Site-specific cell-tissue interactions in rabbit knee joint articular cartilage

Abstract Relationships between cartilage structure and superficial in situ chondrocyte deformations were investigated from 6 different knee joint locations ( n =10 knees). Depth dependent cartilage structure and composition were quantified with microscopic/microspectroscopic methods. Medial tibial c...

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Bibliographic Details
Published in:Journal of biomechanics 2016-09, Vol.49 (13), p.2882-2890
Main Authors: Ronkainen, A.P, Fick, J.M, Herzog, W, Korhonen, R.K
Format: Article
Language:English
Subjects:
Animals
Articular cartilage
Cartilage
Cartilage, Articular - cytology
Chondrocyte
Chondrocytes - physiology
Collagen
Collagen - metabolism
Collagens
Compressing
Correlation
Deformation
Extracellular matrix
Extracellular Matrix - metabolism
Female
Knee
Knee Joint - cytology
Knees
Organ Specificity
Orientation
Pericellular matrix
Physical Medicine and Rehabilitation
Proteoglycans
Proteoglycans - metabolism
Rabbit knee joint
Rabbits
Studies
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Summary:Abstract Relationships between cartilage structure and superficial in situ chondrocyte deformations were investigated from 6 different knee joint locations ( n =10 knees). Depth dependent cartilage structure and composition were quantified with microscopic/microspectroscopic methods. Medial tibial cartilages had the lowest superficial collagen content, highest collagen orientation angle, and highest proteoglycan content in the pericellular matrix relative to that in the extracellular matrix, coupled with the largest chondrocyte deformations. In contrast, femoral groove and lateral tibial cartilages had the highest superficial collagen contents, lowest collagen orientation angles, and low normalized proteoglycan contents in the pericellular matrix, coupled with the smallest chondrocyte deformations. To study cell-tissue interactions further, observations ( n =57) from all locations were pooled and a multivariable linear regression was performed. Cell width deformations ( R2 =0.57) correlated with collagen orientation angle (standardized regression coefficient β =0.398) and collagen content ( β =−0.402). Cell height deformations ( R2 =0.52) also correlated with collagen orientation ( β =−0.248) and collagen content ( β =0.455). Cell volume change upon cartilage compression ( R2 =0.41) correlated with collagen content ( β =0.435) and proteoglycan content ( β =0.279). In conclusion, higher collagen and proteoglycan contents combined with lower collagen orientation angle in the extracellular matrix were related to reductions in superficial chondrocyte deformations. Also, a steep gradient of proteoglycan content from the extracellular to the pericellular matrix was associated with increased cell deformation, particularly in the medial tibial plateau cartilage.
ISSN:0021-9290
1873-2380
DOI:10.1016/j.jbiomech.2016.06.033