Structuring and Shaping of Mechanically Robust and Functional Hydrogels toward Wearable and Implantable Applications

Wang, Xiao‐Qiao; Xie, An‐Quan; Cao, Pengle; Yang, Jian; Ong, Wei Li; Zhang, Ke‐Qin; Ho, Ghim Wei

doi:10.1002/adma.202309952

Advanced Materials

2024

DOI: 10.1002/adma.202309952

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Structuring and Shaping of Mechanically Robust and Functional Hydrogels toward Wearable and Implantable Applications

Xiao‐Qiao Wang,

An‐Quan Xie,

Pengle Cao

et al.

Abstract: Hydrogels possess unique features such as softness, wetness, responsiveness, and biocompatibility, making them highly suitable for biointegrated applications that have close interactions with living organisms. However, conventional man‐made hydrogels are usually soft and brittle, making them inferior to the mechanically robust biological hydrogels. To ensure reliable and durable operation of biointegrated wearable and implantable devices, mechanical matching and shape adaptivity of hydrogels to tissues and org… Show more

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Cited by 8 publications

References 353 publications

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Humidity‐Resistant Wearable Triboelectric Nanogenerator Utilizing a Bound‐Water‐Rich Zwitterionic Hydrogel With Microphase‐Separated Domains

Ding,

Guo,

Ouyang

et al. 2024

Adv Funct Materials

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Triboelectric nanogenerators (TENGs) represent an effective approach for transforming mechanical energy into electrical power, making them suitable for wearable electronic applications. Hydrogels as TENGs electrodes are common, but their use as direct triboelectric layers remains insufficiently explored. Here, a novel zwitterionic monomer 3‐{1‐[6‐(hydroxymethyl)‐2‐methyl‐3,8‐dioxo‐9‐aza‐4,7‐dioxadodec‐1‐en‐12‐yl]imidazol‐3‐ium‐3‐yl}propane‐1‐sulfonate (VNIPS) is synthesized in combination with acrylic acid (AA) and zwitterionic sulfobetaine methacrylate (SBMA) to create a double‐network zwitterionic hydrogel. The hydrogel is developed using a solvent‐exchange process that facilitated the creation of microphase‐separated domains, notablely increasing its mechanical strength (211.9 kPa, 472.3%), conductivity (0.6 mS cm−1), and anti‐freezing capability (−18.3 °C). In addition, the hydrogel's hydrophilic groups interacted with water molecules, reducing charge loss in humid conditions. When employed as the triboelectric positive layer, the hydrogel‐based TENGs achieved a substantial charge density of 456 µC m−2 and an output power density of 464 mW m−2, while maintaining a steady open‐circuit voltage (Voc) of 97 V, with 92% retention under 80% relative humidity. Moreover, the hydrogel's strong adhesion and biocompatibility make it suitable for wearable applications, such as motion sensing and Morse code communication. This work demonstrates the feasibility of zwitterionic hydrogels as triboelectric materials, providing a new strategy for creating efficient, humidity‐resistant energy harvesters.

show abstract

Humidity‐Resistant Wearable Triboelectric Nanogenerator Utilizing a Bound‐Water‐Rich Zwitterionic Hydrogel With Microphase‐Separated Domains

Ding,

Guo,

Ouyang

et al. 2024

Adv Funct Materials

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show abstract

Scalable Layered Heterogeneous Hydrogel Fibers with Strain‐Induced Crystallization for Tough, Resilient, and Highly Conductive Soft Bioelectronics

Cao,

Wang,

Yang

et al. 2024

Advanced Materials

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The advancement of soft bioelectronics hinges critically on the electromechanical properties of hydrogels. Despite ongoing research into diverse material and structural strategies to enhance these properties, producing hydrogels that are simultaneously tough, resilient, and highly conductive for long‐term, dynamic physiological monitoring remains a formidable challenge. Here, a strategy utilizing scalable layered heterogeneous hydrogel fibers (LHHFs) is introduced that enables synergistic electromechanical modulation of hydrogels. High toughness (1.4 MJ m−3) and resilience (over 92% recovery from 200% strain) of LHHFs are achieved through a damage‐free toughening mechanism that involves dense long‐chain entanglements and reversible strain‐induced crystallization of sodium polyacrylate. The unique symmetrical layered structure of LHHFs, featuring distinct electrical and mechanical functional layers, facilitates the mixing of multi‐walled carbon nanotubes to significantly enhance electrical conductivity (192.7 S m−1) without compromising toughness and resilience. Furthermore, high‐performance LHHF capacitive iontronic strain/pressure sensors and epidermal electrodes are developed, capable of accurately and stably capturing biomechanical and bioelectrical signals from the human body under long‐term, dynamic conditions. The LHHF offers a promising route for developing hydrogels with uniquely integrated electromechanical attributes, advancing practical wearable healthcare applications.

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Stretchable, Self‐Healing, and Bioactive Hydrogel with High‐Functionality N,N′‐bis(acryloyl)cystamine Dynamically Bonded Ag@polydopamine Crosslinkers for Wearable Sensors

Shi,

Li,

Chen

et al. 2024

Advanced Science

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Hydrogels present attractive opportunities as flexible sensors due to their soft nature and tunable physicochemical properties. Despite significant advances, practical application of hydrogel‐based sensor is limited by the lack of general routes to fabricate materials with combination of mechanical, conductive, and biological properties. Here, a multi‐functional hydrogel sensor is reported by in situ polymerizing of acrylamide (AM) with N,N′‐bis(acryloyl)cystamine (BA) dynamic crosslinked silver‐modified polydopamine (PDA) nanoparticles, namely PAM/BA‐Ag@PDA. Compared with traditional polyacrylamide (PAM) hydrogel, the BA‐Ag@PDA nanoparticles provide both high‐functionality crosslinks and multiple interactions within PAM networks, thereby endowing the optimized PAM/BA‐Ag@PDA hydrogel with significantly enhanced tensile/compressive strength (349.80 kPa at 383.57% tensile strain, 263.08 kPa at 90% compressive strain), lower hysteresis (5.2%), improved conductivity (2.51 S m−1) and excellent near‐infrared (NIR) light‐triggered self‐healing ability. As a strain sensor, the PAM/BA‐Ag@PDA hydrogel shows a good sensitivity (gauge factor of 1.86), rapid response time (138 ms), and high stability. Owing to abundant reactive groups in PDA, the PAM/BA‐Ag@PDA hydrogel exhibits inherent tissue adhesiveness and antioxidant, along with a synergistic antibacterial effect by PDA and Ag. Toward practical applications, the PAM/BA‐Ag@PDA hydrogel can conformally adhere to skin and monitor subtle activities and large‐scale movements with excellent reliability, demonstrating its promising applications as wearable sensors for healthcare.

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Structuring and Shaping of Mechanically Robust and Functional Hydrogels toward Wearable and Implantable Applications

Cited by 8 publications

References 353 publications

Humidity‐Resistant Wearable Triboelectric Nanogenerator Utilizing a Bound‐Water‐Rich Zwitterionic Hydrogel With Microphase‐Separated Domains

Humidity‐Resistant Wearable Triboelectric Nanogenerator Utilizing a Bound‐Water‐Rich Zwitterionic Hydrogel With Microphase‐Separated Domains

Scalable Layered Heterogeneous Hydrogel Fibers with Strain‐Induced Crystallization for Tough, Resilient, and Highly Conductive Soft Bioelectronics

Stretchable, Self‐Healing, and Bioactive Hydrogel with High‐Functionality N,N′‐bis(acryloyl)cystamine Dynamically Bonded Ag@polydopamine Crosslinkers for Wearable Sensors

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