REFERENCES

1. Serup J, Jemec GBE, Grove GL. Handbook of non-invasive methods and the skin. 2nd edition. CRC Press: Boca Raton. 2006.

2. Liu Y, Pharr M, Salvatore GA. Lab-on-skin: a review of flexible and stretchable electronics for wearable health monitoring. ACS Nano 2017;11:9614-35.

3. Ma Z, Hua H, You C, et al. FlexiPulse: a machine-learning-enabled flexible pulse sensor for cardiovascular disease diagnostics. Cell Rep Phys Sci 2023;4:101690.

4. Guo W, Ma Z, Chen Z, et al. Thin and soft Ti₃C₂Tx MXene sponge structure for highly sensitive pressure sensor assisted by deep learning. Chem Eng J 2024;485:149659.

5. Wang Y, Lee S, Yokota T, et al. A durable nanomesh on-skin strain gauge for natural skin motion monitoring with minimum mechanical constraints. Sci Adv 2020;6:eabb7043.

6. Zhuang M, Yin L, Wang Y, et al. Highly robust and wearable facial expression recognition via deep-learning-assisted, soft epidermal electronics. Research 2021;2021:9759601.

7. Wong TH, Yiu CK, Zhou J, et al. Tattoo-like epidermal electronics as skin sensors for human machine interfaces. Soft Sci 2021;1:10.

8. Zhou Z, Chen K, Li X, et al. Sign-to-speech translation using machine-learning-assisted stretchable sensor arrays. Nat Electron 2020;3:571-8.

9. Fellmann N, Grizard G, Coudert J. Human frontal sweat rate and lactate concentration during heat exposure and exercise. J Appl Physiol Respir Environ Exerc Physiol 1983;54:355-60.

10. Wang B, Zhao C, Wang Z, et al. Wearable aptamer-field-effect transistor sensing system for noninvasive cortisol monitoring. Sci Adv 2022;8:eabk0967.

11. Lin J, Fu R, Zhong X, et al. Wearable sensors and devices for real-time cardiovascular disease monitoring. Cell Rep Phys Sci 2021;2:100541.

12. Chen S, Qi J, Fan S, Qiao Z, Yeo JC, Lim CT. Flexible wearable sensors for cardiovascular health monitoring. Adv Healthc Mater 2021;10:e2100116.

13. Wang C, Sani ES, Gao W. Wearable bioelectronics for chronic wound management. Adv Funct Mater 2022;32:2111022.

14. Ma Y, Zhang Y, Cai S, et al. Flexible hybrid electronics for digital healthcare. Adv Mater 2020;32:e1902062.

15. Gao W, Ota H, Kiriya D, Takei K, Javey A. Flexible electronics toward wearable sensing. Acc Chem Res 2019;52:523-33.

16. Yang JC, Mun J, Kwon SY, Park S, Bao Z, Park S. Electronic skin: recent progress and future prospects for skin-attachable devices for health monitoring, robotics, and prosthetics. Adv Mater 2019;31:e1904765.

17. Yang W, Li N, Zhao S, et al. A breathable and screen-printed pressure sensor based on nanofiber membranes for electronic skins. Adv Mater Technol 2018;3:1700241.

18. Sinha AK, Goh GL, Yeong WY, Cai Y. Ultra-low-cost, crosstalk-free, fast-responding, wide-sensing-range tactile fingertip sensor for smart gloves. Adv Mater Inter 2022;9:2200621.

19. Cho C, Shin W, Kim M, et al. Monolithically programmed stretchable conductor by laser-induced entanglement of liquid metal and metallic nanowire backbone. Small 2022;18:e2202841.

20. Kim J, Won D, Kim TH, Kim CY, Ko SH. Rapid prototyping and facile customization of conductive hydrogel bioelectronics based on all laser process. Biosens Bioelectron 2024;258:116327.

21. You R, Liu YQ, Hao YL, Han DD, Zhang YL, You Z. Laser fabrication of graphene-based flexible electronics. Adv Mater 2020;32:e1901981.

