Bone Markers, Calcium Metabolism, and Calcium Kinetics During Extended-Duration Space Flight on the Mir Space Station

Smith, Scott M.; Wastney, Meryl E.; O’Brien, Kimberly; Моруков, Б. В.; Ларина, И. М.; Abrams, Steven A.; Davis-Street, Janis; Оганов, В. С.; Shackelford, Linda

doi:10.1359/jbmr.041105

Cited by 217 publications

(205 citation statements)

References 30 publications

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“…Spaceflight decreases trabecular indices of bone formation in the iliac crest of monkeys [37,38], and human astronauts experience an imbalance in bone resorption and bone formation during spaceflight [2,39], which probably causes the cortical bone loss that is observed after 4-6 months in space [40,41]. Similarly, patients with acute spinal cord injury (< 6 months postinjury) experience increased bone resorption and increased urinary calcium excretion, which likely explains why spinal cord injury patients lose bone structural properties and demonstrate increased rates of bone fracture [12,16,42,43].…”

Section: Discussionmentioning

confidence: 99%

Decreased bone turnover with balanced resorption and formation prevent cortical bone loss during disuse (hibernation) in grizzly bears (Ursus arctos horribilis)

McGee

Maki

Johnson

et al. 2008

Bone

102

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Disuse uncouples bone formation from resorption, leading to increased porosity, decreased bone geometrical properties, and decreased bone mineral content which compromises bone mechanical properties and increases fracture risk. However, black bear bone properties are not adversely affected by aging despite annual periods of disuse (i.e., hibernation), which suggests that bears either prevent bone loss during disuse or lose bone and subsequently recover it at a faster rate than other animals. Here we show decreased cortical bone turnover during hibernation with balanced formation and resorption in grizzly bear femurs. Hibernating grizzly bear femurs were less porous and more mineralized, and did not demonstrate any changes in cortical bone geometry or whole bone mechanical properties compared to active grizzly bear femurs. The activation frequency of intracortical remodeling was 75% lower during hibernation than during periods of physical activity, but the normalized mineral apposition rate was unchanged. These data indicate bone turnover decreases during hibernation, but osteons continue to refill at normal rates. There were no changes in regional variation of porosity, geometry, or remodeling indices in femurs from hibernating bears, indicating that hibernation did not preferentially affect one region of the cortex. Thus, grizzly bears prevent bone loss during disuse by decreasing bone turnover and maintaining balanced formation and resorption, which preserves bone structure and strength. These results support the idea that bears possess a biological mechanism to prevent disuse osteoporosis.

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Section: Discussionmentioning

confidence: 99%

Decreased bone turnover with balanced resorption and formation prevent cortical bone loss during disuse (hibernation) in grizzly bears (Ursus arctos horribilis)

McGee

Maki

Johnson

et al. 2008

Bone

102

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“…This follows because the abundances of Ca isotopes in urine and soft tissue represent the net effect of changes in bone formation and resorption and Ca excretion integrated over the 2-to 3-d residence time of Ca in soft tissue compartments (21,22). In contrast, each biochemical marker reflects only one process (either bone resorption or formation).…”

Section: Datamentioning

confidence: 99%

“…In the first study, Smith et al (21) estimated rates of new bone formation of 190-635 mg Ca/d for male and female volunteers. In a follow-up study, the work by Smith et al (22) estimated the rate of bone formation of 16 astronauts at 490 ± 153 mg Ca/d before spaceflight and 434 ± 194 mg Ca/d during spaceflight. F diet .…”

Section: Datamentioning

confidence: 99%

Rapidly assessing changes in bone mineral balance using natural stable calcium isotopes

Morgan

Skulan

Gordon

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

115

104

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The ability to rapidly detect changes in bone mineral balance (BMB) would be of great value in the early diagnosis and evaluation of therapies for metabolic bone diseases such as osteoporosis and some cancers. However, measurements of BMB are hampered by difficulties with using biochemical markers to quantify the relative rates of bone resorption and formation and the need to wait months to years for altered BMB to produce changes in bone mineral density large enough to resolve by X-ray densitometry. We show here that, in humans, the natural abundances of Ca isotopes in urine change rapidly in response to changes in BMB. In a bed rest experiment, use of high-precision isotope ratio MS allowed the onset of bone loss to be detected in Ca isotope data after about 1 wk, long before bone mineral density has changed enough to be detectable with densitometry. The physiological basis of the relationship between Ca isotopes and BMB is sufficiently understood to allow quantitative translation of changes in Ca isotope abundances to changes in bone mineral density using a simple model. The rate of change of bone mineral density inferred from Ca isotopes is consistent with the rate observed by densitometry in long-term bed rest studies. Ca isotopic analysis provides a powerful way to monitor bone loss, potentially making it possible to diagnose metabolic bone disease and track the impact of treatments more effectively than is currently possible.osteopenia | biomarker | medical geology | biosignature | spaceflight

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“…Studies using calcium kinetics, site-specific bone densitometry and bone turnover markers document a net loss of bone mineral in the gravitationally-unloaded skeleton of crew members who had flown either on Skylab (28, 56 and 84 days) or on long-duration missions (>4 months) aboard the Russian Mir spacecraft and the International Space Station (ISS) [2][3][4][5][6][7][8][9][10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Recovery of spaceflight-induced bone loss: Bone mineral density after long-duration missions as fitted with an exponential function

Sibonga

Evans

Sung

et al. 2007

Bone

186

106

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The loss of bone mineral in NASA astronauts during spaceflight has been investigated throughout the more than 40 years of space travel. Consequently, it is a medical requirement at NASA Johnson Space Center (JSC) that changes in bone mass be monitored in crew members by measuring bone mineral density (BMD) with dual-energy x-ray absorptiometry (DXA) before and after flight on astronauts who serve on long-duration missions (4-6 months). We evaluated this repository of medical data to track whether there is recovery of bone mineral that was lost during spaceflight.Our analysis was supplemented by BMD data from cosmonauts (by convention, a space traveler formally employed by the Russia Aviation and Space Agency or by the previous Soviet Union) who had also flown on long-duration missions. Data from a total of 45 individual crew members -a small number of whom flew on more than one mission -were used in this analysis.Changes in BMD (between 56 different sets of pre-and postflight measurements) were plotted as a function of time (days after landing). Plotted BMD changes were fitted to an exponential mathematical function that estimated: i) BMD change on landing day (day 0) and ii) the number of days after landing when 50% of the lost bone would be recovered ("50% recovery time") in the lumbar spine, trochanter, pelvis, femoral neck and calcaneus. In sum, averaged losses of bone mineral after long-duration spaceflight ranged between 2-9% across all sites with our recovery model predicting a 50% restoration of bone loss for all sites to be within 9 months.Recovery of spaceflight-induced bone loss 3

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Bone Markers, Calcium Metabolism, and Calcium Kinetics During Extended-Duration Space Flight on the Mir Space Station

Cited by 217 publications

References 30 publications

Decreased bone turnover with balanced resorption and formation prevent cortical bone loss during disuse (hibernation) in grizzly bears (Ursus arctos horribilis)

Decreased bone turnover with balanced resorption and formation prevent cortical bone loss during disuse (hibernation) in grizzly bears (Ursus arctos horribilis)

Rapidly assessing changes in bone mineral balance using natural stable calcium isotopes

Recovery of spaceflight-induced bone loss: Bone mineral density after long-duration missions as fitted with an exponential function

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