Page 96 - Read Online

P. 96

Zhao et al. Soft Sci 2024;4:18 https://dx.doi.org/10.20517/ss.2024.04 Page 31 of 32

130. Yang Y, Su Y, Zhu X, Ye D, Chen R, Liao Q. Flexible enzymatic biofuel cell based on 1, 4-naphthoquinone/MWCNT-Modified bio-
anode and polyvinyl alcohol hydrogel electrolyte. Biosens Bioelectron 2022;198:113833. DOI
131. Escalona-villalpando R, Ortiz-ortega E, Bocanegra-ugalde J, Minteer SD, Ledesma-garcía J, Arriaga L. Clean energy from human
sweat using an enzymatic patch. J Power Sources 2019;412:496-504. DOI
132. Escalona-villalpando RA, Reid RC, Milton RD, Arriaga L, Minteer SD, Ledesma-garcía J. Improving the performance of lactate/
oxygen biofuel cells using a microfluidic design. J Power Sources 2017;342:546-52. DOI
133. Hickey DP, Reid RC, Milton RD, Minteer SD. A self-powered amperometric lactate biosensor based on lactate oxidase immobilized
in dimethylferrocene-modified LPEI. Biosens Bioelectron 2016;77:26-31. DOI PubMed
134. Han XF, Batool N, Wang WT, et al. Templated-assisted synthesis of structurally ordered intermetallic Pt Co with ultralow loading
3
supported on 3D porous carbon for oxygen reduction reaction. ACS Appl Mater Interfaces 2021;13:37133-41. DOI PubMed
135. Zhang W, Zhang J, Fan S, Zhang L, Liu C, Liu J. Oxygen reduction catalyzed by bilirubin oxidase and applications in biosensors and
biofuel cells. Microchem J 2022;183:108052. DOI
136. Macedo LJ, Santo AA, Sedenho GC, et al. Three-dimensional catalysis and the efficient bioelectrocatalysis beyond surface chemistry.
J Catal 2021;401:200-5. DOI
137. Wang J, Sun M, Pei X, et al. Flexible biofuel cell-in-A-tube (iezTube): an entirely self-contained biofuel cell for wearable green bio-
energy harvesting. Adv Funct Mater 2022;32:2209697. DOI
138. Yin S, Jin Z, Miyake T. Wearable high-powered biofuel cells using enzyme/carbon nanotube composite fibers on textile cloth.
Biosens Bioelectron 2019;141:111471. DOI PubMed
139. Sun M, Gu Y, Pei X, et al. A flexible and wearable epidermal ethanol biofuel cell for on-body and real-time bioenergy harvesting
from human sweat. Nano Energy 2021;86:106061. DOI
140. Su Y, Lu L, Zhou M. Wearable microbial fuel cells for sustainable self-powered electronic skins. ACS Appl Mater Interfaces
2022;14:8664-8. DOI PubMed
141. Mohammadifar M, Tahernia M, Yang JH, Koh A, Choi S. Biopower-on-skin: electricity generation from sweat-eating bacteria for
self-powered e-skins. Nano Energy 2020;75:104994. DOI
142. Bae CW, Chinnamani MV, Lee EH, Lee N. Stretchable non-enzymatic fuel cell-based sensor patch integrated with thread-embedded
microfluidics for self-powered wearable glucose monitoring. Adv Mater Inter 2022;9:2200492. DOI
143. Eswaran M, Rahimi S, Pandit S, Chokkiah B, Mijakovic I. A flexible multifunctional electrode based on conducting PANI/Pd
composite for non-enzymatic glucose sensor and direct alcohol fuel cell applications. Fuel 2023;345:128182. DOI
144. Wang C, Shim E, Chang HK, Lee N, Kim HR, Park J. Sustainable and high-power wearable glucose biofuel cell using long-term and
high-speed flow in sportswear fabrics. Biosens Bioelectron 2020;169:112652. DOI PubMed
145. Ortega L, Llorella A, Esquivel JP, Sabaté N. Self-powered smart patch for sweat conductivity monitoring. Microsyst Nanoeng
2019;5:3. DOI PubMed PMC
146. Ju J, Xiao G, Jian Y, et al. Scalable, high-performance, yarn-shaped batteries activated by an ultralow volume of sweat for self-
powered sensing textiles. Nano Energy 2023;109:108304. DOI
147. Liu Y, Huang X, Zhou J, et al. Stretchable sweat-activated battery in skin-integrated electronics for continuous wireless sweat
monitoring. Adv Sci 2022;9:e2104635. DOI PubMed PMC
148. Liu Y, Huang X, Zhou J, et al. Bandage based energy generators activated by sweat in wireless skin electronics for continuous
physiological monitoring. Nano Energy 2022;92:106755. DOI
149. Wu M, Shi R, Zhou J, et al. Bio-inspired ultra-thin microfluidics for soft sweat-activated batteries and skin electronics. J Mater Chem
A 2022;10:19662-70. DOI
150. Zhao G, Park W, Huang X, et al. Soft, sweat-powered health status sensing and visualization system enabled by laser-fabrication. Adv
Sensor Res 2023;2:2300070. DOI
151. Xiao G, Ju J, Lu H, et al. A weavable and scalable cotton-yarn-based battery activated by human sweat for textile electronics. Adv Sci
2022;9:2103822. DOI
152. Lv J, Thangavel G, Li Y, et al. Printable elastomeric electrodes with sweat-enhanced conductivity for wearables. Sci Adv
2021;7:eabg8433. DOI PubMed PMC
153. Luo Z, Wang Y, Kou B, Liu C, Zhang W, Chen L. “Sweat-chargeable” on-skin supercapacitors for practical wearable energy
applications. Energy Storage Mater 2021;38:9-16. DOI
154. Manjakkal L, Pullanchiyodan A, Yogeswaran N, Hosseini ES, Dahiya R. A wearable supercapacitor based on conductive
PEDOT:PSS-coated cloth and a sweat electrolyte. Adv Mater 2020;32:1907254. DOI
155. Dauzon E, Sallenave X, Plesse C, Goubard F, Amassian A, Anthopoulos TD. Pushing the limits of flexibility and stretchability of
solar cells: a review. Adv Mater 2021;33:2101469. DOI
156. Garland NT, Kaveti R, Bandodkar AJ. Biofluid-activated biofuel cells, batteries, and supercapacitors: a comprehensive review. Adv
Mater 2023;35:2303197. DOI PubMed
157. Yin L, Kim KN, Lv J, et al. A self-sustainable wearable multi-modular E-textile bioenergy microgrid system. Nat Commun
2021;12:1542. DOI PubMed PMC

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