Articular Cartilage-Inspired Hybrid Double-Network Hydrogels with a Layered Structure and Low Friction Properties

Huang, Linjun; Li, Zhipeng; Ma, Shuanhong; Ye, Dongdong; Yang, Jia; Qin, G.; Yin, Haiyan; Chen, Qiang

doi:10.1021/acsapm.2c01274

Cited by 6 publications

(3 citation statements)

References 44 publications

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“…Hydrogel, the new functional material, as one of the scaffold materials suitable for tissue engineering, has the advantage of being a promising soft tissue material for articular cartilage replacement due to its high water content, good biocompatibility and surface lubricity. [ 6‐11 ] However, conventional hydrogel materials [ 12‐13 ] ( e.g ., polyvinyl alcohol (PVA), poly(hydroxyethyl methacrylate) (PHEMA) hydrogels, etc .) do not have sufficient mechanical properties and durability to withstand the constant cycles of load and friction.…”

Section: Background and Originality Contentmentioning

confidence: 99%

Ultra‐low Friction and High Load‐Bearing Hydrogel with Tubular Structure Based on Controllable Light‐Induced Dissociation^†

Song

Zhang

et al. 2023

Chin. J. Chem.

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Comprehensive SummaryWith high water content, excellent biocompatibility and lubricating properties, and a microstructure similar to that of the extracellular matrix, hydrogel is becoming one of the most promising materials as a substitute for articular cartilage. However, it is a challenge for hydrogel materials to simultaneously satisfy high loading and low friction. Most hydrogels are brittle, with fracture energies of around 10 J·m−2, as compared with ∼1000 J·m−2 for cartilage. A great deal of effort has been devoted to the synthesis of hydrogels with improved mechanical properties, such as increasing the compactness of the polymer network, introducing dynamic non‐covalent bonds, and increasing the hydrophobicity of the polymer, all at the expense of the lubricating properties of the hydrogel. Herein, we develop a hydrogel material with anisotropic tubular structures where the compactness gradually decreases and eventually disappears from the surface to the subsurface, achieving a balance between lubrication and load‐bearing. The porous layer with hydrophilic carboxyl groups on the surface exhibits extremely low friction (coefficient of friction (COF) ∼0.003, 1 N; COF ∼0.08, 20 N) against the hard steel ball, while the bottom layer acts as an excellent load‐bearing function. What is more, the gradual transition of the tubular structures between the surface and the subsurface ensures the uniform distribution of friction stress between a lubricating and bearing layers, which endows the material with long‐lasting and smooth friction properties. The extraordinary lubricious performance of the hydrogels with anisotropic tubular structure has potential applications in tissue engineering and medical devices.

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Section: Background and Originality Contentmentioning

confidence: 99%

Ultra‐low Friction and High Load‐Bearing Hydrogel with Tubular Structure Based on Controllable Light‐Induced Dissociation^†

Song

Zhang

et al. 2023

Chin. J. Chem.

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“…4 The hybrid agar/poly(acrylamideco-acrylic acid)-Fe 3+ hydrogels reported by Huang et al exhibit high tensile strength (up to 5.12 MPa) and tearing energy (1814 J m À2 ). 26 Despite the satisfactory mechanical performances of these double-crosslinked hydrogels, the possible residual acrylamide monomer caused by an incomplete reaction is carcinogenic and poses a threat to body health. 27 In this work, we used physically crosslinked organohydrogels based on hydrogen bonds between PVA, PHEMA, and glycerin to develop a promising alternative to current materials used in joint replacement surgery.…”

Section: Introductionmentioning

confidence: 99%

“…4 The hybrid agar/poly(acrylamide- co -acrylic acid)-Fe 3+ hydrogels reported by Huang et al exhibit high tensile strength (up to 5.12 MPa) and tearing energy (1814 J m −2 ). 26 Despite the satisfactory mechanical performances of these double-crosslinked hydrogels, the possible residual acrylamide monomer caused by an incomplete reaction is carcinogenic and poses a threat to body health. 27…”

Section: Introductionmentioning

confidence: 99%

Physically cross-linked organo-hydrogels for friction interfaces in joint replacements: design, evaluation and potential clinical applications

Li,

Liang,

Wan

et al. 2023

J. Mater. Chem. B

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Responsiveness of Charged Double Network Hydrogels to Ionic Environment

Lee,

Shrotriya,

Espinosa‐Marzal

2024

Adv Funct Materials

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Charged double network (DN) hydrogels are widely studied for their desirable mechanical strength and tunable properties. In this work, the influence of polymer concentration on microstructure and properties of agarose/polyacrylic acid DN hydrogels is studied. Agarose, the first network, is a brittle biopolymer, while polyacrylic acid (PAAc) is a weak polyelectrolyte. The microstructure, visualized in liquid environment, displays an agarose scaffold coated and interconnected by PAAc, deviating from the common assumption of an entangled double network. Importantly, the charging of PAAc in the hydrogel is regulated not only by the pH and weak polyelectrolyte effects, but also by the restricted swelling of the double network, and hence, it is an inherent regulation mechanism of charged hydrogels. The interactions between the hydrogel and the ionic environment induce microstructural changes and charging of the double network, impacting surface properties such as topography, stiffness, and adhesion, which are spatially resolved by liquid‐environment atomic force microscopy. The responsiveness of the DN hydrogels significantly depends on both polymer concentrations and ion concentrations. These findings provide insights into the responsive behavior of double network hydrogels and reveal universal mechanisms for charged hydrogels, which can guide the future development of functional soft materials.

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Articular Cartilage-Inspired Hybrid Double-Network Hydrogels with a Layered Structure and Low Friction Properties

Cited by 6 publications

References 44 publications

Ultra‐low Friction and High Load‐Bearing Hydrogel with Tubular Structure Based on Controllable Light‐Induced Dissociation^†

Ultra‐low Friction and High Load‐Bearing Hydrogel with Tubular Structure Based on Controllable Light‐Induced Dissociation^†

Physically cross-linked organo-hydrogels for friction interfaces in joint replacements: design, evaluation and potential clinical applications

Responsiveness of Charged Double Network Hydrogels to Ionic Environment

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Articular Cartilage-Inspired Hybrid Double-Network Hydrogels with a Layered Structure and Low Friction Properties

Cited by 6 publications

References 44 publications

Ultra‐low Friction and High Load‐Bearing Hydrogel with Tubular Structure Based on Controllable Light‐Induced Dissociation†

Ultra‐low Friction and High Load‐Bearing Hydrogel with Tubular Structure Based on Controllable Light‐Induced Dissociation†

Physically cross-linked organo-hydrogels for friction interfaces in joint replacements: design, evaluation and potential clinical applications

Responsiveness of Charged Double Network Hydrogels to Ionic Environment

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Product

Resources

About

Ultra‐low Friction and High Load‐Bearing Hydrogel with Tubular Structure Based on Controllable Light‐Induced Dissociation^†

Ultra‐low Friction and High Load‐Bearing Hydrogel with Tubular Structure Based on Controllable Light‐Induced Dissociation^†