Previous exposure to simulated microgravity does not exacerbate bone loss during subsequent exposure in the proximal tibia of adult rats

Abstract Extended periods of inactivity cause severe bone loss and concomitant deterioration of the musculoskeletal system. Considerable research has been aimed at better understanding the mechanisms and consequences of bone loss due to unloading and the associated effects on strength and fracture r...

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Published in:Bone (New York, N.Y.) N.Y.), 2013-10, Vol.56 (2), p.461-473
Main Authors: Shirazi-Fard, Yasaman, Anthony, Rachel A, Kwaczala, Andrea T, Judex, Stefan, Bloomfield, Susan A, Hogan, Harry A
Format: Article
Language:English
Subjects:
Animals
Biological and medical sciences
Bone Density - physiology
Diseases of the osteoarticular system
Disuse osteoporosis
Fundamental and applied biological sciences. Psychology
Hindlimb Suspension - physiology
Hindlimb unloading
Male
Medical sciences
Mice, Inbred C57BL
Multiple unloading
Orthopedics
Osteoporosis. Osteomalacia. Paget disease
Rats
Reambulation
Tibia - physiology
Trabecular bone strength
Vertebrates: anatomy and physiology, studies on body, several organs or systems
Weightlessness Simulation
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Summary:Abstract Extended periods of inactivity cause severe bone loss and concomitant deterioration of the musculoskeletal system. Considerable research has been aimed at better understanding the mechanisms and consequences of bone loss due to unloading and the associated effects on strength and fracture risk. One factor that has not been studied extensively but is of great interest, particularly for human spaceflight, is how multiple or repeated exposures to unloading and reloading affect the skeleton. Space agencies worldwide anticipate increased usage of repeat-flier crewmembers, and major thrust of research has focused on better understanding of microgravity effects on loss of bone density at weightbearing skeletal sites; however there is limited data available on repeat microgravity exposure. The adult hindlimb unloaded (HU) rat model was used to determine how an initial unloading cycle will affect a subsequent exposure to disuse and recovery thereafter. Animals underwent 28 days of HU starting at 6 months of age followed by 56 days of recovery, and then another 28 days of HU with 56 days of recovery. In vivo longitudinal pQCT was used to quantify bone morphological changes, and ex vivo μCT was used to quantify trabecular microarchitecture and cortical shell geometry at the proximal tibia metaphysis (PTM). The mechanical properties of trabecular bone were examined by the reduced platen compression mechanical test. The hypothesis that the initial HU exposure will mitigate decrements in bone mass and density for the second HU exposure was supported as pre- to post-HU declines in total BMC, total vBMD, and cortical area by in vivo pQCT at the proximal tibia metaphysis were milder for the second HU (and not significant) compared to an age-matched single HU (3% vs . 6%, 2% vs . 6%, and 2% vs . 6%, respectively). In contrast, the hypothesis was not supported at the microarchitectural level as losses in BV/TV and Tb.Th. were similar during 2nd HU exposure and age-matched single HU. Recovery with respect to post-HU values and compared to aging controls for total BMC, vBMD and cortical area were slower in older animals exposed to single or double HU cycles compared to recovery of younger animals exposed to a single HU bout. Despite milder recovery at the older age, there was no difference between unloaded animals and controls at the end of second recovery period. Therefore, the data did not support the hypothesis that two cycles of HU exposure with recovery would hav
ISSN:8756-3282
1873-2763
DOI:10.1016/j.bone.2013.07.004