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06-03-2021 | Original Research

Simple preparation of carboxymethyl cellulose-based ionic conductive hydrogels for highly sensitive, stable and durable sensors

Authors: Chunyin Lu, Jianhui Qiu, Manxi Sun, Qifan Liu, Eiichi Sakai, Guohong Zhang

Published in: Cellulose | Issue 7/2021

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Abstract

Ionic conductive hydrogels have recently been increasingly studied due to their broad applications in sensing and flexible devices. Nevertheless, it is still a challenge to simply develop an ionic conductive hydrogel with satisfying comprehensive performance. Herein, ionic conductive hydrogels have been crosslinked by carboxymethyl cellulose and phytic acid via a simple one-pot approach to address these challenges. The unique double crosslinked microstructure ensures that the hydrogel has favourable mechanical performance, resilience (93%, similar to natural resilin), and recovery (20 min, after 7 cycles at 300%) along with less residual strain (6.7%, after 20 successive cycles at 125%). The hydrogel also exhibits outstanding ionic conductivity (6.0 S/m). The combined mechanical performance and ionic conductivity of the prepared hydrogel results in its remarkable performance when used in sensors. The hydrogel-based sensor displays superior sensitivity (GF of 2.86, at a strain of 600%), stability and durability towards both tensile and compressive deformation. In practical applications, the sensor demonstrates a broad strain window to detect both large and very small human activities, showing the excellent potential of this hydrogel in sensing and flexible devices. The approach in this work has also been optimized to potentially allow for large-area, low-cost fabrication.

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Anirudhan T, Tharun A, Rejeena S (2011) Investigation on poly (methacrylic acid)-grafted cellulose/bentonite superabsorbent composite: synthesis, characterization, and adsorption characteristics of bovine serum albumin. Ind Eng Chem Res 50:1866–1874CrossRef

Bian L, Hou C, Tous E, Rai R, Mauck RL, Burdick JA (2013) The influence of hyaluronic acid hydrogel crosslinking density and macromolecular diffusivity on human MSC chondrogenesis and hypertrophy. Biomaterials 34:413–421PubMedCrossRef

Chen G, Huang J, Gu J, Peng S, Xiang X, Chen K, Yang X, Guan L, Jiang X, Hou L (2020) Highly tough supramolecular double network hydrogel electrolytes for an artificial flexible and low-temperature tolerant sensor. J Mater Chem A 8:6776–6784CrossRef

Chen H, Ren X, Gao G (2019) Skin-inspired gels with toughness, antifreezing, conductivity, and remoldability. ACS Appl Mater Interfaces 11:28336–28344PubMedCrossRef

Cui Z-K, KIM S, Baljon JJ, Wu BM, Aghaloo T, Lee M. (2019) Microporous methacrylated glycol chitosan-montmorillonite nanocomposite hydrogel for bone tissue engineering. Nat Commun 10:1–10CrossRef

Distler T, Boccaccini AR (2020) 3D printing of electrically conductive hydrogels for tissue engineering and biosensors—a review. Acta Biomater 101:1–13PubMedCrossRef

Ge G, Zhang Y, Shao J, Wang W, Si W, Huang W, Dong X (2018) Stretchable, transparent, and self-patterned hydrogel-based pressure sensor for human motions detection. Adv Func Mater 28:1802576CrossRef

Heidarian P, Kouzani AZ, Kaynak A, Paulino M, Nasri-Nasrabadi B, Varley R (2020) Double dynamic cellulose nanocomposite hydrogels with environmentally adaptive self-healing and pH-tuning properties. Cellulose 27:1407–1422CrossRef

Hsiao L-Y, Jing L, Li K, Yang H, Li Y, Chen P-Y (2020) Carbon nanotube-integrated conductive hydrogels as multifunctional robotic skin. Carbon 161:784–793CrossRef

Jeong D, Kim C, Kim Y, Jung S (2020) Dual crosslinked carboxymethyl cellulose/polyacrylamide interpenetrating hydrogels with highly enhanced mechanical strength and superabsorbent properties. Eur Polym J 127:109586CrossRef

Kayser LV, Lipomi DJ (2019) Stretchable conductive polymers and composites based on PEDOT and PEDOT: PSS. Adv Mater 31:1806133CrossRef