22. Dong Z, He Q, Shen D, et al. Microfabrication of functional polyimide films and microstructures for flexible MEMS applications. Microsyst Nanoeng 2023;9:31.

23. Lin J, Peng Z, Liu Y, et al. Laser-induced porous graphene films from commercial polymers. Nat Commun 2014;5:5714.

24. Burke M, Larrigy C, Vaughan E, et al. Fabrication and electrochemical properties of three-dimensional (3D) porous graphitic and graphenelike electrodes obtained by low-cost direct laser writing methods. ACS Omega 2020;5:1540-8.

25. Ye R, Chyan Y, Zhang J, et al. Laser-induced graphene formation on wood. Adv Mater 2017;29:1702211.

26. Wang M, Yang Y, Gao W. Laser-engraved graphene for flexible and wearable electronics. Trend Chem 2021;3:969-81.

27. Lu Y, Yang G, Wang S, et al. Stretchable graphene–hydrogel interfaces for wearable and implantable bioelectronics. Nat Electron 2024;7:51-65.

28. Yu H, Gai M, Liu L, et al. Laser-induced direct graphene patterning: from formation mechanism to flexible applications. Soft Sci 2023;3:4.

29. Zhang S, Zhu J, Zhang Y, et al. Standalone stretchable RF systems based on asymmetric 3D microstrip antennas with on-body wireless communication and energy harvesting. Nano Energy 2022;96:107069.

30. Luong DX, Yang K, Yoon J, et al. Laser-induced graphene composites as multifunctional surfaces. ACS Nano 2019;13:2579-86.

31. Shi X, Zhou F, Peng J, Wu R, Wu Z, Bao X. One-step scalable fabrication of graphene-integrated micro-supercapacitors with remarkable flexibility and exceptional performance uniformity. Adv Funct Mater 2019;29:1902860.

32. Wang H, Li X, Wang X, Qin Y, Pan Y, Guo X. Somatosensory electro-thermal actuator through the laser-induced graphene technology. Small 2024;20:e2310612.

33. Page MJ, McKenzie JE, Bossuyt PM, et al. The PRISMA 2020 statement: an updated guideline for reporting systematic reviews. Syst Rev 2021;10:89.

34. Dallinger A, Keller K, Fitzek H, Greco F. Stretchable and skin-conformable conductors based on polyurethane/laser-induced graphene. ACS Appl Mater Interfaces 2020;12:19855-65.

35. Gandla S, Naqi M, Lee M, et al. Highly linear and stable flexible temperature sensors based on laser-induced carbonization of polyimide substrates for personal mobile monitoring. Adv Mater Technol 2020;5:2000014.

36. Luong DX, Subramanian AK, Silva GAL, et al. Laminated object manufacturing of 3D-printed laser-induced graphene foams. Adv Mater 2018;30:e1707416.

37. Carvalho AF, Fernandes AJS, Leitão C, et al. Laser-induced graphene strain sensors produced by ultraviolet irradiation of polyimide. Adv Funct Mater 2018;28:1805271.

38. Lan L, Le X, Dong H, Xie J, Ying Y, Ping J. One-step and large-scale fabrication of flexible and wearable humidity sensor based on laser-induced graphene for real-time tracking of plant transpiration at bio-interface. Biosens Bioelectron 2020;165:112360.

39. Yang L, Zheng G, Cao Y, et al. Moisture-resistant, stretchable NO_x gas sensors based on laser-induced graphene for environmental monitoring and breath analysis. Microsyst Nanoeng 2022;8:78.

40. Zhu J, Liu S, Hu Z, et al. Laser-induced graphene non-enzymatic glucose sensors for on-body measurements. Biosens Bioelectron 2021;193:113606.

41. Rahimi R, Ochoa M, Tamayol A, Khalili S, Khademhosseini A, Ziaie B. Highly stretchable potentiometric pH sensor fabricated via laser carbonization and machining of carbon-polyaniline composite. ACS Appl Mater Interfaces 2017;9:9015-23.

42. Yang Y, Song Y, Bo X, et al. A laser-engraved wearable sensor for sensitive detection of uric acid and tyrosine in sweat. Nat Biotechnol 2020;38:217-24.

