Poly(ionic liquid) functionalization: A general strategy for strong, tough, ionic conductive, and multifunctional polysaccharide hydrogels toward sensors

Xue Yao; Sufeng Zhang; Ning Wei; Liwei Qian; Hao Ding; Jingtao Liu; Wenqi Song; Sergiu Coseri

doi:10.1002/sus2.249

SusMat ›› 2024, Vol. 4 ›› Issue (6) : e249 DOI: 10.1002/sus2.249

RESEARCH ARTICLE

Poly(ionic liquid) functionalization: A general strategy for strong, tough, ionic conductive, and multifunctional polysaccharide hydrogels toward sensors

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Abstract

Ionic conductive hydrogels (ICHs) prepared from natural bioresources are promising candidates for constructing flexible electronics for both commercialization and environmental sustainability due to their intrinsic characteristics. However, simultaneous realization of high stiffness, toughness, conductivity, and multifunctionality while ensuring processing simplicity is extremely challenging. Here, a poly(ionic liquid) (PIL)-macromolecule functionalization strategy within a NaOH/urea system is proposed to construct high-performance and versatile polysaccharide-based ICHs (e.g., cellulosic ICHs). In this strategy, the elaborately designed “soft” (PIL chains) and “hard” (cellulose backbone) structures as well as the dynamic covalent and noncovalent bonds of the cross-linked networks endow the hydrogel with high mechanical strength (9.46 ± 0.23 MPa compressive modulus), exceptional stretchability (214.3%), and toughness (3.64 ± 0.12 MJ m^–3). Ingeniously, due to the inherent conductivity, design flexibility, and functional compatibility of the PILs, the hydrogels exhibit high conductivity (6.54 ± 0.17 mS cm^–1), self-healing ability (94.5% ± 2.0% efficiency), antibacterial properties, freezing resistance, water retention, and recyclability. Interestingly, this strategy is extended to fabricate diverse hydrogels from various polysaccharides, including agar, alginate, hyaluronic acid, and guar gum. In addition, multimodal sensing (strain, temperature, and humidity) is realized based on the stimulus-responsive characteristics of the hydrogels. This strategy opens new perspectives for the design of biomass-based hydrogels and beyond.

Keywords

bioresources / cellulose / conductive hydrogels / multiple functions / poly(ionic liquids) / sensors

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Xue Yao, Sufeng Zhang, Ning Wei, Liwei Qian, Hao Ding, Jingtao Liu, Wenqi Song, Sergiu Coseri. Poly(ionic liquid) functionalization: A general strategy for strong, tough, ionic conductive, and multifunctional polysaccharide hydrogels toward sensors. SusMat, 2024, 4(6): e249 DOI:10.1002/sus2.249

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Bai Z, Wang X, Zheng M, et al. Mechanically robust and transparent organohydrogel-based e-skin nanoengineered from natural skin. Adv Funct Mater. 2023; 33(15): 2212856.

[2]	Li W, Li L, Zheng S, et al. Recyclable, healable, and tough ionogels insensitive to crack propagation. Adv Mater. 2022; 34(28): 2203049.

[3]	Lu C, Wang X, Shen Y, et al. Skin-like transparent, high resilience, low hysteresis, fatigue-resistant cellulose-based eutectogel for self-powered e-skin and human-machine interaction. Adv Funct Mater. 2023; 34(13): 2311502.

[4]	Bai Z, Wang X, Huang M, et al. Smart battery-free and wireless bioelectronic platform based on a nature-skin-derived organohydrogel for chronic wound diagnosis, assessment, and accelerated healing. Nano Energy. 2023; 118: 108989.

[5]	Kim J, Zhang G, Shi M, Suo Z. Fracture, fatigue, and friction of polymers in which entanglements greatly outnumber cross-links. Science. 2021; 374(6564): 212-216.

[6]	Wang J, Wu B, Wei P, Sun S, Wu P. Fatigue-free artificial ionic skin toughened by self-healable elastic nanomesh. Nat Commun. 2022; 13(1): 4411.

[7]	Hu D, Zeng M, Sun Y, Yuan J, Wei Y. Cellulose-based hydrogels regulated by supramolecular chemistry. SusMat. 2021; 1(2): 266-284.

[8]	Li W, Zheng S, Zou X, et al. Tough hydrogels with isotropic and unprecedented crack propagation resistance. Adv Funct Mater. 2022; 32(43): 2207348.

[9]	Li W, Wang X, Liu Z, et al. Nanoconfined polymerization limits crack propagation in hysteresis-free gels. Nat Mater. 2024; 23(1): 131-138.

[10]	He Q, Cheng Y, Deng Y, et al. Conductive hydrogel for flexible bioelectronic device: current progress and future perspective. Adv Funct Mater. 2024; 34(1): 2308974.

[11]	Ye Y, Yu L, Lizundia E, et al. Cellulose-based ionic conductor: an emerging material toward sustainable devices. Chem Rev. 2023; 123(15): 9204-9264.

[12]	Zhao D, Zhu Y, Cheng W, et al. Cellulose-based flexible functional materials for emerging intelligent electronics. Adv Mater. 2021; 33(28): 2000619.

[13]	Qin Y, Zhang W, Liu Y, et al. Cellulosic gel-based triboelectric nanogenerators for energy harvesting and emerging applications. Nano Energy. 2023; 106: 108079.

[14]	Ye Y, Zhang Y, Chen Y, Han X, Jiang F. Cellulose nanofibrils enhanced, strong, stretchable, freezing-tolerant ioni. conductive organohydrogel for multi-functional sensors. Adv Funct Mater. 2020; 30(35): 2003430.

[15]	Yao X, Zhang S, Qian L, et al. Super stretchable, self-healing, adhesive ionic conductive hydrogels based on tailor-made ionic liquid for high-performance strain sensors. Adv Funct Mater. 2022; 32(33): 2204565.

[16]	Li P, Ling Z, Liu X, et al. Nanocomposite hydrogels flexible sensors with functional cellulose nanocrystals for monitoring human motion and lactate in sweat. Chem Eng J. 2023; 466: 143306.

[17]	Tu H, Zhu MX, Duan B, Zhang L. Recent progress in high-strength and robust regenerated cellulose materials. Adv Mater. 2021; 33(28): 2000682.

[18]	Wei P, Wang L, Xie F, Cai J. Strong and tough cellulose-graphene oxide composite hydrogels by multi-modulus components strategy as photothermal antibacterial platform. Chem Eng J. 2022; 431(11): 133964.

[19]	Shen Y, Jia Q, Xu S, et al. Fast-photocurable, mechanically robust, and malleable cellulosic bio-thermosets based on hindered urea bond for multifunctional electronics. Adv Funct Mater. 2023; 34(7): 2310599.

[20]	Zhao X, Chen X, Yuk H, et al. Soft materials by design: unconventional polymer networks give extreme properties. Chem Rev. 2021; 121(8): 4309-4372.

[21]	Xu L, Qiao Y, Qiu D. Coordinatively stiffen and toughen hydrogels with adaptable crystal-domain cross-linking. Adv Mater. 2023; 35(12): 2209913.

[22]	Zhu T, Ni Y, Biesold GM, et al. Recent advances in conductive hydrogels: classifications, properties, and applications. Chem Soc Rev. 2022; 52(2): 473-509.

[23]	Li M, Chen L, Li Y, et al. Superstretchable, yet stiff, fatigue-resistant ligament-like elastomers. Nat Commun. 2022; 13(1): 2279.

[24]	Huang J, Li J, Xu X, Hua L, Lu Z. In situ loading of polypyrrole onto aramid nanofiber and carbon nanotube aerogel fibers as physiology and motion sensors. ACS Nano. 2022; 16(5): 8161-8171.

[25]	Pan X, Li J, Ma N, Ma X, Gao M. Bacterial cellulose hydrogel for sensors. Chem Eng J. 2023; 461: 142062.

[26]	Yang X, Huang J, Chen C, et al. Biomimetic design of double-sided functionalized silver nanoparticle/bacterial cellulose/hydroxyapatite hydrogel mesh for temporary cranioplasty. ACS Appl Mater Interfaces. 2023; 15(8): 10506-10519.

