Abstract
Introduction: Epidemiology suggests that an intrauterine nutrient restriction increases the likelihood of osteoporosis in later life, possibly due to differences in bone structure and strength. We hypothesise that, in an ovine model, early nutritional compromise reduces vertebral cancellous bone density and cortical thickness, and thereby reduces vertebral compressive strength.
Materials and methods: Lumbar spines were dissected from 8 sheep (6 male, 2 female: mean age 2.7 yrs). Spines were divided into different groups, based on the early diet of the sheep: group CC received a control diet, group IU received low protein in utero, and group PN received low protein both in utero and postnatally. Fifteen motion segments (consisting of two vertebrae and the intervening disc and ligaments) were prepared from the spines, and compressed to failure using a hydraulically-controlled materials testing machine to obtain yield strength. 1mm-thick bone slices were taken from the mid-sagittal and para-sagittal regions of each vertebral body and micro-radiographed. Digital images of the micro-radiographs were analysed to obtain the cancellous bone density in anterior and posterior regions, and the cortical thickness in the anterior, posterior, superior and inferior regions. Repeated measures ANOVA was used to test for differences in parameters at the different locations, and between the groups.
Results: The anterior cortex was 28% thinner for the IU group, and 23% thinner for the PN group compared to controls (both p< 0.001). In the PN group, the superior cortex was also 18% thinner than controls (p< 0.02). There was no significant difference between cancellous bone density in either region. Yield strength was 16% lower in the IU group compared to controls, but this did not reach significance.
Discussion: In the nutritionally compromised groups, cortical thickness was lower in regions of the vertebral body where fractures often occur in elderly people. However, the reduction in cortical thickness is not accompanied by a significant reduction in compressive strength in the sheep model. These findings suggest that the well-maintained cancellous bone protects the vertebra from fracture.
Correspondence should be addressed to Mr Carlos Wigderowitz, Senior Lecturer, University Department of Orthopaedic and Trauma Surgery, Ninewells Hospital and Medical School, Dundee DD1 9SY.