43. Torrente-Rodríguez RM, Tu J, Yang Y, et al. Investigation of cortisol dynamics in human sweat using a graphene-based wireless mHealth system. Matter 2020;2:921-37.

44. Chen X, Luo F, Yuan M, et al. A dual-functional graphene-based self-alarm health-monitoring e-skin. Adv Funct Mater 2019;29:1904706.

45. Huang Y, Tao LQ, Yu J, Wang Z, Zhu C, Chen X. Integrated sensing and warning multifunctional devices based on the combined mechanical and thermal effect of porous graphene. ACS Appl Mater Interfaces 2020;12:53049-57.

46. Yang Q, Jin W, Zhang Q, et al. Mixed-modality speech recognition and interaction using a wearable artificial throat. Nat Mach Intell 2023;5:169-80.

47. Zhang C, Chen H, Ding X, et al. Human motion-driven self-powered stretchable sensing platform based on laser-induced graphene foams. Appl Phys Rev 2022;9:011413.

48. Aslam S, Sagar RUR, Liu Y, et al. Graphene decorated polymeric flexible materials for lightweight high areal energy lithium-ion batteries. Appl Mater Today 2019;17:123-9.

49. Das PS, Chhetry A, Maharjan P, Rasel MS, Park JY. A laser ablated graphene-based flexible self-powered pressure sensor for human gestures and finger pulse monitoring. Nano Res 2019;12:1789-95.

50. Song W, Zhu J, Gan B, et al. Flexible, stretchable, and transparent planar microsupercapacitors based on 3D porous laser-induced graphene. Small 2018;14:1702249.

51. Le TSD, Phan HP, Kwon S, et al. Recent advances in laser-induced graphene: mechanism, fabrication, properties, and applications in flexible electronics. Adv Funct Mater 2022;32:2205158.

52. Sharma CP, Arnusch CJ. Laser-induced graphene composite adhesive tape with electro-photo-thermal heating and antimicrobial capabilities. Carbon 2022;196:102-9.

53. Yang W, Zhao W, Li Q, et al. Fabrication of smart components by 3D printing and laser-scribing technologies. ACS Appl Mater Interfaces 2020;12:3928-35.

54. Le TD, Park S, An J, Lee PS, Kim Y. Ultrafast laser pulses enable one-step graphene patterning on woods and leaves for green electronics. Adv Funct Mater 2019;29:1902771.

55. Jung Y, Min J, Choi J, et al. Smart paper electronics by laser-induced graphene for biodegradable real-time food spoilage monitoring. Appl Mater Today 2022;29:101589.

56. Chyan Y, Ye R, Li Y, Singh SP, Arnusch CJ, Tour JM. Laser-induced graphene by multiple lasing: toward electronics on cloth, paper, and food. ACS Nano 2018;12:2176-83.

57. Kim D, Lee H, Hwang E, Hong S, Lee H. Pyrolytic jetting of highly porous laser-induced graphene fiber for cost-effective supercapacitor. Int J Precis Eng Man 2024;11:439-47.

58. Chen X, Li R, Niu G, et al. Porous graphene foam composite-based dual-mode sensors for underwater temperature and subtle motion detection. Chem Eng J 2022;444:136631.

59. Yang J, Zhang K, Yu J, et al. Facile fabrication of robust and reusable PDMS supported graphene dry electrodes for wearable electrocardiogram monitoring. Adv Mater Technol 2021;6:2100262.

60. Kaidarova A, Alsharif N, Oliveira BNM, et al. Laser-printed, flexible graphene pressure sensors. Glob Chall 2020;4:2000001.

61. d’Amora M, Lamberti A, Fontana M, Giordani S. Toxicity assessment of laser-induced graphene by zebrafish during development. J Phys Mater 2020;3:034008.

62. Huang L, Xu S, Wang Z, et al. Self-reporting and photothermally enhanced rapid bacterial killing on a laser-induced graphene mask. ACS Nano 2020;14:12045-53.

63. Huang L, Gu M, Wang Z, et al. Highly efficient and rapid inactivation of coronavirus on non-metal hydrophobic laser-induced graphene in mild conditions. Adv Funct Mater 2021;31:2101195.