[27]	Li L, Li W, Wang X, et al. Ultra-tough and recyclable ionogels constructed by coordinated supramolecular solvents. Angew Chem Int Ed Engl. 2022; 61(50): e202212512.

[28]	Lei K, Chen M, Guo P, et al. Environmentally adaptive polymer hydrogels: maintaining wet-soft features in extreme conditions. Adv Funct Mater. 2023; 33(41): 2303511.

[29]	Cao K, Zhu Y, Zheng Z, et al. Bio-inspired multiscale design for strong and tough biological ionogels. Adv Sci. 2023; 10(13): 2207233.

[30]	Bao B, Zeng Q, Li K, et al. Rapid fabrication of physically robust hydrogels. Nat Mater. 2023; 22(10): 1253-1260.

[31]	Kubota K, Toyoshima N, Miura D, et al. Introduction of a luminophore into generic polymers via mechanoradical coupling with a prefluorescent reagent. Angew Chem Int Ed Engl. 2021; 60(29): 16003-16008.

[32]	Rivera DG, Ricardo MG, Vasco AV, Wessjohann LA, Van der Eycken EV. On-resin multicomponent protocols for biopolymer assembly and derivatization. Nat Protoc. 2021; 16(2): 561-578.

[33]	Bargstedt J, Reinschmidt M, Tydecks L, et al. Photochromic nucleosides and oligonucleotides. Angew Chem Int Ed Engl. 2024; 63(9): e202310797.

[34]	Zheng S, Li W, Ren Y, et al. Moisture-wicking, breathable, and intrinsically antibacterial electronic skin based on dual-gradient poly(ionic liquid) nanofiber membranes. Adv Mater. 2022; 34(4): 2106570.

[35]	Li L, Wang X, Gao S, et al. High-toughness and high-strength solvent-free linear poly(ionic liquid) elastomers. Adv Mater. 2024; 36(7): 2308547.

[36]	Wang S, Yu L, Wang S, et al. Strong, tough, ionic conductive, and freezing-toleran. all-natural hydrogel enabled by cellulose-bentonite coordination interactions. Nat Commun. 2022; 13(1): 3408.

[37]	Tong R, Chen G, Pan D, et al. Highly stretchable and compressible cellulose ionic hydrogels for flexible strain sensors. Biomacromolecules. 2019; 20(5): 2096-2104.

[38]	Wan H, Qin C, Lu A. A flexible, robust cellulose/phytic acid/polyaniline hydrogel for all-in-one supercapacitors and strain sensors. J Mater Chem A. 2022; 10(33): 17279-17287.

[39]	Guo Y, Nakajima T, Mredha MTI, et al. Facile preparation of cellulose hydrogel with Achilles tendon-like super strength through aligning hierarchical fibrous structure. Chem Eng J. 2022; 428: 132040.

[40]	Zhao D, Zhu Y, Cheng W, et al. A dynamic gel with reversible and tunable topological networks and performances. Matter. 2020; 2(2): 390-403.

[41]	Patchan M, Graham JL, Xia Z, et al. Synthesis and properties of regenerated cellulose-based hydrogels with high strength and transparency for potential use as an ocular bandage. Mater Sci Eng C. 2013; 33(5): 3069-3076.

[42]	Zhou S, Guo K, Bukhvalov D, et al. H-bond/ionic coordination switching for fabrication of highly oriented cellulose hydrogels. J Mater Chem A. 2021; 9(9): 5533-5541.

[43]	Jiang G, Wang G, Zhu Y, et al. A scalable bacterial cellulose ionogel for multisensory electronic skin. Research. 2022; 2022: 9814767.

[44]	Zhang M, Chen S, Sheng N, et al. A strategy of tailoring polymorphs and nanostructures to construct self-reinforced nonswelling high-strength bacterial cellulose hydrogels. Nanoscale. 2019; 11(32): 15347-15358.

[45]	Huang J, Huang X, Wu P. One stone for three birds: one-step engineering highly elastic and conductive hydrogel electronics with multilayer MXene as initiator, crosslinker and conductive filler simultaneously. Chem Eng J. 2022; 428: 132515.

