The effects of hip contact aberrations on stress patterns within the human femoral head

Abstract

A two-dimensional finite element model incorporating cancellous bone inhomogeneity is used to study femoral head stress alterations caused by changes from the usual articular contact patterns. The contact stress distributions, calculated from an earlier mathematical analysis by Greenwald and O'Connor (16), are found to influence not only the adjacent subchondral bone, but relatively distant parts of the head as well. Both abnormally large joint incongruity and abnormally low cartilage compliance cause load to shift away from the superior “weight-bearing” area, out toward the periphery of the contact region. As a consequence, transverse compressive stresses, which are of appreciable magnitude but which do not contribute to weight bearing, are built up throughout much of the superior and central portions of the femoral head. Most small changes in the overall cartilage thickness or in its thickness distribution, when considered in isolation from hip compliance changes, have only minor effects on the internal stress distribution. An important exception is cartilage thinning at the superior margin, which can result in abrupt longitudinal compressive stress concentrations. It is suggested that such alterations of the normal patterns of stress transmission may contribute to sclerosis or to the formation of osteophytes or cysts in the osteoarthritic hip.