64. Le TD, Lee YA, Nam HK, et al. Green flexible graphene–inorganic-hybrid micro-supercapacitors made of fallen leaves enabled by ultrafast laser pulses. Adv Funct Mater 2022;32:2107768.

65. Yi J, Chen J, Yang Z, et al. Facile patterning of laser-induced graphene with tailored Li nucleation kinetics for stable lithium-metal batteries. Adv Energy Mater 2019;9:1901796.

66. Stanford MG, Zhang C, Fowlkes JD, et al. High-resolution laser-induced graphene. Flexible electronics beyond the visible limit. ACS Appl Mater Interfaces 2020;12:10902-7.

67. Duy LX, Peng Z, Li Y, Zhang J, Ji Y, Tour JM. Laser-induced graphene fibers. Carbon 2018;126:472-9.

68. Rahimi R, Ochoa M, Yu W, Ziaie B. Highly stretchable and sensitive unidirectional strain sensor via laser carbonization. ACS Appl Mater Interfaces 2015;7:4463-70.

69. Zang X, Shen C, Chu Y, et al. Laser-induced molybdenum carbide-graphene composites for 3D foldable paper electronics. Adv Mater 2018;30:e1800062.

70. Yang L, Liu C, Yuan W, et al. Fully stretchable, porous MXene-graphene foam nanocomposites for energy harvesting and self-powered sensing. Nano Energy 2022;103:107807.

71. Huang X, Li H, Li J, et al. Transient, implantable, ultrathin biofuel cells enabled by laser-induced graphene and gold nanoparticles composite. Nano Lett 2022;22:3447-56.

72. Sharma S, Pradhan GB, Jeong S, Zhang S, Song H, Park JY. Stretchable and all-directional strain-insensitive electronic glove for robotic skins and human-machine interfacing. ACS Nano 2023;17:8355-66.

73. Zhang C, Chen J, Gao J, et al. Laser processing of crumpled porous graphene/MXene nanocomposites for a standalone gas sensing system. Nano Lett 2023;23:3435-43.

74. Zhang S, Chhetry A, Zahed MA, et al. On-skin ultrathin and stretchable multifunctional sensor for smart healthcare wearables. npj Flex Electron 2022;6:11.

75. Xu G, Jarjes ZA, Desprez V, Kilmartin PA, Travas-Sejdic J. Sensitive, selective, disposable electrochemical dopamine sensor based on PEDOT-modified laser scribed graphene. Biosens Bioelectron 2018;107:184-91.

76. Heikenfeld J, Jajack A, Rogers J, et al. Wearable sensors: modalities, challenges, and prospects. Lab Chip 2018;18:217-48.

77. Kaidarova A, Khan MA, Marengo M, et al. Wearable multifunctional printed graphene sensors. npj Flex Electron 2019;3:15.

78. Xu K, Lu Y, Honda S, Arie T, Akita S, Takei K. Highly stable kirigami-structured stretchable strain sensors for perdurable wearable electronics. J Mater Chem C 2019;7:9609-17.

79. Ling Y, Zhuang X, Xu Z, et al. Mechanically assembled, three-dimensional hierarchical structures of cellular graphene with programmed geometries and outstanding electromechanical properties. ACS Nano 2018;12:12456-63.

80. Zhu Y, Cai H, Ding H, Pan N, Wang X. Fabrication of low-cost and highly sensitive graphene-based pressure sensors by direct laser scribing polydimethylsiloxane. ACS Appl Mater Interfaces 2019;11:6195-200.

81. Wang H, Zhao Z, Liu P, Guo X. A soft and stretchable electronics using laser-induced graphene on polyimide/PDMS composite substrate. npj Flex Electron 2022;6:26.

82. Jeong SY, Lee JU, Hong SM, et al. Highly skin-conformal laser-induced graphene-based human motion monitoring sensor. Nanomaterials 2021;11:951.

83. Sun B, McCay RN, Goswami S, et al. Gas-permeable, multifunctional on-skin electronics based on laser-induced porous graphene and sugar-templated elastomer sponges. Adv Mater 2018;30:e1804327.

