Catch bond-inspired hydrogels with repeatable and loading rate-sensitive specific adhesion
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Hao Wang | Zuoying Yuan | Anqi Jiang | Jianyong Huang | Pengfei Wei | Bo Zhao | Xing Su | Zhuoling Tian | Xiaocen Duan | Xiaozhi Liu | Zhuo Wan
[1] Shuqiang Huang,et al. In situ fused granular hydrogels with ultrastretchability, strong adhesion, and mutli-bioactivities for efficient chronic wound care , 2022, Chemical Engineering Journal.
[2] Baolin Guo,et al. Hydrogel adhesives for generalized wound treatment: Design and applications , 2022, Journal of Polymer Science.
[3] Yue Zhao,et al. Supramolecular Adhesive Hydrogels for Tissue Engineering Applications. , 2022, Chemical reviews.
[4] Zuoying Yuan,et al. Hydrogel-based patient-friendly photodynamic therapy of oral potentially malignant disorders. , 2022, Biomaterials.
[5] J. Gong,et al. Bioinspired Underwater Adhesives , 2021, Advanced materials.
[6] Lan Li,et al. Hydrogel tapes for fault-tolerant strong wet adhesion , 2021, Nature Communications.
[7] Jianyu Li,et al. Tissue adhesion with tough hydrogels: Experiments and modeling , 2021 .
[8] Wenguang Liu,et al. Recent advances in wet adhesives: Adhesion mechanism, design principle and applications , 2021 .
[9] Jiayue Shi,et al. PEG-based thermosensitive and biodegradable hydrogels. , 2021, Acta biomaterialia.
[10] Baolin Guo,et al. Dual-Dynamic-Bond Cross-Linked Antibacterial Adhesive Hydrogel Sealants with On-Demand Removability for Post-Wound-Closure and Infected Wound Healing. , 2021, ACS nano.
[11] D. Mooney,et al. Advanced bandages for diabetic wound healing , 2021, Science Translational Medicine.
[12] Junyu Chen,et al. A mussel-inspired film for adhesion to wet buccal tissue and efficient buccal drug delivery , 2021, Nature Communications.
[13] Xuesi Chen,et al. Green Tea Derivative Driven Smart Hydrogels with Desired Functions for Chronic Diabetic Wound Treatment , 2021, Advanced Functional Materials.
[14] D. Mooney,et al. Polymeric Tissue Adhesives. , 2021, Chemical reviews.
[15] S. Keten,et al. Self-strengthening biphasic nanoparticle assemblies with intrinsic catch bonds , 2021, Nature communications.
[16] M. Murrell,et al. Detailed Balance Broken by Catch Bond Kinetics Enables Mechanical‐Adaptation in Active Materials , 2020, Advanced functional materials.
[17] Liang Xu,et al. Ctenophore-inspired hydrogels for efficient and repeatable underwater specific adhesion to biotic surfaces , 2020, Materials Horizons.
[18] Z. Suo,et al. Strength and toughness of adhesion of soft materials measured in lap shear , 2020 .
[19] Xuanhe Zhao,et al. Instant tough bioadhesive with triggerable benign detachment , 2020, Proceedings of the National Academy of Sciences.
[20] Xiong Lu,et al. Mussel‐Inspired Hydrogels for Self‐Adhesive Bioelectronics , 2020, Advanced Functional Materials.
[21] H. Gaub,et al. Streptavidin/biotin: Tethering geometry defines unbinding mechanics , 2020, Science Advances.
[22] Baolin Guo,et al. Physical Double‐Network Hydrogel Adhesives with Rapid Shape Adaptability, Fast Self‐Healing, Antioxidant and NIR/pH Stimulus‐Responsiveness for Multidrug‐Resistant Bacterial Infection and Removable Wound Dressing , 2020, Advanced Functional Materials.
[23] Wenxin Wang,et al. Wound dressing change facilitated by spraying zinc ions , 2020 .
[24] B. Lei,et al. Bioactive Antiinflammatory Antibacterial Antioxidative Silicon-Based Nanofibrous Dressing Enables Cutaneous Tumor Photothermo-Chemo Therapy and Infection-Induced Wound Healing. , 2020, ACS nano.
[25] Zhipeng Gu,et al. Advances and Impact of Antioxidant Hydrogel in Chronic Wound Healing , 2020, Advanced healthcare materials.
[26] Tengfei Zhang,et al. Catechol-functionalized hydrogels: biomimetic design, adhesion mechanism, and biomedical applications. , 2020, Chemical Society reviews.
[27] Shutao Wang,et al. A reversible underwater glue based on photo- and thermo-responsive dynamic covalent bonds , 2020, Materials Horizons.
[28] M. Humayun,et al. Reversible Bioadhesives Using Tannic Acid Primed Thermally‐Responsive Polymers , 2019, Advanced Functional Materials.
[29] Xuanhe Zhao,et al. Dry double-sided tape for adhesion of wet tissues and devices , 2019, Nature.
[30] E. Shirzaei Sani,et al. Local Immunomodulation Using an Adhesive Hydrogel Loaded with miRNA-Laden Nanoparticles Promotes Wound Healing. , 2019, Small.
[31] Qian Sun,et al. M1 macrophage mediated increased reactive oxygen species (ROS) influence wound healing via the MAPK signaling in vitro and in vivo , 2019, Toxicology and applied pharmacology.
[32] S. Keten,et al. A Simple Mechanical Model for Synthetic Catch Bonds , 2019, Matter.