Kong B, Chen Y, Liu R, Liu X, Liu C, Shao Z, Xiong L, Liu X, Sun W, Mi S (2020) Fiber reinforced GelMA hydrogel to induce the regeneration of corneal stroma. Nat Commun 11:1–12CrossRef

Li S, Pan H, Wang Y, Sun J (2020) Polyelectrolyte complex-based self-healing, fatigue-resistant and anti-freezing hydrogels as highly sensitive ionic skins. J Mater Chem A 8:3667–3675CrossRef

Lin P, Ma S, Wang X, Zhou F (2015) Molecularly engineered dual-crosslinked hydrogel with ultrahigh mechanical strength, toughness, and good self-recovery. Adv Mater 27:2054–2059PubMedCrossRef

Liu S, Li K, Hussain I, Oderinde O, Yao F, Zhang J, Fu G (2018) A conductive self-healing double network hydrogel with toughness and force sensitivity. Chem A Eur J 24:6632–6638CrossRef

Liu Y-J, Cao W-T, Ma M-G, Wan P (2017) Ultrasensitive wearable soft strain sensors of conductive, self-healing, and elastic hydrogels with synergistic “soft and hard” hybrid networks. ACS Appl Mater Interfaces 9:25559–25570PubMedCrossRef

Liu Y, Huang X, Han K, Dai Y, Zhang X, Zhao Y (2019) High-performance lignin-based water-soluble macromolecular photoinitiator for the fabrication of hybrid hydrogel. ACS Sustain Chem Eng 7:4004–4011CrossRef

Liu Y, Wang W, Wang A (2010) Adsorption of lead ions from aqueous solution by using carboxymethyl cellulose-g-poly (acrylic acid)/attapulgite hydrogel composites. Desalination 259:258–264CrossRef

Means AK, Grunlan MA (2019) Modern strategies to achieve tissue-mimetic, mechanically robust hydrogels. ACS Macro Lett 8:705–713CrossRef

Mohamed ZE-S, Amr A, Knittel D, Schollmeyer E (2010) Synthesis and application of new sizing and finishing additives based on carboxymethyl cellulose. Carbohyd Polym 81:769–774CrossRef

Pan S, Xia M, Li H, Jiang X, He P, Sun Z, Zhang Y (2020) Transparent, high-strength, stretchable, sensitive and anti-freezing poly (vinyl alcohol) ionic hydrogel strain sensors for human motion monitoring. J Mater Chem C 8:2827–2837CrossRef

Ren K, Cheng Y, HUANG C, Chen R, Wang Z, Wei J. (2019) Self-healing conductive hydrogels based on alginate, gelatin and polypyrrole serve as a repairable circuit and a mechanical sensor. J Mater Chem B 7:5704–5712PubMedCrossRef

Ryplida B, Lee KD, In I, Park SY (2019) Light-induced swelling-responsive conductive, adhesive, and stretchable wireless film hydrogel as electronic artificial skin. Adv Func Mater 29:1903209CrossRef

Sang Z, Qian J, Han J, deng X, Shen J, Li G, Xie Y. (2020) Comparison of three water-soluble polyphosphate tripolyphosphate, phytic acid, and sodium hexametaphosphate as crosslinking agents in chitosan nanoparticle formulation. Carbohyd Polym 230:115577CrossRef

Shao L, Li Y, Ma Z, Bai Y, Wang J, Zeng P, Gong P, Shi F, Ji Z, Qiao Y (2020) A highly sensitive strain sensor based on stretchable and conductive poly (vinyl alcohol)/phytic acid/NH2-POSS hydrogel with a 3D microporous structure. ACS Appl Mater Interf 12:26496–26508CrossRef

Song J, Chen S, Sun L, Guo Y, Zhang L, Wang S, Xuan H, Guan Q, You Z (2020) mechanically and electronically robust transparent organohydrogel fibers. Adv Mater 32:1906994CrossRef

Sui X, GUO H, Chen P, Zhu Y, Wen C, Gao Y, Yang J, Zhang X, Zhang L. (2020) Zwitterionic osmolyte-based hydrogels with antifreezing property, high conductivity, and stable flexibility at subzero temperature. Adv Func Mater 30:1907986CrossRef