84. Sindhu B, Kothuru A, Sahatiya P, Goel S, Nandi S. Laser-induced graphene printed wearable flexible antenna-based strain sensor for wireless human motion monitoring. IEEE Trans Electron Devices 2021;68:3189-94.

85. Luo S, Hoang PT, Liu T. Direct laser writing for creating porous graphitic structures and their use for flexible and highly sensitive sensor and sensor arrays. Carbon 2016;96:522-31.

86. Mehmood A, Mubarak NM, Khalid M, Jagadish P, Walvekar R, Abdullah EC. Graphene/PVA buckypaper for strain sensing application. Sci Rep 2020;10:20106.

87. Jeong SY, Ma YW, Lee JU, Je GJ, Shin BS. Flexible and highly sensitive strain sensor based on laser-induced graphene pattern fabricated by 355 nm pulsed laser. Sensors 2019;19:4867.

88. Wei S, Liu Y, Yang L, et al. Flexible large e-skin array based on patterned laser-induced graphene for tactile perception. Sensor Actuat A Phys 2022;334:113308.

89. Yoon H, Lee K, Shin H, et al. In situ co-transformation of reduced graphene oxide embedded in laser-induced graphene and full-range on-body strain sensor. Adv Funct Mater 2023;33:2300322.

90. Shao Q, Liu G, Teweldebrhan D, Balandin AA. High-temperature quenching of electrical resistance in graphene interconnects. Appl Phys Lett 2008;92:202108.

91. Kulyk B, Silva BFR, Carvalho AF, et al. Laser-induced graphene from paper by ultraviolet irradiation: humidity and temperature sensors. Adv Mater Technol 2022;7:2101311.

92. Tian Q, Yan W, Li Y, Ho D. Bean pod-inspired ultrasensitive and self-healing pressure sensor based on laser-induced graphene and polystyrene microsphere sandwiched structure. ACS Appl Mater Interfaces 2020;12:9710-7.

93. Li Y, Long J, Chen Y, Huang Y, Zhao N. Crosstalk-free, high-resolution pressure sensor arrays enabled by high-throughput laser manufacturing. Adv Mater 2022;34:e2200517.

94. Marengo M, Marinaro G, Kosel J. Flexible temperature and flow sensor from laser-induced graphene. In: 2017 IEEE SENSORS; 2017 Oct 29 - Nov 01; Glasgow, UK. IEEE; 2017. p. 1-3.

95. Wang J, Wang N, Xu D, Tang L, Sheng B. Flexible humidity sensors composed with electrodes of laser induced graphene and sputtered sensitive films derived from poly(ether-ether-ketone). Sensor Actuat B Chem 2023;375:132846.

96. Liu S, Chen R, Chen R, et al. Facile and cost-effective fabrication of highly sensitive, fast-response flexible humidity sensors enabled by laser-induced graphene. ACS Appl Mater Interfaces 2023;15:57327-37.

97. Xu K, Fujita Y, Lu Y, et al. A wearable body condition sensor system with wireless feedback alarm functions. Adv Mater 2021;33:e2008701.

98. Babatain W, Buttner U, El-Atab N, Hussain MM. Graphene and liquid metal integrated multifunctional wearable platform for monitoring motion and human-machine interfacing. ACS Nano 2022;16:20305-17.

99. Moin A, Zhou A, Rahimi A, et al. A wearable biosensing system with in-sensor adaptive machine learning for hand gesture recognition. Nat Electron 2021;4:54-63.

100. Yang H, Li J, Lim KZ, et al. Automatic strain sensor design via active learning and data augmentation for soft machines. Nat Mach Intell 2022;4:84-94.

101. Lu Y, Kong D, Yang G, et al. Machine learning-enabled tactile sensor design for dynamic touch decoding. Adv Sci 2023;10:e2303949.

102. Xie J, Zhao Y, Zhu D, et al. A machine learning-combined flexible sensor for tactile detection and voice recognition. ACS Appl Mater Interfaces 2023;15:12551-9.

