Transmission of Force in the Lumbosacral Spine During Backward Falls

Autor: Carolyn Van Toen, Stephen N. Robinovitch, Peter A. Cripton, Meena M. Sran
Rok vydání: 2012
Předmět:
Zdroj: Spine. 37:E519-E527
ISSN: 0362-2436
DOI: 10.1097/brs.0b013e31823ecae0
Popis: Vertebral body fractures are the most common type of osteoporotic fractures.1,2 These fractures represent a growing public health concern because the incidence is projected to increase as the population ages.3 Vertebral fractures are associated with substantial increases in back pain, functional limitation, disability, and mortality.4,5 Falls are a major contributing factor to the occurrence of osteoporotic fractures6; 41% of vertebral fractures in older men are associated with falls from standing height or lower.7 The most common vertebral fracture site for older men is the lumbosacral spine, which represents 56% of all cases.7 Falls from standing height or lower also account for between 8% and 26% of spinal cord injuries,7,8 and more than two-thirds of these injuries occur in older adults.8 The risk of vertebral fracture in a backward fall depends, by definition, on a “factor of safety.” This factor of safety is defined as the ratio of the force that will typically result in failure under a loading configuration similar to that applied in the fall (i.e., tolerance) divided by the peak-applied force. Previous studies have measured the force applied to the buttocks in subinjurious backward falls in human subjects.9 The compressive force required to cause fracture of lumbar vertebrae has been determined by testing isolated cadaver spine segments.10–17 However, the peak forces occurring at the lumbosacral spine during a backward fall are not known, and this is a barrier to the development of injury prevention strategies. An intervention that has been suggested to reduce the incidence of fall-related fractures is the use of compliant or low-stiffness flooring.9,18,19 In a previous experimental study conducted by a subset of this study’s authors, human subjects fell from standing onto floors of various stiffnesses.9 Impact forces at the buttocks decreased with decreases in floor stiffness; however, the effect on spine forces was not addressed. To determine the effect of floor stiffness on spine forces experimentally, direct measurement of spinal component loads would be necessary; however, these are difficult to measure even during benign activities in vivo.10,11 Numerical models have been used to study the loads generated in the human spine during various activities,12–15 and this method has also been used to study spinal forces during trauma.16–18 Some of the previous models have been complex, have simulated multiple degrees of freedom at each joint, and have incorporated anatomic details such as the rib cage, lumbar muscles, viscera, facet joints, and intervertebral discs.12,14–16 Axial spine forces are related to fracture risk19–23; therefore, they are of primary interest in this study. It was our objective to develop an appropriate model to allow examination of the effect of floor stiffness on axial loading at various levels of the spine during a fall. We had access to a unique set of data to incorporate into our model. These human subject-specific data from our previous experimental study provided a level of verification for the present computational model.9 No previous mathematical modelling or experimental studies have examined spine forces resulting from a backward fall onto the buttocks. Accordingly, the specific objectives in this study were (1) to develop and verify a lumped-parameter model to predict intervertebral forces at several levels of the lumbosacral spine during backward falls from standing, (2) to evaluate the effect of floor stiffness on these forces, and (3) to examine how these compare with the axial force associated with fracture of the spine.
Databáze: OpenAIRE
Externí odkaz: