Abstract
INTRODUCTION
Avascular necrosis (AVN) of the femoral head (FH) initiates from biological disruptions in the bone and may progress to mechanical failure of the hip. Mechanical and structural properties of AVN bone have not been widely reported, however such understanding is important when designing therapies for AVN. Brown et al.[1] assessed mechanical properties of different regions of AVN FH bone and reported 52% reduction in yield strength and 72% reduction in elastic modulus of necrotic regions when compared to non-necrotic bone. This study aimed to characterise structural and mechanical properties of FH bone with AVN and understand the relationship between lesion volume and associated mechanical properties.
METHODS
Twenty FH specimens from patients undergoing hip arthroplasty for AVN and six non-pathological cadaveric FH controls were collected. Samples were computed tomography scanned and images analysed for percentage lesion volume with respect to FH volume. Samples were further divided for structural and mechanical testing. The mechanical property group were further processed to remove 9mm cylindrical bone plugs from the load bearing and non-load-bearing regions of the FHs. FH and bone plug samples were tested in compression (1mm/min); elastic modulus and yield stress were calculated.
RESULTS
Imaging
Individual lesion size within AVN FHs varied: multiple small lesions or small numbers of large lesions were present in all FHs. Mean lesion volume percentage for AVN FHs was significantly greater than control FHs (p30% total FH volume. Structural Properties: The mean elastic modulus for AVN FHs was 15% lower than that of control FHs and mean yield stress was 4% lower than that of control FHs, however this difference was not significant.
Mechanical Properties
The mean elastic modulus and yield stress of bone plugs from the load-bearing regions of AVN FHs were significantly lower than those of control samples (79% and 77% respectively; p<0.05, Kruskal-Wallis), however, for non-load-bearing samples, mean elastic modulus and yield stress of AVN FHs were significantly higher than control samples (by 153% and 123% respectively; p<0.05, Kruskal-Wallis).
DISCUSSION
Although mechanical properties of bone in load-bearing regions of AVN FHs were significantly less than those of control FHs, replicating previous findings by Brown et al. (1981, CORR. 156, 240-7), mechanical properties in the non-load bearing regions were increased. This may be due to adaptation of the non-load bearing region to support loads following AVN in normally load bearing regions, or due to the presence of denser sclerotic tissue.
In this study, necrotic bone samples demonstrated smaller changes in mechanical properties in the load-bearing region with respect to those regions in the control samples than previously reported by Brown et al.. This may be due to differences in experimental methods (e.g. patient demographics, quality of control bone samples, loading rate, and location of samples) or due to the disease stage of the AVN FHs from which tissues were taken. In addition, this study has demonstrated that necrotic lesions are not consistent in quantity, size and location.
