Clinical biomechanics
-
Clinical biomechanics · Jun 2012
Describing the active region boundary of EMG-assisted biomechanical models of the low back.
Electromyography-assisted (EMG-assisted) biomechanical models are used to characterize the muscle and joint reaction forces in the lumbar region. However, during a full-range trunk flexion, there is a transition of extension moment from the trunk extensor muscles to the passive tissues of the low back, indicating that the empirical EMG data used to drive these EMG-assisted models becomes less correlated with the extensor moment. The objectives of this study were to establish the trunk flexion angles at which the passive tissues generate substantial trunk extension moment and to document how these angles change with asymmetry. ⋯ These results indicate that EMG-assisted biomechanical models need to consider the role of passive tissues at trunk flexion angles significantly less than previously thought and these flexion angles vary as a function of the asymmetry and direction of motion.
-
Clinical biomechanics · Jun 2012
Investigating the change in three dimensional deformity for idiopathic scoliosis using axially loaded MRI.
Adolescent idiopathic scoliosis is a complex three-dimensional deformity, involving a lateral deformity in the coronal plane and axial rotation of the vertebrae in the transverse plane. Gravitational loading plays an important biomechanical role in governing the coronal deformity, however, less is known about how they influence the axial deformity. This study investigates the change in three-dimensional deformity of a series of scoliosis patients due to compressive axial loading. ⋯ This study suggests that the biomechanical effects of axial loading primarily influence the coronal deformity, with no significant change in vertebral axial rotation or intravertebral rotation observed between the unloaded and loaded condition. However, the magnitude of changes in vertebral rotation with compressive loading may have been too small to detect given the resolution of the current technique.
-
Clinical biomechanics · May 2012
Femoral bone strains during antegrade nailing: a comparison of two entry points with identical nails using finite element analysis.
Antegrade femoral nailing has become the standard treatment for diaphyseal femoral shaft fractures. Concerns linger that improper location of the nail entry point may lead to iatrogenic fracture and further complications. This study used finite element analysis to compare the strain magnitude and distribution resulting from each of two entry points in the proximal femur during antegrade nailing. ⋯ The trochanteric entry will have a much greater potential of iatrogenic fracture of the proximal femur during insertion of a nail. Strains with this entry point exceed the yield level of bone and the repeated loading with the progression of the nail could cause fissures or fractures. Caution should be taken during insertion of an antegrade nail when utilizing a lateral trochanteric starting point secondary to an increased risk of trochanteric fracture and lateral cortex fracture.
-
Clinical biomechanics · May 2012
An ex vivo biomechanical comparison of a novel vertebral compression fracture treatment system to kyphoplasty.
Vertebral compression fracture repair aims to relieve pain and improve function by restoring vertebral structure and biomechanics, but is still associated with risks arising from polymethylmethacrylate cement extravasation. The Kiva® Vertebral Compression Fracture Treatment System, a stacked coil implant made of polyetheretherketone and delivered over a guide-wire, is a novel device designed to provide height restoration and mechanical stabilization, while improving cement containment and minimizing disruption of cancellous bone. The objective of this study was to determine whether the Kiva system is as effective as balloon kyphoplasty at restoring mechanical properties in osteoporotic vertebral compression fractures. ⋯ Kiva exhibits similar biomechanical performance to balloon kyphoplasty, but may reduce the risk of extravasation through the containment mechanism of the implant design and by reducing cement volume.
-
Clinical biomechanics · Mar 2012
Posterior motion preserving implants evaluated by means of intervertebral disc bulging and annular fiber strains.
The aims of motion preserving implants are to ensure sufficient stability to the spine, to release facet joints by also allowing a physiological loading to the intervertebral disc. The aim of this study was to assess disc load contribution by means of annular fiber strains and disc bulging of intact and stiffened segments. This was compared to the segments treated with various motion preserving implants. ⋯ This study introduces an in vitro method, which was employed to evaluate spinal implants other than standard biomechanical methods. We could demonstrate that dynamic stabilization methods are able to keep fiber strains and disc bulging in a physiological range.