A BIOMECHANICAL EVALUATION OF THE LONG STEM INTRAMEDULLARY HIP SCREW

Despite the advantages associated with short-stem intramedullary hip screw devices for the treatment of intertrochanteric fractures, recent reports have shown an increased incidence of femoral shaft fractures after their insertion. These findings led to the hypothesis that an intramedullary hip screw with a longer stem may more effectively redistribute loads to the distal end of the femoral shaft, where they may be more readily absorbed by the increased bony cross-sectional area. To characterize the load patterns of a long-stem device in the femur, 10 fresh-frozen adult femurs were instrumented with unidirectional strain gauges. A total of eight strain gauges were placed in the direction of principal femoral strains on the medial and lateral surfaces of each femur. Each femur was held in a steel vice at 15 degrees of adduction in the coronal plane and vertical in the sagittal plane. The femurs were then subjected to successively increasing vertically applied compressive loads from 0 N to 1,400 N at 200-N increments using a servohydraulic testing machine. Strain values were recorded at each load after a 5-min equilibration period. Each femur was tested under five conditions: (a) intact, (b) after insertion of the long-stem intramedullary hip screw device, (c) with an experimentally created two-part fracture, (d) with a stable four-part fracture, and (e) with an unstable four-part fracture with the posteromedial fragment removed. Half the femurs were randomly assigned to have two distal interlocking screws placed before fracture. The remaining half were loaded without distal interlocking screws. The results indicate that the loads on the femur with intertrochanteric fractures are redistributed such that the proximal femur is subjected to significantly lower strains. Moreover, even though strain values in the distal metaphysis at the site of load transfer were relatively high, they did not differ significantly from the values recorded in the intact femur. Thus, the long-stem intramedullary hip screw device transmits progressively decreasing load to the proximal femur with increasing fracture instability and redistributes this load throughout the distal femur without significantly increasing distal femoral strain values.