Page 122 - Read Online

P. 122

Xi et al. Soft Sci 2023;3:26 https://dx.doi.org/10.20517/ss.2023.13 Page 31 of 34

133. He X, Hao Y, He M, Qin X, Wang L, Yu J. Stretchable thermoelectric-based self-powered dual-parameter sensors with decoupled
temperature and strain sensing. ACS Appl Mater Interfaces 2021;13:60498-507. DOI
134. Lee S, Park J. Fingerprint-inspired triboelectric nanogenerator with a geometrically asymmetric electrode design for a self-powered
dynamic pressure sensor. Nano Energy 2022;101:107546. DOI
135. Li G, Li L, Zhang P, Chang C, Xu F, Pu X. Ultra-stretchable and healable hydrogel-based triboelectric nanogenerators for energy
harvesting and self-powered sensing. RSC Adv 2021;11:17437-44. DOI PubMed PMC
136. Bai C, Wang Z, Yang S, et al. Wearable electronics based on the gel thermogalvanic electrolyte for self-powered human health
monitoring. ACS Appl Mater Interfaces 2021;13:37316-22. DOI PubMed
137. Huang J, Gu J, Liu J, et al. Environment stable ionic organohydrogel as a self-powered integrated system for wearable electronics. J
Mater Chem A 2021;9:16345-58. DOI
138. He X, Zhang X, Zhang H, et al. Facile fabrication of stretchable and multifunctional thermoelectric composite fabrics with strain-
enhanced self-powered sensing performance. Compos Commun 2022;35:101275. DOI
139. Zhang X, Ai J, Zou R, Su B. Compressible and stretchable magnetoelectric sensors based on liquid metals for highly sensitive, self-
powered respiratory monitoring. ACS Appl Mater Interfaces 2021;13:15727-37. DOI PubMed
140. Zeng X, Deng HT, Wen DL, Li YY, Xu L, Zhang XS. Wearable multi-functional sensing technology for healthcare smart detection.
Micromachines 2022;13:254. DOI PubMed PMC
141. Shin YE, Park YJ, Ghosh SK, Lee Y, Park J, Ko H. Ultrasensitive multimodal tactile sensors with skin-inspired microstructures
through localized ferroelectric polarization. Adv Sci 2022;9:e2105423. DOI PubMed PMC
142. Jinno H, Yokota T, Koizumi M, et al. Self-powered ultraflexible photonic skin for continuous bio-signal detection via air-operation-
stable polymer light-emitting diodes. Nat Commun 2021;12:2234. DOI PubMed PMC
143. Kim Y, Lee J, Hong H, Park S, Ryu W. Self-powered wearable micropyramid piezoelectric film sensor for real-time monitoring of
blood pressure. Adv Eng Mater 2023;25:2200873. DOI
144. Wang B, Liu C, Xiao Y, et al. Ultrasensitive cellular fluorocarbon piezoelectret pressure sensor for self-powered human physiological
monitoring. Nano Energy 2017;32:42-9. DOI
145. Xu L, Zhang Z, Gao F, et al. Self-powered ultrasensitive pulse sensors for noninvasive multi-indicators cardiovascular monitoring.
Nano Energy 2021;81:105614. DOI
146. Laurila M, Peltokangas M, Montero KL, et al. Self-powered, high sensitivity printed e-tattoo sensor for unobtrusive arterial pulse
wave monitoring. Nano Energy 2022;102:107625. DOI
147. Sahoo S, Walke P, Nayak SK, Rout CS, Late DJ. Recent developments in self-powered smart chemical sensors for wearable
electronics. Nano Res 2021;14:3669-89. DOI
148. Li L, Chen Z, Hao M, et al. Moisture-driven power generation for multifunctional flexible sensing systems. Nano Lett 2019;19:5544-
52. DOI
149. Su Y, Wang J, Wang B, et al. Alveolus-inspired active membrane sensors for self-powered wearable chemical sensing and breath
analysis. ACS Nano 2020;14:6067-75. DOI PubMed
150. Liu Q, Wang XX, Song WZ, et al. Wireless single-electrode self-powered piezoelectric sensor for monitoring. ACS Appl Mater
Interfaces 2020;12:8288-95. DOI PubMed
151. Xue Z, Wu L, Yuan J, Xu G, Wu Y. Self-powered biosensors for monitoring human physiological changes. Biosensors 2023;13:236.
DOI PubMed PMC
152. Wang J, Tang F, Wang Y, Lu Q, Liu S, Li L. Self-healing and highly stretchable gelatin hydrogel for self-powered strain sensor. ACS
Appl Mater Interfaces 2020;12:1558-66. DOI PubMed
153. Li M, Chen J, Zhong W, et al. Large-area, wearable, self-powered pressure-temperature sensor based on 3D thermoelectric spacer
fabric. ACS Sens 2020;5:2545-54. DOI PubMed
154. Xu S, Fan Z, Yang S, et al. Highly flexible, stretchable, and self-powered strain-temperature dual sensor based on free-standing
PEDOT:PSS/carbon nanocoils-poly(vinyl) alcohol films. ACS Sens 2021;6:1120-8. DOI PubMed
155. Kanokpaka P, Chang L, Wang B, et al. Self-powered molecular imprinted polymers-based triboelectric sensor for noninvasive
monitoring lactate levels in human sweat. Nano Energy 2022;100:107464. DOI
156. Shajari S, Salahandish R, Zare A, et al. MicroSweat: a wearable microfluidic patch for noninvasive and reliable sweat collection
enables human stress monitoring. Adv Sci 2023;10:e2204171. DOI
157. Gonzalez-Solino C, Lorenzo MD. Enzymatic fuel cells: towards self-powered implantable and wearable diagnostics. Biosensors
2018;8:11. DOI PubMed PMC
158. Zhao J, Lin Y, Wu J, et al. A fully integrated and self-powered smartwatch for continuous sweat glucose monitoring. ACS Sens
2019;4:1925-33. DOI PubMed
159. Zhang X, Jing Y, Zhai Q, et al. Point-of-care diagnoses: flexible patterning technique for self-powered wearable sensors. Anal Chem
2018;90:11780-4. DOI PubMed
160. Ghoreishizadeh SS, Moschou D, McBay D, Gonalez-Solino C, Dutta G, Di Lorenzo M, Soltan A, Ieee. Towards self-powered and
autonomous wearable glucose sensor. In: 25th IEEE International Conference on Electronics, Circuits and Systems (ICECS).
Bordeaux, France; 2018. p. 701-4. DOI
161. Kil HJ, Kim SR, Park JW. A Self-charging supercapacitor for a patch-type glucose sensor. ACS Appl Mater Interfaces 2022;14:3838-
48. DOI PubMed

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