[1] Choi S, Lee H, Ghaffari R, et al. Recent advances in flexible and stretchable bio-electronic devices integrated with nanomaterials［J］.Advanced Materials,2016,28(22): 4203-4218.

[2] Trung T Q, Lee N E. Flexible and stretchable physical sensor integrated platforms for wearable human-activity monitoring and personal healthcare［J］.Advanced Materials,2016,28(22): 4338-4372.

[3] Yamada T, Hayamizu Y, Yamamoto Y, et al. A stretchable carbon nanotube strain sensor for human-motion detection［J］.Nature Nanotechnology,2011,6(5): 296.

[4] Lipomi D J, Lee J A, Vosgueritchian M, et al. Electronic properties of transparent conductive films of PEDOT∶PSS on stretchable substrates［J］.Chemistry of Materials,2012,24(2): 373-382.

[5] Kim S R, Kim J H, Park J W. Wearable and transparent capacitive strain sensor with high sensitivity based on patterned Ag nanowire networks［J］.ACS Applied Materials & Interfaces,2017,9(31): 26407-26416.

[6] Roh E, Hwang B U, Kim D, et al. Stretchable, transparent, ultrasensitive, and patchable strain sensor for human-machine interfaces comprising a nanohybrid of carbon nanotubes and conductive elastomers［J］.ACS Nano,2015,9(6): 6252-6261.

[7] Kim J Y, Ji S, Jung S, et al. 3D Printable composite dough for stretchable, ultrasensitive and body-patchable strain sensors［J］.Nanoscale,2017,9(31): 11035-11046.

[8] Li Y, Samad Y A, Taha T, et al. Highly flexible strain sensor from tissue paper for wearable electronics［J］.ACS Sustainable Chemistry & Engineering,2016,4(8): 4288-4295.

[9] Lipomi D J, Lee J A, Vosgueritchian M, et al. Electronic properties of transparent conductive films of PEDOT∶PSS on stretchable substrates［J］.Chemistry of Materials,2012,24(2): 373-382.

[10] Fang X, Tan J, Gao Y, et al. High-performance wearable strain sensors based on fragmented carbonized melamine sponges for human motion detection［J］.Nanoscale,2017 9(45): 17948-17956.

[11] Schwartz G, Tee B C K, Mei J, et al. Flexible polymer transistors with high pressure sensitivity for application in electronic skin and health monitoring［J］.Nature Communications,2013,4(1): 1-8.

[12] Yang T, Jiang X, Zhong Y, et al. A wearable and highly sensitive graphene strain sensor for precise home-based pulse wave monitoring［J］.ACS Sensors,2017,2(7): 967-974.

[13] Viry L, Levi A, Totaro M, et al. Flexible three-axial force sensor for soft and highly sensitive artificial touch［J］.Advanced Materials,2014,26(17): 2659-2664.

[14] Li Y, Samad Y A, Taha T, et al. Highly flexible strain sensor from tissue paper for wearable electronics［J］.ACS Sustainable Chemistry & Engineering,2016,4(8): 4288-4295.

[15] Cao J, Lu C, Zhuang J, et al. Multiple hydrogen bonding enables the self-healing of sensors for human-machine interactions［J］.Angewandte Chemie International Edition,2017,56(30): 8795-8800.

[16] Deng C, Pan L, Zhang D, et al. A super stretchable and sensitive strain sensor based on a carbon nanocoil network fabricated by a simple peeling-off approach［J］.Nanoscale,2017,9(42): 16404-16411.

[17] Park M, Park J, Jeong U. Design of conductive composite elastomers for stretchable electronics［J］.Nano Today,2014,9(2): 244-260.

[18] Amjadi M, Kyung K U, Park I, et al. Stretchable, skin-mountable, and wearable strain sensors and their potential applications: a review［J］.Advanced Functional Materials,2016,26(11): 1678-1698.

