Reversibility of nontraumatic disuse osteoporosis during its active phase

Jaworski, Z. F. G.; Uhthoff, H. K.

Affiliations

¹Department of Medicine, Faculty of Health Sciences, University of Ottawa at the Ottawa General Hospital, 501 Smyth Road, Ottawa, Ontario, Canada

²Division of Orthopaedic Surgery, Faculty of Health Sciences, University of Ottawa at the Ottawa General Hospifal, 501 Smyth Road, Ottawa, Ontario, Canada

Abstract and keywords

The potential for the recovery of bone lost during the active phase of disuse osteoporosis, both in the diaphyseal compacta and metaphyseal spongiosa was tested in young adult and old Beagle dogs. Immobilization for up to 60 weeks was achieved by placing the forelimb in a spica cast and remobilization by removing it. Bone volume was estimated in the third metacarpus, radius, ulna and humerus at the mid-diaphysis and at the level of distal metaphyseal spongiosa in both forelimbs by radiography and histomorphometry.

Measurements carried out on animals remobilized showed considerable recovery of the original bone loss. In both age groups, the residual deficits increased, however, with the duration of immobilization and were similar in the metaphyseal spongiosa and in the diaphyseal compacta. The old dogs which began the study with 10% less bone than the younger dogs, showed smaller proportional losses than the younger dogs but greater residual deficits, most evident in the diaphysis. In both age groups the distal, weight-bearing bones tended to show greater losses and also greater recovery both in diaphyseal compacta and the metaphyseal spongiosa. Thus, 28 weeks after cast removal following 32 weeks of immobilization the following findings were noted: In the third metacarpal diaphyseal compacta in the younger dogs, a 53.6% loss (mostly from the periosteal envelope) decreased to 16.3% (a 70% recovery) while in the older dogs a 37.6% loss (mostly from the endosteal envelope) decreased to 23% (a 40% recovery). In metacarpal metaphyseal spongiosa in young adult dogs, a 50% loss reduced to 16.8% (a 66% recovery) while in the older dogs a 47% loss reduced to 19% (a 60% recovery).

These observations apply only to the effect of remobilization on recovery of bone loss incurred during the active phase of disuse osteoporosis. The same potential for recovery may not exist later in the inactive phase of established disuse osteoporosis. The permanent losses, however, could be prevented by appropriate measures taken during the active phase of osteoporosis.

Keywords: Disuse Osteoporosis; Bone Histomorphometry; Bone Loss Recovery

Links

DOI: 10.1016/8756-3282(86)90003-7

PubMed: 3801236

WoS: A1986F296300003

History

Received: 1985-11-14

Revised: 1986-05-11

Accepted: 1986-05-11

Online: 2004-02-13

Cited Works (5)

Year	Entry
1978	Uhthoff HK, Jaworski ZF. Bone loss in response to long-term immobilisation. J Bone Joint Surg. August 1978;60B(3):420-429.
1974	Minaire P, Meunier P, Edouard C, Bernard J, Courpron P, Bourret J. Quantitative histological data on disuse osteoporosis: comparison with biological data. Calcif Tiss Res. December 1974;17(1):57-73.
1970	Donaldson CL, Hulley SB, Vogel JM, Hattner RS, Bayers JH, McMillan DE. Effect of prolonged bed rest on bone mineral. Metabolism. December 1970;19(12):1071-1084.
1980	Jaworski ZFG, Liskova-Kiar M, Uhthoff HK. Effect of long-term immobilisation on the pattern of bone loss in older dogs. J Bone Joint Surg. February 1980;62B(1):104-110.
1983	Krølner B, Toft B. Vertebral bone loss: an unheeded side effect of therapeutic bed rest. Clin Sci (London). 1983;64(5):537-540.

Cited By (34)