Sun X, Qin Z, Ye L, Zhang H, Yu Q, Wu X, Li J, Yao F (2020a) Carbon nanotubes reinforced hydrogel as flexible strain sensor with high stretchability and mechanically toughness. Chem Eng J 382:122832CrossRef

Sun X, Yao F, Li J (2020b) Nanocomposite hydrogel-based strain and pressure sensors: a review. J Mater Chem A 8:18605–18623CrossRef

Sun X, Yao F, Wang C, Qin Z, Zhang H, Yu Q, ZHANG H, Dong X, Wei Y, Li J. 2020c. Ionically Conductive Hydrogel with Fast Self‐Recovery and Low Residual Strain as Strain and Pressure Sensors. Macromolecular Rapid Communications: 2000185.

Tatham AS, Shewry PR (2002) Comparative structures and properties of elastic proteins. Philos Trans R Soc Lond B Biol Sci 357:229–234PubMedPubMedCentralCrossRef

Wang H, Zhu CN, Zeng H, Ji X, Xie T, Yan X, Wu ZL, Huang F (2019) reversible ion-conducting switch in a novel single-ion supramolecular hydrogel enabled by photoresponsive host-guest molecular recognition. Adv Mater 31:1807328CrossRef

Wang L, Daoud WA (2019) Hybrid conductive hydrogels for washable human motion energy harvester and self-powered temperature-stress dual sensor. Nano Energy 66:104080CrossRef

Wang MX, Chen YM, GAO Y, Hu C, Hu J, Tan L, Yang Z. (2018) Rapid self-recoverable hydrogels with high toughness and excellent conductivity. ACS Appl Mater Interfaces 10:26610–26617PubMedCrossRef

Wang W, Liu Y, Wang S, Fu X, Zhao T, Chen X, Shao Z (2020) Physically cross-linked silk fibroin-based tough hydrogel electrolyte with exceptional water retention and freezing tolerance. ACS Appl Mater Interfaces 12:25353–25362PubMedCrossRef

Wang X, Gu Y, Xiong Z, Cui Z, Zhang T (2014) Silk-molded flexible, ultrasensitive, and highly stable electronic skin for monitoring human physiological signals. Adv Mater 26:1336–1342PubMedCrossRef

Wang X, Wen K, Yang X, Li L, Yu X (2017) Biocompatibility and anti-calcification of a biological artery immobilized with naturally-occurring phytic acid as the crosslinking agent. J Mater Chem B 5:8115–8124PubMedCrossRef

Wang Y, Zhang L, Lu A (2019) Transparent, antifreezing, ionic conductive cellulose hydrogel with stable sensitivity at subzero temperature. ACS Appl Mater Interfaces 11:41710–41716PubMedCrossRef

Wang Z, Cong Y, Fu J (2020) Stretchable and tough conductive hydrogels for flexible pressure and strain sensors. J Mater Chem B 8:3437–3459PubMedCrossRef

Wang Z, Yuan L, Jiang F, Zhang Y, Wang Z, Tang C (2016) Bioinspired high resilient elastomers to mimic resilin. ACS Macro Letters 5:220–223CrossRef

Wang Z, Zhou H, Lai J, Yan B, Liu H, Jin X, Ma A, Zhang G, Zhao W, Chen W (2018) Extremely stretchable and electrically conductive hydrogels with dually synergistic networks for wearable strain sensors. J Mater Chem C 6:9200–9207CrossRef

Yang J, Yao J, Guan S (2020) Enhanced electroresponsive and electrochemical properties of the biological gel artificial muscle prepared by sodium alginate and carboxylated chitosan. Sens Actuat B Chem 322:128526CrossRef

Ye Y, Zhang Y, Chen Y, Han X, Jiang F (2020) Cellulose Nanofibrils Enhanced, Strong, Stretchable, Freezing-Tolerant Ionic Conductive Organohydrogel for Multi-Functional Sensors. Adv Func Mater 30:2003430CrossRef

