Abstract
Relationships between composition, structure and constituent-specific functional properties of human articular cartilage at different stages of osteoarthritis (OA) are poorly known. We established these relationships by comparison of elastic, viscoelastic and fibril-reinforced poroelastic mechanical properties with microscopic and spectroscopic analysis of structure and composition of healthy and osteoarthritic human tibial cartilage (n = 27). At a low frequency (0.005 Hz), proteoglycan content correlated negatively and collagen content correlated positively with the phase difference (i.e. tissue viscosity). At a high-frequency regime (> 0.05 Hz), proteoglycan content correlated negatively and collagen orientation angle correlated positively with the phase difference. Proteoglycans were lost in the early and advanced OA groups compared to the healthy group, while the superficial collagen orientation angle was greater only in the advanced OA group compared to the healthy group. Simultaneously, the initial fibril network modulus (fibril pretension) was smaller in the early and advanced OA groups compared to the healthy group. These findings suggest different mechanisms contribute to cartilage viscosity in low and high frequencies, and that the loss of superficial collagen pretension during early OA is due to lower tissue swelling (PG loss), while in advanced OA, both collagen disorganization and lower swelling modulate the collagen fibril pretension.
Highlights
Articular cartilage provides the joint with smooth movements during locomotion
Consistent with the changes in the equilibrium and non-fibrillar matrix modulus observed in our previous study,[15] the PG loss occurred from 0 to 12% of the cartilage thickness in the early OA group compared to the healthy group
The PG loss in the advanced OA group compared to the healthy group progressed further, up to 37% of the cartilage thickness
Summary
Articular cartilage provides the joint with smooth movements during locomotion. Cartilage is highly resilient and dissipative tissue. The fluid phase makes up approximately 70-80% of the wet weight of the tissue. The solid phase consists mainly of proteoglycans (PGs) (5–7% of the wet weight) and collagen fibril (mainly type II, 15–23% of the wet weight).[29,35–37] The content, structure, and interactions between these main constituents control the mechanical behavior of cartilage. Cartilage responses to impacts and high-strain loads are mainly regulated by the collagen fibrils network and high interstitial fluid pressure. Fluid flows out of the tissue and PGs mainly control the equilibrium stiffness of the tissue.[37,51]
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