Dual Physical Crosslinking Strategy to Construct Moldable Hydrogels with Ultrahigh Strength and Toughness

A dual physical crosslinking (DPC) strategy is used to construct moldable hydrogels with ultrahigh strength and toughness. First, polyelectrolyte complex (PEC) hydrogels are prepared through the in situ polymerization of acrylic acid monomers in the concentrated chitosan (Ch) solutions. Subsequently, Ag+ ions are introduced into the PEC hydrogels to form coordination bonds between NH2 and COOH groups. High‐density electrostatic interaction and coordination bonds endow the DPC hydrogels with high strength and toughness. The mechanical properties of the DPC hydrogels strongly depend on the weight ratio of Ch to poly(acrylic acid) and the loading concentration of Ag+ ions. When the loading concentration of Ag+ ions is in the range of 1.0–1.5 mol L−1, DPC 0.10–0.25 hydrogels display the maximum tensile strength (24.0 MPa) and toughness (84.7 MJ m−3) with a strain of more than 600%. Specially, the DPC hydrogels display an excellent moldable behavior due to the reversible properties of the electrostatic interaction and coordination bonds. The DPC strategy can also be applied in various other systems and opens a new avenue to fabricate hydrogels with outstanding mechanical properties and antibacterial activities.

[1]  J. Gong,et al.  Inorganic/Organic Double‐Network Gels Containing Ionic Liquids , 2017, Advanced materials.

[2]  B Kollbe Ahn,et al.  Toughening elastomers using mussel-inspired iron-catechol complexes , 2017, Science.

[3]  K. Winey Designing tougher elastomers with ionomers , 2017, Science.

[4]  Liming Bian,et al.  Self‐Assembled Injectable Nanocomposite Hydrogels Stabilized by Bisphosphonate‐Magnesium (Mg2+) Coordination Regulates the Differentiation of Encapsulated Stem Cells via Dual Crosslinking , 2017 .

[5]  Chunyu Chang,et al.  Dual Physically Cross-Linked Nanocomposite Hydrogels Reinforced by Tunicate Cellulose Nanocrystals with High Toughness and Good Self-Recoverability. , 2017, ACS applied materials & interfaces.

[6]  Honglei Guo,et al.  Tough polyion-complex hydrogels from soft to stiff controlled by monomer structure , 2017 .

[7]  Xuanhe Zhao,et al.  Hydraulic hydrogel actuators and robots optically and sonically camouflaged in water , 2017, Nature Communications.

[8]  R. Weiss,et al.  Fabrication of Tough Hydrogels from Chemically Cross-Linked Multiple Neutral Networks , 2016 .

[9]  Lina Zhang,et al.  Ultra‐Stretchable and Force‐Sensitive Hydrogels Reinforced with Chitosan Microspheres Embedded in Polymer Networks , 2016, Advanced materials.

[10]  Fei Yang,et al.  A Universal Soaking Strategy to Convert Composite Hydrogels into Extremely Tough and Rapidly Recoverable Double‐Network Hydrogels , 2016, Advanced materials.

[11]  Wuyi Zhou,et al.  Dual Physically Cross-Linked Hydrogels with High Stretchability, Toughness, and Good Self-Recoverability , 2016 .

[12]  Qi Zhang,et al.  Alginate Hydrogel: A Shapeable and Versatile Platform for in Situ Preparation of Metal-Organic Framework-Polymer Composites. , 2016, ACS applied materials & interfaces.

[13]  Lina Zhang,et al.  Quaternized Chitosan/Poly(acrylic acid) Polyelectrolyte Complex Hydrogels with Tough, Self-Recovery, and Tunable Mechanical Properties , 2016 .

[14]  Mario Miscuglio,et al.  Highly Elastic and Conductive Human‐Based Protein Hybrid Hydrogels , 2016, Advanced materials.

[15]  Lujie Cao,et al.  Multistimuli-Responsive, Moldable Supramolecular Hydrogels Cross-Linked by Ultrafast Complexation of Metal Ions and Biopolymers. , 2015, Angewandte Chemie.

