Papers Published

  1. J Hewitt, F Guilak, R Glisson, TP Vail, Regional material properties of the human hip joint capsule ligaments., Journal of orthopaedic research : official publication of the Orthopaedic Research Society, United States, vol. 19 no. 3 (May, 2001), pp. 359-64 .
    (last updated on 2006/06/06)

    The hip joint capsule functions to constrain translation between the femur and acetabulum while allowing rotational and planar movements. Despite the crucial role it plays in the pathogenesis of hip instability, little is known about its biomechanical properties. The goal of this study was to determine the regional material properties of the iliofemoral and ischiofemoral ligaments of the capsule. Ten human cadaveric specimens of each ligament were tested to failure in tension. The stress at failure, strain at failure, strain energy density at failure, toe- and linear-region elastic moduli, and the Poisson's ratio were measured for each ligament. The strain to failure was greatest in the ischiofemoral ligament, while no significant difference was noted in failure stress by region or ligament. The Young's moduli of elasticity ranged from 76.1 to 285.8 MPa among the different ligaments, and were generally consistent with properties previously reported for the shoulder capsule. The elastic moduli and strain energy density at failure differed by region. No significant differences in Poisson's ratio were found by region or ligament. The average Poisson's ratio was approximately 1.4, consistent with anisotropic behavior of ligamentous tissues. Understanding the material properties of the hip capsule may help the orthopaedic surgeon better understand normal ligament function, and thereby choose a surgical approach or strategy of repair. Furthermore, knowledge of the normal mechanical function of the hip capsule ligaments could assist in the evaluation of the success of a repair.

    Aged • Aged, 80 and over • Elasticity • Female • Hip Joint • Humans • Joint Capsule • Ligaments, Articular • Male • Middle Aged • Stress, Mechanical • anatomy & histology • physiology*