Year	Entry
1998	Martin RB, Burr DB, Sharkey NA. Skeletal Tissue Mechanics. New York, NY: Springer-Verlag; 1998.
1990	Frost HM. Skeletal structural adaptations to mechanical usage (SATMU), II: redefining Wolff's Law: the remodeling problem. Anat Rec. April 1990;226(4):414-422.
2006	Robling AG, Castillo AB, Turner CH. Biomechanical and molecular regulation of bone remodeling. Annu Rev Biomed Eng. 2006;8:455-498.
1991	Bertram JEA, Swartz SM. The “law of bone transformation”: a case of crying Wolff? Biol Rev. August 1991;66(3):245-273.
1991	Turner CH. Homeostatic control of bone structure: an application of feedback theory. Bone. 1991;12(3):203-217.
1992	Lanyon LE. The success and failure of the adaptive response to functional load-bearing in averting bone fracture. Bone. 1992;13(2):S17-S21.
1998	Mullender M, van Rietbergen B, Rüegsegger P, Huiskes R. Effect of mechanical set point of bone cells on mechanical control of trabecular bone architecture. Bone. February 1998;22(2):125-131.
1992	Frost HM, Jee WSS. On the rat model of human osteopenias and osteoporoses. Bone Miner. September 1992;18(3):227-236.
1992	Frost HM. Perspectives: bone's mechanical usage windows. Bone Miner. December 1992;19(3):257-271.
1995	Duncan RL, Turner CH. Mechanotransduction and the functional response of bone to mechanical strain. Calcif Tiss Int. December 1995;57(5):344-358.
1999	Turner CH. Toward a mathematical description of bone biology: the principle of cellular accommodation. Calcif Tiss Int. December 1999;65(6):466-471.
1994	Turner CH, Forwood MR, Otter MW. Mechanotransduction in bone: do bone cells act as sensors of fluid flow? FASEB J. August 1994;8(11):875-878.
1987	Lanyon LE. Functional strain in bone tissue as an objective, and controlling stimulus for adaptive bone remodelling. J Biomech. 1987;20(11-12):1083-1093.
1994	Goulet RW, Goldstein SA, Ciarelli MJ, Kuhn JL, Brown MB, Feldkamp LA. The relationship between the structural and orthogonal compressive properties of trabecular bone. J Biomech. April 1994;27(4):375-389.
1997	Turner CH, Annet V, Pidaparti RMV. A uniform strain criterion for trabecular bone adaptation: do continuum-level strain gradients drive adaptation? J Biomech. June 1997;30(6):555-563.
2001	Lanyon L, Skerry T. Postmenopausal osteoporosis as a failure of bone's adaptation to functional loading: a hypothesis. J Bone Miner Res. November 2001;16(11):1937-1947.
2006	Adams MA, Pollintine P, Tobias JH, Wakley GK, Dolan P. Intervertebral disc degeneration can predispose to anterior vertebral fractures in the thoracolumbar spine. J Bone Miner Res. September 2006;21(9):1409-1416.
2016	Cabahug-Zuckerman P, Frikha-Benayed D, Majeska RJ, Tuthill A, Yakar S, Judex S, Schaffler MB. Osteocyte apoptosis caused by hindlimb unloading is required to trigger osteocyte RANKL production and subsequent resorption of cortical and trabecular bone in mice femurs. J Bone Miner Res. July 2016;31(7):1356-1365.
1988	Skerry TM, Bitensky L, Chayen J, Lanyon LE. Loading-related reorientation of bone proteoglycan in vivo: strain memory in bone tissue? J Orthop Res. July 1988;6(4):547-551.
1995	Gross TS, Rubin CT. Uniformity of resorptive bone loss induced by disuse. J Orthop Res. September 1995;13(5):708-714.
2002	Ehrlich PJ, Lanyon LE. Mechanical strain and bone cell function: a review. Osteoporos Int. September 2002;13(9):688-700.
2015	Cabahug-Zuckerman P. A Β₃ Integrin Based Mechanosome in Bone Tissue Osteocytes: Plasticity to Changes in Mechanical Loading [PhD thesis]. New York, NY: The City College of New York; 2015.
2000	Ryder KD. Parathyroid Hormone Modulates the Response of Osteoblast-Like Cells to Mechanical Stimulation [PhD thesis]. Indianapolis, IN: Indiana University; May 2000.
1997	Heinonen A. Exercise as an Osteogenic Stimulus [PhD thesis]. University of Jyväskylä; 1997.
2009	McGee-Lawrence ME. Skeletal Preservation by Hibernating Bears [PhD thesis]. Houghton, MI: Michigan Technological University; 2009.
2011	Wojda SJ. The Effects of Hibernation on Bone in Yellow-Bellied Marmots [Master's thesis]. Houghton, MI: Michigan Technological University; 2011.
1992	Bloomfield SA. Site-Specific Changes in Bone Mass and Alterations in Calciotropic Hormones With Electrical Stimulation Exercise in Individuals With Chronic Spinal Cord Injury [PhD thesis]. The Ohio State University; 1992.
1998	D'Andrea SE. Lower Limb Response to Impact in Simulated Microgravity and 1G [PhD thesis]. The Ohio State University; 1998.
1994	Levenston ME. Simulation of Functional Adaptation in Trabecular and Cortical Bone [PhD thesis]. Stanford University; September 1994.
1994	Oden ZM. Computational Prediction of Functional Adaptation in Canine Radii [PhD thesis]. Tulane University; 1994.
2000	Coleman JC. Analysis of in Vivo Bone Strain History During Dynamic Mechanical Loading [PhD thesis]. Tulane University; 2000.
2004	Roberts MD. Adaptation of Bone to Mechanical and Nonmechanical Stimuli: An Integrated Experimental and Computational Study [PhD thesis]. Tulane University; 2004.
2006	Macdonald HM. Effectiveness of a School-Based Physical Activity Intervention for Increasing Bone Strength in Children: Action Schools! British Columbia [PhD thesis]. Vancouver, BC: University of British Columbia; July 2006.
1993	Goulet RW. The Quantification of the Structure and Mechanical Properties of Trabecular Bone [PhD thesis]. University of Michigan; 1993.