, Chinese Academy of Sciences. He is focusing on bio-interface stretchable electrodes. Peizhi Guo received his Ph.D. degree from Institute of Chemistry, Chinese Academy of Sciences in 2006. He is currently a full professor in Qingdao University. His main research fields are functional materials and electrochemistry. Guanglin Li, professor, director of Institute of Integration, director of Neuroengineering Center, senior expert of Rehabilitation and Biomedical Engineering, Shenzhen Institute of High Technology, Chinese Academy of Sciences. Director of the Key Laboratory of human-computer intelligent collaborative system, Chinese Academy of Sciences, high-level (national level) leading talent in Shenzhen, and expert enjoying special subsidies of the State Counci. Zhiyuan Liu is currently a professor in Shenzhen Institutes of Advanced Technology, Chinese Academy of Sciences, China. He received his B.S. from Harbin Institute of Technology and was award his Ph.D. in Materials Science and Engineering (MSE) in 2017 from Nanyang Technological University (NTU), Singapore. During that time, he worked with Prof. Xiaodong Chen in Singapore and Prof. Zhenan Bao in Stanford University. His research interests are soft and stretchable bio-interface sensors. He has published more than 30 high profiled papers in Advanced Materials, Journal of the American Chemical Society, ACS Applied Materials & Interfaces, and so on. These authors contributed equally to this work. |
|
|
1 Cui Y, Wei Q Q, Park H K, et al. Science,2001,293(5533),1289. 2 Hua Q L, Sun J L, Liu H T, et al. Nature Communications,2018,9,244. 3 Khan S, Dang W T, Lorenzelli L, et al. IEEE Transactions on Semiconductor Manufacturing,2015,28(4),486. 4 Lipomi D J, Vosgueritchian M, Tee B C K, et al. Nature Nanotechnology,2011,6(12),788. 5 Mannsfeld S C B, Tee B C K, Stoltenberg R M, et al. Nature Materials,2010,9(10),859. 6 Schwartz G, Tee B C K, Mei J G, et al. Nature Communications,2013,4,1859. 7 Li M, Li H, Zhong W, et al. ACS Applied Materials & Interfaces,2014,6(2),1313. 8 Li X, Zhang R J, Yu W J, et al. Scientific Reports,2012,2,6. 9 Yamada T, Hayamizu Y, Yamamoto Y, et al. Nature Nanotechnology,2011,6(5),296. 10 Zhao X L, Hua Q L, Yu R M, et al. Advanced Electronic Materials,2015,1,7. 11 Chun K Y, Oh Y, Rho J, et al. Nature Nanotechnology,2010,5(12),853. 12 Zhang Y H, Xu S, Fu H R, et al. Soft Matter,2013,9(33),8062. 13 Ho M D, Liu Y Y, Dong D S, et al. Nano Letters,2018,18(6),3593. 14 Xu S, Zhang Y H, Cho J, et al. Nature Communications,2013,4,1543. 15 Kim T, Canlier A, Kim G H, et al. ACS Applied Materials & Interfaces,2013,5(3),788. 16 Park J H, Han S, Kim D, et al. Advanced Functional Materials,2017,27(29),11. 17 Wang X L, Hu H, Shen Y D, et al. Advanced Materials,2011,23(27),3090. 18 Wang Y, Gong S, Wang S J, et al. ACS Nano,2018,12(10),9742. 19 Jung S, Hong S, Kim J, et al. Scientific Reports,2015,5,17081. 20 Lim S, Son D, Kim J, et al. Advanced Functional Materials,2015,25(3),375. 21 Kim D C, Shim H J, Lee W, et al. Advanced Materials,2019,1902743. 22 Choi S, Han S I, Kim D, et al. Chemical Society Reviews,2019,48,1566. 23 Harito C, Bavykin D V, Yuliarto B, et al. Nanoscale,2019,11,4653. 24 Lope M A, Valentin J L, Carretero J, et al. European Polymer Journal,2007,43,4143. 25 Wang Y, Qiu Y, Ameri S K, et al. Npj Flexible Electronics,2018,2,1. 26 Choi S, Park J, Hyun W, et al. ACS Nano,2015,9,6626. 27 Liang J, Li L, Niu X, et al. Nature Photonics,2013,7,817. 28 Liang J, Li L, Tong K, et al. ACS Nano,2014,8,1590. 