Abstract
The hip joint capsule passively restrains extreme range of motion protecting against impingement, dislocation and possibly edge loading. These functions would be advantageous following total hip arthroplasty (THA) however the degree of capsular excision, preservation and/or repair greatly varies between surgeons/approaches. Therefore, we asked: how does THA affect capsular ligamentous biomechanics? Which factors have the biggest influence?
For this laboratory based, cadaveric model, THA was performed through the acetabular medial wall, thus preserving the entire hip capsule. A previously published testing rig was used to measure capsular function by internally and externally rotating the hip in each of five hip positions (standing, sitting, gait heel strike, and two impingement risk positions, full flexion with adduction & extension with abduction). N=8 hips were tested both before and after THA allowing for repeated measurements between the native and replaced hip.
The ROM before the capsule engaged increased following THA (p<0.05), indicating reduced biomechanical function. Internal rotation was affected more than external rotation. Increasing neck length restored the ROM more towards the native condition. Increasing head size also had a small positive effect, but less than neck length.
Following THA, the capsular ligaments were no longer able to wrap around the smaller femoral head thereby limiting their ability to restrain excessive hip movement. The anterior capsule is affected less than the posterior, and may benefit from being preserved length. A repair to the posterior capsule should compensate for the reduced THA head size in order to restore function.