Purpose: Postero-anterior (PA) mobilization is widely used to manage low back pain by physiotherapists. The PA load is applied through the spinous process of a vertebra. Low bone density is a counter-indication of PA mobilization, whether PA mobilization may cause fractures in fragile vertebrae is unclear. Therefore, the aim of this study was to quantify the role of bone density on a fracture risk in the first lumbar vertebra subjected to PA load. Methods:A finite element model of the first lumbar vertebra of an elderly female was created to predict the fracture risk of the PA mobilization. The von Mises stress and minimum principal strain were used as the assessment indicators. Three different bone density cases were evaluated to reflect healthy, osteoporotic, and severe osteoporotic conditions by assuming heterogeneous moduli based on local bone density converted from computed tomographic images. Results:In the severe osteoporotic condition under PA load, the maximum von Mises stress and largest compressive strain occurred in the pedicles and spinous process. These stress and strain exceeded the yield stress and yield strain indicating a high risk for failure. The resulted stress and strain were also excessive in the pedicles for healthy and moderate osteoporotic conditions.Conclusions: PA mobilization can increase the risk of vertebra fracture in elderly with osteoporosis. The pedicles and spinous process of osteoporotic L1 vertebra are the critical regions prone to fracture. We recommend that it is crucial to be reduce force when applying the PA mobilization to elderly with osteoporosis.
Short stems are becoming increasingly popular in total hip arthroplasty as they preserve the bone stock and simplify the implantation process. Short stems are advised mainly for patients with good bone stock. The clinical use of short stems could be enlarged to patients with poor bone stock if a cemented alternative would be available. Therefore, this study aimed to quantify the mechanical performance of a cemented short stem and to compare the “undersized” cementing strategy (stem one size smaller than the rasp) with the “line‐to‐line” technique (stem and rasp with identical size). A prototype cemented short stem was implanted in eight pairs of human cadaveric femora using the two cementing strategies. Four pairs were experimentally tested in a single‐legged stance condition; stiffness, strength, and bone surface displacements were measured. Subject‐specific nonlinear finite element models of all the implanted femora were developed, validated against the experimental data, and used to evaluate the behavior of cemented short stems under physiological loading conditions resembling level walking. The two cementing techniques resulted in nonsignificant differences in stiffness and strength. Strength and stiffness as calculated from finite element were 8.7 ± 16% and 9.9 ± 15.0% higher than experimentally measured. Displacements as calculated from finite element analyses corresponded strongly (R 2 ≥ .97) with those measured by digital image correlation. Stresses during level walking were far below the fatigue limit for bone and bone cement. The present study suggests that cemented short stems are a promising solution in osteoporotic bone, and that the line‐to‐line and undersized cementing techniques provide similar outcomes.
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