3D morphometric analysis of calcified cartilage properties using micro-computed tomography

Summary Objective Our aim is to establish methods for quantifying morphometric properties of calcified cartilage (CC) from micro-computed tomography (μCT). Furthermore, we evaluated the feasibility of these methods in investigating relationships between osteoarthritis (OA), tidemark surface morphology and open subchondral channels (OSCCs). Method Samples ( n  = 15) used in this study were harvested from human lateral tibial plateau ( n  = 8). Conventional roughness and parameters assessing local 3-dimensional (3D) surface variations were used to quantify the surface morphology of the CC. Subchondral channel properties (percentage, density, size) were also calculated. As a reference, histological sections were evaluated using Histopathological osteoarthritis grading (OARSI) and thickness of CC and subchondral bone (SCB) was quantified. Results OARSI grade correlated with a decrease in local 3D variations of the tidemark surface (amount of different surface patterns ( r s  = −0.600, P  = 0.018), entropy of patterns (EP) ( r s  = −0.648, P  = 0.018), homogeneity index (HI) ( r s  = 0.555, P  = 0.032)) and tidemark roughness (TMR) ( r s  = −0.579, P  = 0.024). Amount of different patterns (ADP) and EP associated with channel area fraction (CAF) ( r p  = 0.876, P r p  = 0.665, P  = 0.007, respectively) and channel density (CD) ( r p  = 0.680, P  = 0.011; r p  = 0.582, P  = 0.023, respectively). TMR was associated with CAF ( r p  = 0.926, P r p  = 0.574, P  = 0.025). CC topography differed statistically significantly in early OA vs healthy samples. Conclusion We introduced a μ-CT image method to quantify 3D CC topography and perforations through CC. CC topography was associated with OARSI grade and OSCC properties; this suggests that the established methods can detect topographical changes in tidemark and CC perforations associated with OA.