103. Zhao P, Zhang Y, Liu Y, Huo D, Hou J, Hou C. Wearable electrochemical patch based on iron nano-catalysts incorporated laser-induced graphene for sweat metabolites detection. Biosens Bioelectron 2024;249:116012.

104. Ricciardolo FL, Sorbello V, Ciprandi G. FeNO as biomarker for asthma phenotyping and management. Allergy Asthma Proc 2015;36:e1-8.

105. Antus B, Barta I, Horvath I, Csiszer E. Relationship between exhaled nitric oxide and treatment response in COPD patients with exacerbations. Respirology 2010;15:472-7.

106. Malerba M, Radaeli A, Olivini A, et al. Exhaled nitric oxide as a biomarker in COPD and related comorbidities. Biomed Res Int 2014;2014:271918.

107. Wang H, Xiang Z, Zhao P, et al. Double-sided wearable multifunctional sensing system with anti-interference design for human-ambience interface. ACS Nano 2022;16:14679-92.

108. Sun H, Gao X, Guo L, et al. Graphene-based dual-function acoustic transducers for machine learning-assisted human–robot interfaces. InfoMat 2023;5:e12385.

109. Song W, Wang H, Liu G, Peng M, Zou D. Improving the photovoltaic performance and flexibility of fiber-shaped dye-sensitized solar cells with atomic layer deposition. Nano Energy 2016;19:1-7.

110. Pu X, Song W, Liu M, et al. Wearable power-textiles by integrating fabric triboelectric nanogenerators and fiber-shaped dye-sensitized solar cells. Adv Energy Mater 2016;6:1601048.

111. Jung S, Lee J, Hyeon T, Lee M, Kim DH. Fabric-based integrated energy devices for wearable activity monitors. Adv Mater 2014;26:6329-34.

112. Lee JW, Xu R, Lee S, et al. Soft, thin skin-mounted power management systems and their use in wireless thermography. Proc Natl Acad Sci U S A 2016;113:6131-6.

113. Liu C, Neale ZG, Cao G. Understanding electrochemical potentials of cathode materials in rechargeable batteries. Mater Today 2016;19:109-23.

114. Cong HP, Chen JF, Yu SH. Graphene-based macroscopic assemblies and architectures: an emerging material system. Chem Soc Rev 2014;43:7295-325.

115. Aricò AS, Bruce P, Scrosati B, Tarascon JM, van Schalkwijk W. Nanostructured materials for advanced energy conversion and storage devices. Nat Mater 2005;4:366-77.

116. Pu X, Liu M, Li L, et al. Wearable textile-based in-plane microsupercapacitors. Adv Energy Mater 2016;6:1601254.

117. Wang J, Li X, Zi Y, et al. A flexible fiber-based supercapacitor-triboelectric-nanogenerator power system for wearable electronics. Adv Mater 2015;27:4830-6.

118. Wang H, Yang Y, Guo L. Nature-inspired electrochemical energy-storage materials and devices. Adv Energy Mater 2017;7:1601709.

119. Zhou L, Zhuang Z, Zhao H, Lin M, Zhao D, Mai L. Intricate hollow structures: controlled synthesis and applications in energy storage and conversion. Adv Mater 2017;29:1602914.

120. Yu Y, Nassar J, Xu C, et al. Biofuel-powered soft electronic skin with multiplexed and wireless sensing for human-machine interfaces. Sci Robot 2020;5:eaaz7946.

121. Chen J, Wang ZL. Reviving vibration energy harvesting and self-powered sensing by a triboelectric nanogenerator. Joule 2017;1:480-521.

122. Stanford MG, Li JT, Chyan Y, Wang Z, Wang W, Tour JM. Laser-induced graphene triboelectric nanogenerators. ACS Nano 2019;13:7166-74.

123. Wang G, Zhang L, Zhang J. A review of electrode materials for electrochemical supercapacitors. Chem Soc Rev 2012;41:797-828.

124. 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.

125. Yang R, Zhang W, Tiwari N, Yan H, Li T, Cheng H. Multimodal sensors with decoupled sensing mechanisms. Adv Sci 2022;9:e2202470.