[16]  Wei Wang,et al.  A Mechanically Strong, Highly Stable, Thermoplastic, and Self‐Healable Supramolecular Polymer Hydrogel , 2015, Advanced materials.

[17]  Francesco Stellacci,et al.  Antibacterial activity of silver nanoparticles: A surface science insight , 2015 .

[18]  Liang-Yin Chu,et al.  Poly(N‐isopropylacrylamide)‐Clay Nanocomposite Hydrogels with Responsive Bending Property as Temperature‐Controlled Manipulators , 2015 .

[19]  Honglei Guo,et al.  Oppositely Charged Polyelectrolytes Form Tough, Self‐Healing, and Rebuildable Hydrogels , 2015, Advanced materials.

[20]  Jie Zheng,et al.  A Novel Design Strategy for Fully Physically Linked Double Network Hydrogels with Tough, Fatigue Resistant, and Self‐Healing Properties , 2015 .

[21]  Xiaolong Wang,et al.  Molecularly Engineered Dual‐Crosslinked Hydrogel with Ultrahigh Mechanical Strength, Toughness, and Good Self‐Recovery , 2015, Advanced materials.

[22]  Lina Zhang,et al.  Construction of cellulose based ZnO nanocomposite films with antibacterial properties through one-step coagulation. , 2015, ACS applied materials & interfaces.

[23]  Wenguang Liu,et al.  Dipole–Dipole and H‐Bonding Interactions Significantly Enhance the Multifaceted Mechanical Properties of Thermoresponsive Shape Memory Hydrogels , 2015 .

[24]  Hermann Ehrlich,et al.  Chitin and chitosan in selected biomedical applications , 2014 .

[25]  Xiaowen Shi,et al.  Emerging chitin and chitosan nanofibrous materials for biomedical applications. , 2014, Nanoscale.

[26]  Bruce P. Lee,et al.  Novel Hydrogel Actuator Inspired by Reversible Mussel Adhesive Protein Chemistry , 2014, Advanced materials.

[27]  Zhigang Suo,et al.  Strengthening alginate/polyacrylamide hydrogels using various multivalent cations. , 2013, ACS applied materials & interfaces.

[28]  Jian Ping Gong,et al.  Physical hydrogels composed of polyampholytes demonstrate high toughness and viscoelasticity. , 2013, Nature materials.

[29]  Hong Dong,et al.  Cation-induced hydrogels of cellulose nanofibrils with tunable moduli. , 2013, Biomacromolecules.

[30]  Qiuming Wang,et al.  A Robust, One‐Pot Synthesis of Highly Mechanical and Recoverable Double Network Hydrogels Using Thermoreversible Sol‐Gel Polysaccharide , 2013, Advanced materials.

[31]  E. Palleau,et al.  Reversible patterning and actuation of hydrogels by electrically assisted ionoprinting , 2013, Nature Communications.

[32]  C. Roland,et al.  Strength Enhancement in Miscible Blends of Butyl Rubber and Polyisobutylene , 2013 .

[33]  Matthias Epple,et al.  Silver as antibacterial agent: ion, nanoparticle, and metal. , 2013, Angewandte Chemie.

[34]  Z. Suo,et al.  Highly stretchable and tough hydrogels , 2012, Nature.

[35]  T. Kurokawa,et al.  Structure Optimization and Mechanical Model for Microgel-Reinforced Hydrogels with High Strength and Toughness , 2012 .

[36]  Jian Ping Gong,et al.  Why are double network hydrogels so tough , 2010 .

[37]  Na Wang,et al.  Nanostructured Sheets of TiO Nanobelts for Gas Sensing and Antibacterial Applications , 2008 .

[38]  T. Kurokawa,et al.  Double‐Network Hydrogels with Extremely High Mechanical Strength , 2003 .

[39]  Miyajima,et al.  Analysis of Complexation Equilibria of Polyacrylic Acid by a Donnan-Based Concept , 1997, Journal of colloid and interface science.

[40]  T. Miyajima,et al.  Metal complexation of negatively charged polymers: Evaluation of the electrostatic effect on the complexation equilibria , 1991 .

[41]  P. Desideri,et al.  Chromatographic behaviour of inorganic ions on chitosan thin layers and columns , 1978 .