Zhang B, He J, Shi M, Liang Y, Guo B (2020) Injectable self-healing supramolecular hydrogels with conductivity and photo-thermal antibacterial activity to enhance complete skin regeneration. Chem Eng J 400:125994CrossRef

Zhang H, Niu W, Zhang S (2020) Extremely stretchable, sticky and conductive double-network ionic hydrogel for ultra-stretchable and compressible supercapacitors. Chem Eng J 387:124105CrossRef

Zhang H, Wu X, Qin Z, Sun X, Zhang H, Yu Q, Yao M, He S, Dong X, Yao F. 2020c. Dual physically cross-linked carboxymethyl cellulose-based hydrogel with high stretchability and toughness as sensitive strain sensors. Cellulose: 1–15.

Zhang L, Lu H, Yu J, Fan Y, Ma J, Wang Z (2019) Contribution of lignin to the microstructure and physical performance of three-dimensional lignocellulose hydrogels. Cellulose 26:2375–2388CrossRef

Zhang Q, Liu X, Duan L, Gao G (2020) Nucleotide-driven skin-attachable hydrogels toward visual human—machine interfaces. Journal of Materials Chemistry A 8:4515–4523CrossRef

Zhang S, Zhang Y, Li B, Zhang P, Kan L, Wang G, Wei H, Zhang X, Ma N (2019) One-step preparation of a highly stretchable, conductive, and transparent poly (vinyl alcohol)–phytic acid hydrogel for casual writing circuits. ACS Appl Mater Interfaces 11:32441–32448PubMedCrossRef

Zhang X, Sheng N, Wang L, Tan Y, Liu C, Xia Y, Nie Z, Sui K (2019) Supramolecular nanofibrillar hydrogels as highly stretchable, elastic and sensitive ionic sensors. Materials Horizons 6:326–333CrossRef

Zhang Z, Chen Z, Wang Y, Zhao Y (2020) Bioinspired conductive cellulose liquid-crystal hydrogels as multifunctional electrical skins. Proc Natl Acad Sci 117:18310–18316PubMedCrossRef

Zhao Y, Li Z, Song S, Yang K, Liu H, Yang Z, Wang J, Yang B, Lin Q (2019) Skin-inspired antibacterial conductive hydrogels for epidermal sensors and diabetic foot wound dressings. Adv Func Mater 29:1901474CrossRef

Zheng C, Yue Y, Gan L, Xu X, Mei C, Han J (2019) Highly stretchable and self-healing strain sensors based on nanocellulose-supported graphene dispersed in electro-conductive hydrogels. Nanomaterials 9:937PubMedCentralCrossRef

Zhou H, Wang Z, Zhao W, Tong X, Jin X, Zhang X, Yu Y, Liu H, Ma Y, Li S (2020) Robust and sensitive pressure/strain sensors from solution processable composite hydrogels enhanced by hollow-structured conducting polymers. Chem Eng J 403:126307CrossRef

Zhou Y, Wan C, Yang Y, Yang H, Wang S, Dai Z, Ji K, Jiang H, Chen X, Long Y (2019) Highly stretchable, elastic, and ionic conductive hydrogel for artificial soft electronics. Adv Func Mater 29:1806220CrossRef

Zhu L, Qiu J, Sakai E, Ito K (2017) Rapid recovery double cross-linking hydrogel with stable mechanical properties and high resilience triggered by visible light. ACS Appl Mater Interfaces 9:13593–13601PubMedCrossRef

Zhu X, Yang C, Wu P, Ma Z, Shang Y, Bai G, Liu X, Chang G, Li N, Dai J (2020) Precise control of versatile microstructure and properties of graphene aerogel via freezing manipulation. Nanoscale 12:4882–4894PubMedCrossRef

Title: Simple preparation of carboxymethyl cellulose-based ionic conductive hydrogels for highly sensitive, stable and durable sensors
Authors: Chunyin Lu
Jianhui Qiu
Manxi Sun
Qifan Liu
Eiichi Sakai
Guohong Zhang
Publication date: 06-03-2021
Publisher: Springer Netherlands
Published in: Cellulose / Issue 7/2021
Print ISSN: 0969-0239
Electronic ISSN: 1572-882X
DOI: https://doi.org/10.1007/s10570-021-03800-2

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