The effects of focal articular defects on cartilage contact mechanics

Gratz, Kenneth R.; Wong, Benjamin L.; Bae, Won C.; Sah, Robert L.

doi:10.1002/jor.20762

Cited by 78 publications

(73 citation statements)

References 43 publications

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“…Moreover, in a high number of associated operations and complex cases, the treatment could be considered a salvage procedure. With this in consideration, our results seem to be in line with those previously reported in the literature with other techniques-with good clinical and MRI findings at 2 years and a slower improvement in patellofemoral lesions, as well as in less active and older patients [4][5][6]8,18,25 -but the separate evaluation reduces the number of patients in each subgroup, thus hampering a proper, deeper analysis and comparison with the literature.…”

Section: Discussionsupporting

confidence: 92%

Novel Nano-composite Multilayered Biomaterial for Osteochondral Regeneration

et al. 2011

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Section: Discussionsupporting

confidence: 92%

Novel Nano-composite Multilayered Biomaterial for Osteochondral Regeneration

et al. 2011

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“…5), are instrumental to predict the protruding of implant into joint cavity during dynamic movements of the knee. The macroscopic tissue deformations surrounding the defect were similar to that reported previously (Braman et al 2005;Gratz et al 2009). Our results agree with the previous biomechanical studies, which demonstrated that the untreated defects result in increased contact pressures (Brown et al 1991;Guettler et al 2004).…”

Section: Discussionsupporting

confidence: 81%

Time-dependent behavior of cartilage surrounding a metal implant for full-thickness cartilage defects of various sizes: a finite element study

Manda

Eriksson

2011

Biomech Model Mechanobiol

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Recently, physiological and biomechanical studies on animal models with metal implants filling full-thickness cartilage defects have resulted in good clinical outcomes. The knowledge of the time-dependent macroscopic behavior of cartilage surrounding the metal implant is essential for understanding the joint function after treating such defects. We developed a model to investigate the in vivo time-dependent behavior of the tibiofemoral cartilages surrounding the metal implant, when the joint is subjected to an axial load for various defect sizes. Results show that time-dependent effects on cartilage behavior are significant, and can be simulated. These effects should be considered when evaluating the results from an implant. In particular, the depth into the cartilage where an implant is positioned and the mechanical sealing due to solidification of the poroelastic material need a time aspect. We found the maximal deformations, contact pressures and contact forces in the joint with time for the implant positioned in flush and sunk 0.3 mm into the cartilage. The latter position gives the better joint performance. The results after 60 s may be treated as the primary results, reflecting the effect of accumulation in the joint due to repeated short-time loadings. The wedge-shaped implant showed beneficial in providing mechanical sealing of cartilages surrounding the implant with time.

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“…13 Given the substantial mechanical forces that occur during simple activities such as walking, 14,15 any construct intended to fill a cartilage defect should have the ability to carry mechanical loads similar to the native tissue and to elicit a beneficial host response. To achieve these goals we developed a nonbiodegradable porous hydrogel (polyvinyl alcohol [PVA]) scaffold, the composition of which is stable over time and whose mechanical properties can be varied by changing the PVA polymer content.…”

mentioning

confidence: 99%

A Novel Macroporous Polyvinyl Alcohol Scaffold Promotes Chondrocyte Migration and Interface Formation in anIn VitroCartilage Defect Model

Wanivenhaus

Chen

et al. 2012

Tissue Engineering Part A

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Scaffold-cartilage integration is critical for the clinical success of a scaffold used for the repair of a focal cartilage defect. In this study, a macroporous polyvinyl alcohol (PVA) scaffold was found to facilitate chondrocyte infiltration and interfacial matrix formation in a juvenile bovine in vitro cartilage defect model. These results were found to depend on the press-fit between the scaffold and the cartilage, pretreatment of the cartilage with collagenase prior to scaffold insertion, and chondrocyte preseeding of the scaffold. Infiltrated and preseeded chondrocytes in the scaffold survived for 6 weeks in culture and resulted in sufficient matrix at the interface to significantly increase the interface shear strength 30-fold that compared favorably with the interface shear strength of cartilage-cartilage constructs. The ability of this macroporous PVA scaffold to form a stable interface with articular cartilage demonstrates the potential use of this scaffold design for focal cartilage defect repair.

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The effects of focal articular defects on cartilage contact mechanics

Cited by 78 publications

References 43 publications

Novel Nano-composite Multilayered Biomaterial for Osteochondral Regeneration

Novel Nano-composite Multilayered Biomaterial for Osteochondral Regeneration

Time-dependent behavior of cartilage surrounding a metal implant for full-thickness cartilage defects of various sizes: a finite element study

A Novel Macroporous Polyvinyl Alcohol Scaffold Promotes Chondrocyte Migration and Interface Formation in anIn VitroCartilage Defect Model

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