[33] Xingxing Zhang,et al. Engineering Bioactive Self-Healing Antibacterial Exosomes Hydrogel for Promoting Chronic Diabetic Wound Healing and Complete Skin Regeneration , 2019, Theranostics.
[34] Wenguang Liu,et al. Poly(N-acryloyl glycinamide): a fascinating polymer that exhibits a range of properties from UCST to high-strength hydrogels. , 2018, Chemical communications.
[35] Georgette B. Salieb-Beugelaar,et al. PDMS with designer functionalities—Properties, modifications strategies, and applications , 2018, Progress in Polymer Science.
[36] Malcolm Xing,et al. Hydrogen bonds autonomously powered gelatin methacrylate hydrogels with super-elasticity, self-heal and underwater self-adhesion for sutureless skin and stomach surgery and E-skin. , 2018, Biomaterials.
[37] M. Mrksich,et al. Potent laminin-inspired antioxidant regenerative dressing accelerates wound healing in diabetes , 2018, Proceedings of the National Academy of Sciences.
[38] Zhigang Suo,et al. Topological Adhesion of Wet Materials , 2018, Advanced materials.
[39] Bo Wang,et al. Mussel-Inspired Cellulose Nanocomposite Tough Hydrogels with Synergistic Self-Healing, Adhesive, and Strain-Sensitive Properties , 2018 .
[40] Pingao Huang,et al. Quadruple H-Bonding Cross-Linked Supramolecular Polymeric Materials as Substrates for Stretchable, Antitearing, and Self-Healable Thin Film Electrodes. , 2018, Journal of the American Chemical Society.
[41] A. Khademhosseini,et al. Polyphenol uses in biomaterials engineering. , 2018, Biomaterials.
[42] D J Mooney,et al. Tough adhesives for diverse wet surfaces , 2017, Science.
[43] Fei Gao,et al. A High Strength Self-Healable Antibacterial and Anti-Inflammatory Supramolecular Polymer Hydrogel. , 2017, Macromolecular rapid communications.
[44] Youhong Tang,et al. Mussel-Inspired Adhesive and Tough Hydrogel Based on Nanoclay Confined Dopamine Polymerization. , 2017, ACS nano.
[45] C. Abell,et al. Biomimetic Supramolecular Polymer Networks Exhibiting both Toughness and Self‐Recovery , 2017, Advanced materials.
[46] A. Balazs,et al. Tuning the Mechanical Properties of Polymer-Grafted Nanoparticle Networks through the Use of Biomimetic Catch Bonds , 2016 .
[47] Ali Khademhosseini,et al. Photocrosslinkable Gelatin Hydrogel for Epidermal Tissue Engineering , 2016, Advanced healthcare materials.
[48] Wei Wang,et al. A Mechanically Strong, Highly Stable, Thermoplastic, and Self‐Healable Supramolecular Polymer Hydrogel , 2015, Advanced materials.
[49] T. Dierks,et al. Catch bond interaction between cell-surface sulfatase Sulf1 and glycosaminoglycans. , 2015, Biophysical journal.
[50] V. Vasioukhin. Faculty Opinions recommendation of Cell adhesion. The minimal cadherin-catenin complex binds to actin filaments under force. , 2014 .
[51] Niels Volkmann,et al. The minimal cadherin-catenin complex binds to actin filaments under force , 2014, Science.
[52] Michael Hinczewski,et al. Plasticity of hydrogen bond networks regulates mechanochemistry of cell adhesion complexes , 2014, Proceedings of the National Academy of Sciences.
[53] Hui Li,et al. Resolving the molecular mechanism of cadherin catch bond formation , 2014, Nature Communications.
[54] Cheng Zhu,et al. Accumulation of Dynamic Catch Bonds between TCR and Agonist Peptide-MHC Triggers T Cell Signaling , 2014, Cell.
[55] Jian Ping Gong,et al. Physical hydrogels composed of polyampholytes demonstrate high toughness and viscoelasticity. , 2013, Nature materials.
[56] L. McIntire,et al. Actin depolymerization under force is governed by lysine 113:glutamic acid 195-mediated catch-slip bonds , 2013, Proceedings of the National Academy of Sciences.
[57] Jing Fang,et al. Cell adhesion nucleation regulated by substrate stiffness: a Monte Carlo study. , 2012, Journal of biomechanics.
[58] Jing Fang,et al. Influence of substrate stiffness on cell-substrate interfacial adhesion and spreading: a mechano-chemical coupling model. , 2011, Journal of colloid and interface science.
[59] Andrés J. García,et al. Demonstration of catch bonds between an integrin and its ligand , 2009, The Journal of cell biology.
[60] Q. Cheng,et al. Computational modeling for cell spreading on a substrate mediated by specific interactions, long-range recruiting interactions, and diffusion of binders. , 2009, Physical review. E, Statistical, nonlinear, and soft matter physics.
[61] K. V. Van Vliet,et al. Extending Bell's model: how force transducer stiffness alters measured unbinding forces and kinetics of molecular complexes. , 2008, Biophysical journal.
[62] Klaus Schulten,et al. How the headpiece hinge angle is opened: new insights into the dynamics of integrin activation , 2006, The Journal of cell biology.
[63] E. Evans. Probing the relation between force--lifetime--and chemistry in single molecular bonds. , 2001, Annual review of biophysics and biomolecular structure.
[64] G. I. Bell. Models for the specific adhesion of cells to cells. , 1978, Science.
[65] L. Weiss,et al. Cell adhesion. , 1978, International dental journal.
[66] Zuoying Yuan,et al. A hydra tentacle-inspired hydrogel with underwater ultra-stretchability for adhering adipose surfaces , 2022 .