29 Islam M R, Beg M D H, Jamari S S. Journal of Applied Polymer Science,2014,131(18),40787. 30 Delebecq E, Pascault J P, Boutevin B, et al. Chemical Reviews,2012,113,80. 31 Kang J, Tok J B H, Bao Z. Nature Electronics,2019,2,144. 32 Kang J, Son D, Vardoulis O, et al. Advanced Materials Technology,2019,4,1800417. 33 Patrick J F, Robb M J, Sottos N R, et al. Nature,2016,540,363. 34 Kim S H, Seo H, Kang J, et al. ACS Nano,2019,13,6531. 35 Kang J, Son D, Wang G J N, et al. Advanced Materials,2018,30,1706846. 36 Wu W. Science and Technology of Advanced Materials,2019,20,187. 37 Song J, Jiang H, Liu Z J, et al. International Journal Of Solids And Structures,2008,45,3107. 38 Khang D Y, Rogers J A, Lee H H. Advanced Functional Materials,2009,19,1526. 39 Rogers J A, Someya T, Huang Y. Science,2010,327,1603. 40 Qi Y, Kim J, Nguyen T D, et al. Nano Letters,2011,11,1331. 41 Kim K K, Hong S, Cho H M, et al. Nano Letters,2015,15,5240. 42 Dickey M D, Chiechi R C, Larsen R J, et al. Advanced Functional Materials,2008,18,1097. 43 Dickey M D. Advanced Materials,2017,29,1606425. 44 Wu W. Nanoscale,2017,9,7342. 45 Wei Y, Xinzhou W, Weibing G, et al. Journal of Semiconductor Techno-logy and Science,2018,39,015002. 46 Niu X Z, Peng S L, Liu L Y, et al. Advanced Materials,2007,19,2682. 47 Domenech S C, Bendo L, Mattos D J S, et al. Polymers & Polymer Composites,2009,30,897. 48 Boland C S, Khan U, Ryan G, et al. Science,2016,354,1257. 49 Chen Z, Ren W, Gao L, et al. Nature Materials,2011,10,424. 50 Shin M K, Oh J, Lima M, et al. Advanced Materials,2010,22,2663. 51 Lu T, Finkenauer L, Wissman J, et al. Advanced Functional Materials,2014,24,3351. 52 Stoyanov H, Kollosche M, Risse S, et al. Advanced Materials,2013,25,578. 53 Ding H, Zhong M, Wu H, et al. ACS Nano,2016,10,5991. 54 Hur J, Im K, Kim S W, et al. ACS Nano,2014,8,10066. 55 Norton J J S, Lee D S, Lee J W, et al. Proceedings of the National Academy of Sciences of the United States of America,2015,112(13),3920. 56 Xu L, Gutbrod S R, Bonifas A P, et al. Nature Communications,2014,5,3329. 57 Choi S, Han S I, Jung D, et al. Nature Nanotechnology,2018,13(11),1048. 58 Kim D H, Ghaffari R, Lu N, et al. Proceedings of the National Academy of Sciences of the United States of America,2012,109(49),19910. 59 Kim D H, Lu N, Ghaffari R, et al. Nature Materials,2011,10(4),316. 60 Minev I R, Musienko P, Hirsch A, et al. Science,2015,347(6218),159. 61 Khodagholy D, Gelinas J N, Thesen T, et al. Nature Neuroscience,2015,18(2),310. 62 Viventi J, Kim D H, Vigeland L, et al. Nature Neuroscience,2011,14(12),1599. 63 Xie C, Liu J, Fu T M, et al. Nature Materials,2015,14(12),1286. 64 Song E, Chiang C-H, Li R, et al. Proceedings of the National Academy of Sciences of the United States of America,2019,116(31),15398. 65 Rubehn B, Bosman C, Oostenveld R, et al. Journal of Neural Enginee-ring,2009,6(3),036003. 66 Kim S J, Cho K W, Cho H R, et al. Advanced Functional Materials,2016,26(19),3207. 67 Ware T, Simon D, Hearon K, et al. Macromolecular Materials and Engineering,2012,297(12),1193. 68 Zhang Y, Mickle A D, Gutruf P, et al. Science of Advanced Materials,2019,5(7),3108. 69 Qusba A, RamRakhyani A K, So J H, et al. IEEE Sensors Journal,2014,14(4),1074. 70 Shi L, Zhu T, Gao G, et al. Nature Communications,2018,9(1),2630. 71 Pu X, Liu M, Chen X, et al. Science Advances,2017,3,5. 72 Matsuzaki R,Tabayashi K. Advanced Functional Materials,2015,25(25),3806. 73 Lee J H, Jeong Y R, Lee G, et al. ACS Applied Materials & Interfaces,2018,10(33),28027. |
|
|
|