Injectable, Pore‐Forming, Perfusable Double‐Network Hydrogels Resilient to Extreme Biomechanical Stimulations

Taheri, Sareh; Bao, Guangyu; He, Zixin; Mohammadi, Sepideh; Ravanbakhsh, Hossein; Lessard, Larry; Li, Jianyu; Mongeau, Luc

doi:10.1002/advs.202102627

Cited by 31 publications

(42 citation statements)

References 56 publications

(62 reference statements)

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“…Structural characteristics such as porosity and nanoparticles distribution have a major impact on the physical, mechanical, and biological properties of the resulting nanocomposite gels. [54][55][56][57] In all cases, the obtained microgels had an average diameter ranging from 200 to 300 μm (Figure S2, Supporting Information). They were well-dispersed and acquired a well-defined spherical shape.…”

Section: Structural Propertiesmentioning

confidence: 99%

Immunomodulatory Microgels Support Proregenerative Macrophage Activation and Attenuate Fibroblast Collagen Synthesis

Mohammadi

Ravanbakhsh

Taheri

et al. 2022

Adv Healthcare Materials

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Scars composed of fibrous connective tissues are natural consequences of injury upon incisional wound healing in soft tissues. Hydrogels that feature a sustained presentation of immunomodulatory cytokines are known to modulate wound healing. However, existing immunomodulatory hydrogels lack interconnected micropores to promote cell ingrowth. Other limitations include invasive delivery procedures and harsh synthesis conditions that are incompatible with drug molecules. Here, hybrid nanocomposite microgels containing interleukin‐10 (IL‐10) are reported to modulate tissue macrophage phenotype during wound healing. The intercalation of laponite nanoparticles in the polymer network yields microgels with tissue‐mimetic elasticity (Young's modulus in the range of 2–6 kPa) and allows the sustained release of IL‐10 to promote the differentiation of macrophages toward proregenerative phenotypes. The porous interstitial spaces between microgels promote fibroblast proliferation and fast trafficking (an average speed of ≈14.4 µm h−1). The incorporation of hyaluronic acid further enhances macrophage infiltration. The coculture of macrophages and fibroblasts treated with transforming growth factor‐beta 1 resulted in a twofold reduction in collagen‐I production for microgels releasing IL‐10 compared to the IL‐10 free group. The new microgels show potential toward regenerative healing by harnessing the antifibrotic behavior of host macrophages.

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Section: Structural Propertiesmentioning

confidence: 99%

Immunomodulatory Microgels Support Proregenerative Macrophage Activation and Attenuate Fibroblast Collagen Synthesis

Mohammadi

Ravanbakhsh

Taheri

et al. 2022

Adv Healthcare Materials

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“…Macroporous structures are often vulnerable to rupture but could be circumvented by a tough and pore-insensitive matrix 25 , 26 . To test this point, we perform pure-shear tests to characterize the toughness and pore sensitivity of LIMB.…”

Section: Resultsmentioning

confidence: 99%

“…These properties exceed soft tissues/organs such as cartilage and blood vessels, as well as the fully swollen tough adhesive in prior works 12 , 27 , 28 . The mechanical performance of the xerogel is attributed to its double-network design, where hydrogen bonds dissipate substantial energy and resist swelling 21 , 25 .…”

Section: Resultsmentioning

confidence: 99%

Liquid-infused microstructured bioadhesives halt non-compressible hemorrhage

et al. 2022

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Non-compressible hemorrhage is an unmet clinical challenge that accounts for high mortality in trauma. Rapid pressurized blood flows under hemorrhage impair the function and integrity of hemostatic agents and the adhesion of bioadhesive sealants. Here, we report the design and performance of bioinspired microstructured bioadhesives, formed with a macroporous tough xerogel infused with functional liquids. The xerogel can rapidly absorb interfacial fluids such as whole blood and promote blood clotting, while the infused liquids facilitate interfacial bonding, sealing, and antibacterial function. Their synergy enables the bioadhesives to form tough adhesion on ex vivo human and porcine tissues and diverse engineered surfaces without the need for compression, as well as on-demand instant removal and storage stability. We demonstrate a significantly improved hemostatic efficacy and biocompatibility in rats and pigs compared to non-structured counterparts and commercial products. This work opens new avenues for the development of bioadhesives and hemostatic sealants.

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“…Hydrated and ionic materials such as deformable and tough ionic hydrogels have been regarded as one of the most ideal stretchable materials for electronic applications because of their excellent biocompatibility, − high stretchability, high electrical conductivity, and tunable mechanical properties (e.g., toughness, stretchability, and elasticity). , Thus, ionic hydrogels have been applied to developing a variety of stretchable sensors and electronics, including pressure sensors, − strain sensors, touchpads, , robotic skins, and TENGs . Because ionic hydrogels are solid-like, soft, highly stretchable, transparent, and biocompatible, ionic hydrogel-based TENGs show great potential as the power source for wearable electronics and soft robotics.…”

Section: Introductionmentioning

confidence: 99%

An Ionic Hydrogel-Based Antifreezing Triboelectric Nanogenerator

Ying

Zuo

Wan

et al. 2022

ACS Appl. Electron. Mater.

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The rapid development of stretchable electronics and soft robotics requires a sustainable power source that can match their mechanical stretchability in various working environments. Ionic hydrogel-based soft triboelectric nanogenerators (TENGs) show great promise for those application scenarios. However, ionic hydrogel-based TENGs suffer from the freezing issue under subzero temperatures. In this study, a low-cost, highly stretchable, and antifreezing ionic triboelectric nanogenerator (iTENG) is designed to involve a dielectric elastomer and a freeze-tolerant ionic hydrogel as the electrification layer and the electrode, respectively. The iTENG design achieves a unique combination of merits such as robust hydrogel–elastomer bonding, high stretchability (300%), and excellent tolerance of extremely low temperature (down to −53 °C). Because of the reliable interfacial bonding, the iTENG shows a good mechanical durability under different stretching conditions. The iTENG can harvest mechanical energies from various human motions and can also serve as a self-powered wearable sensor in both regular and extremely cold environments. The stretchable iTENG overcomes the strain-induced performance degradation of existing stretchable materials with percolated conductive fillers and the water freezing-induced degradation of conductive ionic hydrogels, providing a feasible design of stretchable and sustainable power sources for stretchable electronics and soft robotics operating in harsh environments.

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Injectable, Pore‐Forming, Perfusable Double‐Network Hydrogels Resilient to Extreme Biomechanical Stimulations

Cited by 31 publications

References 56 publications

Immunomodulatory Microgels Support Proregenerative Macrophage Activation and Attenuate Fibroblast Collagen Synthesis

Immunomodulatory Microgels Support Proregenerative Macrophage Activation and Attenuate Fibroblast Collagen Synthesis

Liquid-infused microstructured bioadhesives halt non-compressible hemorrhage

An Ionic Hydrogel-Based Antifreezing Triboelectric Nanogenerator

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