Td. Brown et al., MECHANICAL CONSEQUENCES OF CORE DRILLING AND BONE-GRAFTING ON OSTEONECROSIS OF THE FEMORAL-HEAD, Journal of bone and joint surgery. American volume, 75A(9), 1993, pp. 1358-1367
We employed an anatomically realistic three-dimensional finite-element
model to explore several biomechanical variables involved in coring o
r bone-grafting of a segmentally necrotic femoral head. The mechanical
efficacy of several variants of these procedures was indexed in terms
of their alteration of the stress:strength ratio in at-risk necrotic
cancellous bone. For coring alone, the associated structural compromis
e was generally modest, provided that the tract did not extend near th
e subchondral plate. Cortical bone-grafting was potentially of great s
tructural benefit for femoral heads in which the graft penetrated deep
ly into the superocentral or lateral aspect of the lesion, ideally wit
h abutment against the subchondral plate. By contrast, central or late
ral grafts that stopped well short of the subchondral plate were contr
aindicated biomechanically because they caused marked elevations in st
ress on the necrotic cancellous bone. Calculated levels of stress were
relatively insensitive to variations in the diameter of the graft. CL
INICAL RELEVANCE: Preservation of the natural femoral head in the pres
ence of osteonecrosis depends on avoidance of collapse of structurally
incompetent necrotic cancellous bone. Coring and cortical bone-grafti
ng both alter the distribution of mechanical stress in the necrotic fe
moral head. The alterations in stress depend on the location, diameter
, and degree of penetration of the core or graft tract. Intraoperative
ly, there is usually substantial latitude for placement of the tract,
but the associated effects on mechanical stresses in the head are not
well understood. This finite-element model provides a systematic means
to study such influences and identifies several technical factors tha
t bear on the biomechanical efficacy of these head-preserving procedur
es.