Juha Töyräs scite author profile

It has been suggested that orientational changes in the collagen network of articular cartilage account for the depthwise T 2 anisotropy of MRI through the magic angle effect. To investigate the relationship between laminar T 2 appearance and collagen organization (anisotropy), bovine osteochondral plugs (N ‫؍‬ 9) were T 2 mapped at 9.4T with cartilage surface normal to the static magnetic field. Collagen fibril arrangement of the same samples was studied with polarized light microscopy, a quantitative technique for probing collagen organization by analyzing its ability to rotate plane polarized light, i.e.

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Comparison of the equilibrium response of articular cartilage in unconfined compression, confined compression and indentation

Korhonen

Laasanen

Töyräs

et al. 2002

Journal of Biomechanics

381

285

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Fibril reinforced poroelastic model predicts specifically mechanical behavior of normal, proteoglycan depleted and collagen degraded articular cartilage

Korhonen

Laasanen

Töyräs

et al. 2003

Journal of Biomechanics

246

247

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Collagen network primarily controls Poisson's ratio of bovine articular cartilage in compression

et al. 2006

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ABSTRACT:The equilibrium Young's modulus of articular cartilage is known to be primarily determined by proteoglycans (PGs). However, the relation between the Poisson's ratio and the composition and structure of articular cartilage is more unclear. In this study, we determined Young's modulus and Poisson's ratio of bovine articular cartilage in unconfined compression. Subsequently, the same samples, taken from bovine knee (femoral, patellar and tibial cartilage) and shoulder (humeral cartilage) joints, were processed for quantitative microscopic analysis of PGs, collagen content, and collagen architecture. The Young's modulus, Poisson's ratio, PG content (estimated with optical density measurements), collagen content, and birefringence showed significant topographical variation (p < 0.05) among the test sites. Experimentally the Young's modulus was strongly determined by the tissue PG content (r ¼ 0.86, p < 0.05). Poisson's ratio revealed a significant negative linear correlation (r ¼ À0.59, p < 0.05) with the collagen content, as assessed by the Fourier transform infrared imaging. Finite element analyses, conducted using a fibril reinforced biphasic model, indicated that the mechanical properties of the collagen network strongly affected the Poisson's ratio. We conclude that Poisson's ratio of articular cartilage is primarily controlled by the content and organization of the collagen network. ß

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Spatial assessment of articular cartilage proteoglycans with Gd‐DTPA‐enhanced T₁ imaging

Nieminen

Rieppo

Silvennoinen³

et al. 2002

Magnetic Resonance in Med

145

119

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In Gd-DTPA-enhanced T 1 imaging of articular cartilage, the MRI contrast agent with two negative charges is understood to accumulate in tissue inversely to the negative charge of cartilage glycosaminoglycans (GAGs) of proteoglycans (PGs), and this leads to a decrease in the T 1 relaxation time of tissue relative to the charge in tissue. By assuming a constant relaxivity for Gd-DTPA in cartilage, it has further been hypothesized that the contrast agent concentration in tissue could be estimated from consecutive T 1 measurements in the absence or presence of the contrast agent. The spatial sensitivity of the technique was examined at 9.4 T in normal and PG-depleted bovine patellar cartilage samples. As a reference, spatial PG concentration was assessed with digital densitometry from sa-

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Quantitative MR microscopy of enzymatically degraded articular cartilage

et al. 2000

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T2 relaxation time mapping reveals age- and species-related diversity of collagen network architecture in articular cartilage

Nissi

Rieppo

Töyräs

et al. 2006

Osteoarthritis and Cartilage

102

104

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According to the present results, T(2) mapping is capable of detecting histological differences in cartilage collagen architecture among species, likely to be strongly related to the differences in maturation of the tissue. This diversity in the MRI appearance of healthy articular cartilage should also be recognized when using juvenile animal tissue as a model for mature human cartilage in experimental studies.

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Structure-Function Relationships in Enzymatically Modified Articular Cartilage

Rieppo¹,

Töyräs

Nieminen³

et al. 2003

Cells Tissues Organs

117

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The present study is aimed at revealing structure-function relationships of bovine patellar articular cartilage. Collagenase, chondroitinase ABC and elastase were used for controlled and selective enzymatic modifications of cartilage structure, composition and functional properties. The effects of the enzymatic degradations were quantitatively evaluated using quantitative polarized light microscopy, digital densitometry of safranin O-stained sections as well as with biochemical and biomechanical techniques. The parameters related to tissue composition and structure were correlated with the indentation stiffness of cartilage. In general, tissue alterations after enzymatic digestions were restricted to the superficial cartilage. All enzymatic degradations induced superficial proteoglycan (PG) depletion. Collagenase also induced detectable superficial collagen damage, though without causing cartilage fibrillation or tissue swelling. Quantitative microscopic techniques were more sensitive than biochemical methods in detecting these changes. The Young’s modulus of cartilage decreased after enzymatic treatments indicating significant softening of the tissue. The PG concentration of the superficial zone proved to be the major determinant of the Young’s modulus (r² = 0.767, n = 72, p < 0.001). Results of the present study indicate that specific enzymatic degradations of the tissue PGs and collagen can provide reproducible experimental models to clarify the structure-function relationships of cartilage. Effects of these models mimic the changes observed in early osteoarthrosis. Biomechanical testing and quantitative microscopic techniques proved to be powerful tools for detecting the superficial structural and compositional changes while the biochemical measurements on the whole uncalcified cartilage were less sensitive.

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Juha Töyräs

T₂ relaxation reveals spatial collagen architecture in articular cartilage: A comparative quantitative MRI and polarized light microscopic study

Comparison of the equilibrium response of articular cartilage in unconfined compression, confined compression and indentation

Fibril reinforced poroelastic model predicts specifically mechanical behavior of normal, proteoglycan depleted and collagen degraded articular cartilage

Collagen network primarily controls Poisson's ratio of bovine articular cartilage in compression

Spatial assessment of articular cartilage proteoglycans with Gd‐DTPA‐enhanced T₁ imaging

Quantitative MR microscopy of enzymatically degraded articular cartilage

T2 relaxation time mapping reveals age- and species-related diversity of collagen network architecture in articular cartilage

Structure-Function Relationships in Enzymatically Modified Articular Cartilage

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Juha Töyräs

T2 relaxation reveals spatial collagen architecture in articular cartilage: A comparative quantitative MRI and polarized light microscopic study

Comparison of the equilibrium response of articular cartilage in unconfined compression, confined compression and indentation

Fibril reinforced poroelastic model predicts specifically mechanical behavior of normal, proteoglycan depleted and collagen degraded articular cartilage

Collagen network primarily controls Poisson's ratio of bovine articular cartilage in compression

Spatial assessment of articular cartilage proteoglycans with Gd‐DTPA‐enhanced T1 imaging

Quantitative MR microscopy of enzymatically degraded articular cartilage

T2 relaxation time mapping reveals age- and species-related diversity of collagen network architecture in articular cartilage

Structure-Function Relationships in Enzymatically Modified Articular Cartilage

Contact Info

Product

Resources

About

T₂ relaxation reveals spatial collagen architecture in articular cartilage: A comparative quantitative MRI and polarized light microscopic study

Spatial assessment of articular cartilage proteoglycans with Gd‐DTPA‐enhanced T₁ imaging