An estimation of mechanical propertes of articular cartilage for biphasic finite element analyses

Sakai, Nobuo; Hagihara, Yoshihiro; Hashimoto, Chie; Komori, Mochimitsu; Sawae, Yoshinori; Murakami, Teruo

doi:10.1299/jbse.15-00228

Cited by 6 publications

(2 citation statements)

References 47 publications

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“…It was found that we required viscosity in the solid phase to generate the small peak of the non‐fibre model just after the definite compression. In the analysis of the synovial articular cartilage, the solid phase was represented by a simple elastic model [21]. The large sharp peak of the articular cartilage was represented by the collagen network structure.…”

Section: Discussionmentioning

confidence: 99%

Biomimetic artificial cartilage: fibre‐reinforcement of PVA hydrogel to promote biphasic lubrication mechanism

Sakai

Yarimitsu

Sawae

et al. 2019

Biosurface and Biotribology

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The fibre-reinforced structure in synovial articular cartilage plays an important role in enhancing the fluid load support in the biphasic lubrication mechanism. Poly(vinyl alcohol) (PVA) hydrogel is a potential biomimetic articular cartilage material. In this study, PVA hydrogel was reinforced with PVA fibres to improve its frictional properties. By computational analysis, the position of the PVA fibre layer was examined with a migrating contact condition to reduce the friction coefficient. To improve the fibre reinforcement, a method for fibre placement was developed to retain the initial strain of the fibre in the hydrogel matrix. The experimental results showed that the fibre-reinforced PVA hydrogel with a surface fibre layer had a low friction coefficient of 0.031 in pure water. The fibre-reinforced PVA hydrogel successfully reduced friction coefficient. 2 Materials and methods 2.1 PVA hydrogel properties A PVA hydrogel sheet was prepared by a repeated FT method. PVA powder (Kishida Chemical Co., Ltd., Japan; Poval, 020-63185) was Biosurface and Biotribology

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Section: Discussionmentioning

confidence: 99%

Biomimetic artificial cartilage: fibre‐reinforcement of PVA hydrogel to promote biphasic lubrication mechanism

Sakai

Yarimitsu

Sawae

et al. 2019

Biosurface and Biotribology

Self Cite

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“…The weeping [8] and boosted [9] mechanism were proposed based on the frictional mechanism of hydrogel material in the past. It is well known that the articular cartilage shows the time‐dependent compressive behaviour [10, 11], which was explained by a ‘biphasic model’ [12]. In the biphasic model, the cartilaginous tissue was modelled by the mixed composition of solid and fluid phase.…”

Section: Introductionmentioning

confidence: 99%

Transitional behaviour between biphasic lubrication and soft elastohydrodynamic lubrication of poly(vinyl alcohol) hydrogel using microelectromechanical system pressure sensor

Sakai

Yarimitsu

Sawae

et al. 2018

Biosurface and Biotribology

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The soft hydrogel material is expected for a candidate material as biomimetic artificial cartilage with synergistic functionalities of adaptive multimode lubrication. In boundary lubrication mode of hydrogel material, the biphasic lubrication mechanism cooperatively exerts its functionality. In hydrodynamic lubrication mode, it is preferable that the lubricating surfaces be impermeable to trap the fluid pressure in contact surfaces, whereas the actual biphasic material like a hydrogel is a permeable material with surface porosity. It is indicated that the interstitial fluid pressurisation in the permeable biphasic material can contribute to significant fluid load support under lower sliding speed condition. So, the authors examined how the contrary fluid pressure effect appears in the transition from the boundary lubrication mode to soft elastohydrodynamic lubrication mode. In the experiment, a small pressure sensor was utilised to measure the in-situ fluid pressure in sliding condition. Although the experimental condition of this study was selective, the result showed a possibility of the negative effect of the biphasic surface, in which the permeable surface diminished the hydrodynamic fluid pressure. This means that one should manage and enhance the biphasic lubrication abilities in wide operation range when the hydrogel material was used as a load bearing material.

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Depth and strain rate-dependent mechanical response of chondrocytes in reserve zone cartilage subjected to compressive loading

Kazemi

Williams

2021

Biomech Model Mechanobiol

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An estimation of mechanical propertes of articular cartilage for biphasic finite element analyses

Cited by 6 publications

References 47 publications

Biomimetic artificial cartilage: fibre‐reinforcement of PVA hydrogel to promote biphasic lubrication mechanism

Biomimetic artificial cartilage: fibre‐reinforcement of PVA hydrogel to promote biphasic lubrication mechanism

Transitional behaviour between biphasic lubrication and soft elastohydrodynamic lubrication of poly(vinyl alcohol) hydrogel using microelectromechanical system pressure sensor

Depth and strain rate-dependent mechanical response of chondrocytes in reserve zone cartilage subjected to compressive loading

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