A histomorphometric study of cortical bone activity during increased weight-bearing exercise

Raab, Diane M.; Crenshaw, Thomas D.; Kimmel, Donald B.; Smith, Everett L.

Affiliations

¹Biogerontology Laboratory, University of Wisconsin, Madison

²Department of Meat and Animal Sciences, University of Wisconsin, Madison

³Center for Hard Tissue Research, Creighton University, Omaha, Nebraska

Abstract

To quantify cortical bone response to weight-bearing exercise, bone size, mineral content, and formation were measured at the femoral midshaft in swine. Bone formation was measured histomorphometrically on the periosteal, endosteal, and osteonal surfaces. Sedentary adult crossbred sows (3 years, 229 kg) were randomly assigned to basal (B, n = 6), control (C, n = 7), or trained (T, n = 7) groups. The basal and control groups did not exercise and were killed initially (B) or after 20 weeks (C). The trained group walked on a treadmill 20 minutes/day at 5 km/h and 5% grade, 5 days/week for 20 weeks. Bone length, area, or fat-free dry weight was not different with time (B versus C) or with training (C versus T). Periosteal modeling was stimulated by walking. Periosteal formation surface and mineral apposition rate (MAR) were greater in trained than control femora. No effects of walking were measured on the endosteal surface. Intracortical remodeling was not affected by walking. The number of labeled osteons (22.4 cm⁻²) was not different among groups, but osteonal MAR was greater in trained (1.18 μm/day) than control (0.96 μ/day) femora. Walking for 20 weeks in the previously sedentary sows was not a sufficient stimulus to create differences in gross measures of bone size or mineral content but did increase periosteal and intracortical MAR. The primary effect of increased exercise appeared to be osteoblast activation.

Links

DOI: 10.1002/jbmr.5650060712

PubMed: 1950678

WoS: A1991GN78900011

History

Received: 1990-07-23

Revised: 1990-12-21

Accepted: 1991-01-16

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