[46]	Zhao D, Pang B, Zhu Y, et al. A stiffness-switchable, biomimetic smart material enabled by supramolecular reconfiguration. Adv Mater. 2022; 34(10): 2107857.

[47]	Hua M, Wu S, Ma Y, et al. Strong tough hydrogels via the synergy of freeze-casting and salting out. Nature. 2021; 590(7847): 594-599.

[48]	Wang X, Zheng S, Xiong J, et al. Stretch-induced conductivity enhancement in highly conductive and tough hydrogels. Adv Mater. 2024; 36(25): 2313845.

[49]	Sun X, Mao Y, Yu Z, Yang P, Jiang F. A biomimetic “salting out-alignment-locking” tactic to design strong and tough hydrogel. Adv Mater. 2024; 36(25): 2400084.

[50]	Wu Y, Zhang Y, Wu H, et al. Solvent-exchange-assisted wet annealing: a new strategy for superstrong, tough, stretchable, and anti-fatigu. hydrogels. Adv Mater. 2023; 35(15): 2210624.

[51]	Ye Y, Oguzlu H, Zhu J, et al. Ultrastretchable ionogel with extreme environmental resilience through controlled hydration interactions. Adv Funct Mater. 2022; 33(2): 2209787.

[52]	Luo Z, Li W, Yan J, Sun J. Roles of ionic liquids in adjusting nature of ionogels: a mini review. Adv Funct Mater. 2022; 32(32): 2203988.

[53]	Chen Z, Gui Q, Wang Y. Dynamic chemistry in ionic liquid-based conductor. Green Chem Eng. 2021; 2(4): 346-358.

[54]	Poh WC, Eh AL, Wu W, Guo X, Lee PS. Rapidly photocurable solid-state poly(ionic liquids) ionogels for thermally robust and flexible electrochromic devices. Adv Mater. 2022; 34(51): 2206952.

[55]	He X, Dong J, Zhang X, et al. Self-healing, anti-fatigue, antimicrobial ionic conductive hydrogels based on choline-amino acid polyionic liquids for multi-functional sensors. Chem Eng J. 2022; 435: 135168.

[56]	Liu Z, Wang Y, Ren Y, et al. Poly(ionic liquid) hydrogel-based anti-freezing ionic skin for a soft robotic gripper. Mater Horiz. 2020; 7(3): 919-927.

[57]	Xu Q, Hou M, Wang L, Zhang X, Liu L. Anti-bacterial, anti-freezing starch/ionic liquid/PVA a ion-conductive hydrogel with high performance for multi-stimulation sensitive responsive sensors. Chem Eng J. 2023; 477: 147065.

[58]	Li Q, Yan F, Texter J. Polymerized and colloidal ionic liquids-syntheses and applications. Chem Rev. 2024; 124(7): 3813-3931.

[59]	Bruen D, Delaney C, Diamond D, Florea L. Fluorescent probes for sugar detection. ACS Appl Mater Interfaces. 2018; 10(44): 38431-38437.

[60]	Han Z, Wang P, Lu Y, et al. A versatile hydrogel network-repairing strategy achieved by the covalent-like hydrogen bond interaction. Sci Adv. 2022; 8(2): 1-11.

[61]	Zhu Y, Guo Y, Cao K, et al. A general strategy for synthesizing biomacromolecular ionogel membranes via solvent-induced self-assembly. Nat Synth. 2023; 2(9): 864-872.

[62]	Zong S, Lv H, Liu C, et al. Mussel inspired cu-tannic autocatalytic strategy for rapid self-polymerization of conductive and adhesive hydrogel sensors with extreme environmental tolerance. Chem Eng J. 2023; 465: 142831.

[63]	Ye Y, Jiang F. Highly stretchable, durable, and transient conductive hydrogel for multi-functional sensor and signal transmission applications. Nano Energy. 2022; 99: 107374.

[64]	Liu H, Zhang S, Li Z, et al. Harnessing the wide-range strain sensitivity of bilayered PEDOT:PSS films for wearable health monitoring. Matter. 2021; 4(9): 2886-2901.