[19] Kim K H, Jang N S, Ha S H, et al. Highly sensitive and stretchable resistive strain sensors based on microstructured metal nanowire/elastomer composite films［J］.Small,2018,14(14): 1704232.

[20] Wang R, Xu W, Shen W, et al. A highly stretchable and transparent silver nanowire/thermoplastic polyurethane film strain sensor for human motion monitoring［J］.Inorganic Chemistry Frontiers,2019,6(11): 3119-3124.

[21] Gong S, Lai D T H, Su B, et al. Highly stretchy black gold E-skin nanopatches as highly sensitive wearable biomedical sensors［J］.Advanced Electronic Materials,2015,1(4): 1400063.

[22] Segev-Bar M, Haick H. Flexible sensors based on nanoparticles［J］.ACS Nano,2013,7(10): 8366-8378.

[23] Wu S Y, Peng S H, Han Z J, et al. Ultrasensitive and stretchable strain sensors based on mazelike vertical graphene network［J］.ACS Applied Materials & Interfaces,2018,10(42): 36312-36322.

[24] Gilshteyn E P, Romanov S A, Kopylova D S, et al. Mechanically tunable single-walled carbon nanotube films as a universal material for transparent and stretchable electronics［J］.ACS Applied Materials & Interfaces,2019,11(30): 27327-27334.

[25] Shajari S, Mahmoodi M, Rajabian M, et al. Highly sensitive and stretchable carbon nanotube/fluoroelastomer nanocomposite with a double-percolated network for wearable electronics［J］.Advanced Electronic Materials,2020: 1901067.

[26] Peng X W, Wu K Z, Hu Y J, et al. A mechanically strong and sensitive CNT/rGO-CNF carbon aerogel for piezoresistive sensors［J］.Journal of Materials Chemistry A,2018,6(46): 23550-23559.

[27] Oh E, Kim T, Yoon J, et al. Highly reliable liquid metal-solid metal contacts with a corrugated single-walled carbon nanotube diffusion barrier for stretchable electronics［J］.Advanced Functional Materials,2018,28(51): 1806014.

[28] He Z L, Zhou G H, Byun J H, et al. Highly stretchable multi-walled carbon nanotube/thermoplastic polyurethane composite fibers for ultrasensitive, wearable strain sensors［J］. Nanoscale, 2019, 11(13): 5884-5890.

[29] Lee J, Lim M, Yoon J, et al. Transparent, flexible strain sensor based on a solution-processed carbon nanotube network［J］. ACS applied materials & interfaces, 2017, 9(31): 26279-26285.

[30] Zhilyaeva M A, Shulga E V, Shandakov S D, et al. A novel straightforward wet pulling technique to fabricate carbon nanotube fibers［J］. Carbon, 2019, 150: 69-75.

[31] Ahuja P, Ujjain S K, Urita K, et al. Chemically and mechanically robust SWCNT based strain sensor with monotonous piezoresistive response for infrastructure monitoring［J］. Chemical Engineering Journal, 2020, 388: 124174.

[32] Ma L, Lu W. Carbon Nanotube film based flexible Bi-directional strain sensor for large deformation［J］. Materials Letters, 2020, 260: 126959.

[33] Liang B H, Lin Z Q, Chen W J, et al. Ultra-stretchable and highly sensitive strain sensor based on gradient structure carbon nanotubes［J］. Nanoscale, 2018, 10(28): 13599-13606.

[34] Wang Y L, Jia Y Y, Zhou Y J, et al. Ultra-stretchable, sensitive and durable strain sensors based on polydopamine encapsulated carbon nanotubes/elastic bands［J］. Journal of Materials Chemistry C, 2018, 6(30): 8160-8170.

[35] Liu H, Gao J C, Huang W J, et al. Electrically conductive strain sensing polyurethane nanocomposites with synergistic carbon nanotubes and graphene bifillers［J］. Nanoscale, 2016, 8(26): 12977-12989.