In vitro glycation of articular cartilage alters the biomechanical response of chondrocytes in a depth-dependent manner

In vitro glycation of articular cartilage alters the biomechanical response of chondrocytes in a depth-dependent manner

Summary Objective To determine if increasing cartilage cross-links through in vitro glycation of cartilage explants can alter the biomechanical response of chondrocytes to compressive deformation. Method Bovine osteochondral explants were either incubated with cell culture solution supplemented with...

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Bibliographic Details
Published in:Osteoarthritis and cartilage Vol. 22; no. 10; pp. 1410 - 1418
Main Authors: Fick, J.M, Huttu, M.R.J, Lammi, M.J, Korhonen, R.K
Format: Journal Article
Language:English
Published: England Elsevier Ltd 01-10-2014
Subjects:
Aging
Animals
Articular cartilage
Biomechanical Phenomena - drug effects
Biomechanical Phenomena - physiology
biomechanics
biomekanik
Cartilage, Articular - drug effects
Cartilage, Articular - metabolism
Cartilage, Articular - physiology
Cattle
cell research
Cell Size - drug effects
cellforskning
Chondrocyte deformation
Chondrocytes - drug effects
Chondrocytes - metabolism
Chondrocytes - physiology
collagen
Cross-linking
Glycosylation
In Vitro Techniques
Microscopy, Confocal
Rheumatology
Ribose
Ribose - metabolism
Ribose - pharmacology
Stress, Mechanical
Aging
Chondrocyte deformation
Articular cartilage
Cross-linking
Ribose
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Summary:Summary Objective To determine if increasing cartilage cross-links through in vitro glycation of cartilage explants can alter the biomechanical response of chondrocytes to compressive deformation. Method Bovine osteochondral explants were either incubated with cell culture solution supplemented with ( n  = 7) or without ( n  = 7) ribose for 42 h in order to induce glycation. Deformation-induced changes in cell volume, dimensions and local tissue strains were determined through confocal laser scanning microscopy (CLSM) and the use of a custom built micro-compression device. Osteochondral explants were also utilized to demonstrate changes in depth-wise tissue properties, biomechanical tissue properties and cross-links such as pentosidine (Pent), hydroxylysyl pyridinoline (HP) and lysyl pyridinoline (LP). Results The ribose treated osteochondral samples experienced reduced cell volume deformation in the upper tissue zone by ∼8% ( P  = 0.005), as compared the control samples, through restricting cell expansion. In the deeper tissue zone, cell volume deformation was increased by ∼12% ( P  < 0.001) via the transmission of mechanical signals further into the tissue depth. Biomechanical testing of the ribose treated osteochondral samples demonstrated an increase in the equilibrium and dynamic strain dependent moduli ( P  < 0.001 and P  = 0.008, respectively). The biochemical analysis revealed an increase in Pent cross-links ( P  < 0.001). Depth-wise tissue property analyses revealed increased levels of carbohydrate content, greater levels of fixed charge density and an increased carbohydrate to protein ratio from 6 to 16%, 55–100% and 72–79% of the normalized tissue thickness (from the surface), respectively, in the ribose-treated group ( P  < 0.05). Conclusion In vitro glycation alters the biomechanical response of chondrocytes in cartilage differently in upper and deeper zones, offering possible insights into how aging could alter cell deformation behavior in cartilage.
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ISSN:1063-4584
1522-9653
1522-9653
DOI:10.1016/j.joca.2014.07.020