Changes in Bone Mineral Density with Age in Men and Women: A Longitudinal Study

Warming, Lise; Hassager, Christian; Christiansen, Claus

doi:10.1007/s001980200001

Cited by 300 publications

(198 citation statements)

References 26 publications

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“…While the cumulative influence of genes on ΔBMD is large, the contribution of environmental factors is also important; measured covariates accounted for 10% to 28% of phenotypic variation. Associations with BMD of several of the environmental correlates identified in this study, including age, female sex, postmenopausal status, low body weight, and weight loss, have been detected in previous studies [11][12][13]37]. Interestingly, we observed differences in magnitude and direction for ΔBMD across skeletal sites, as has been observed by others, although not always for the same sites [9][10][11].…”

Section: Discussionsupporting

confidence: 87%

“…Cross-sectional study designs cannot sufficiently distinguish between processes leading to peak BMD acquisition versus loss with age, and this has been a persistent limitation of cross-sectional epidemiological and genetic studies of BMD, particularly those carried out in older individuals since such studies cannot allow for variation in rates of change in BMD during aging. Longitudinal studies have shown that weight, interim change in weight, alcohol consumption, smoking, sex, estrogen replacement therapy, menopausal status, exercise, calcium intake, and serum vitamin D level may affect change in BMD over time, and that rates of BMD change may differ among skeletal sites [9][10][11][12][13]. Rate of bone loss as a risk factor for fracture independent of bone mass has recently been reported in a cohort of postmenopausal women (mean age of 62 years) [14], reinforcing the clinical importance of change in BMD for bone health.…”

Section: Introductionmentioning

confidence: 99%

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Genetic influences on bone loss in the San Antonio Family Osteoporosis study

et al. 2008

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Section: Discussionsupporting

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Genetic influences on bone loss in the San Antonio Family Osteoporosis study

et al. 2008

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“…Bone mineral levels in the upper extremity normally decline with age [51]. However, we did not find such a correlation in our study.…”

Section: Predictors Of Bone Mineral Content In Paretic Armcontrasting

confidence: 92%

Muscle strength is a determinant of bone mineral content in the hemiparetic upper extremity: Implications for stroke rehabilitation

Pang

Eng

2005

Bone

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Individuals with stroke have a high incidence of bone fractures and approximately 30% of these fractures occur in the upper extremity. The high risk of falls and the decline in bone and muscle health make the chronic stroke population particularly prone to upper extremity fractures. This was the first study to investigate the bone mineral content (BMC), bone mineral density (BMD) and soft tissue composition of the upper extremities and their relationship to stroke-related impairments in ambulatory individuals with chronic stroke (onset >1 year). Dual-energy X-ray absorptiometry (DXA) was used to acquire total body scans on 56 (22 women) communitydwelling individuals (≥50 years of age) with chronic stroke. BMC (g) and BMD (g/cm 2 ), lean mass (g) and fat mass (g) for each arm were derived from the total body scans. The paretic upper extremity was evaluated for muscle strength (hand-held dynamometry), spasticity (Modified Ashworth Scale), impairment of motor function (Fugl-Meyer Motor Assessment) and amount of use of the paretic arm in daily activities (Motor Activity Log). Results showed that the paretic arm had significantly lower BMC (13.8%, p<0.001), BMD (4.5%, p<0.001) and lean mass (9.0%, p<0.001) but higher fat mass (6.3%, p=0.028) than the non-paretic arm. Multiple regression analysis showed that lean mass in the paretic arm, height and muscle strength were significant predictors (R 2 =0.810, p<0.001) of the paretic arm BMC. Height, muscle strength and gender were significant predictors (R 2 =0.822, p<0.001) of lean mass in the paretic arm. These results highlight the potential of muscle strengthening to promote bone health of the paretic arm in individuals with chronic stroke.

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“…Dozens of clinical phenotypes, such as Parkinson's (Reeve et al ., 2014), AD (McAuley et al ., 2009), body mass index, blood pressure (Mungreiphy et al ., 2011) and bone mineral density (Warming et al ., 2002), as well as lifestyle parameters, such as nutrition (Wieser et al ., 2011), smoking and physical activity, are strongly related to age (Harman, 1988; Wang et al ., 2009). Composite measures such as the Rockwood frailty index (Rockwood & Mitnitski, 2007) combine several of those clinical traits to form a more homogenous phenotype – frailty – from its diverse appearance.…”

Section: Omics and Agingmentioning

confidence: 99%

“…In contrast, biological age is a broader concept that takes the individual physical and mental health into account, thus capturing individual differences of the aging process. Most aging studies search for associations of chronological age with clinical and molecular phenotypes (Warming et al ., 2002). However, several studies used phenotypes, such as lung function, grip strength or bone mineral density, as proxies to investigate molecular changes in biological aging (Jackson et al ., 2003; Bell et al ., 2012; Levine, 2013).…”

Section: Introductionmentioning

confidence: 99%

Integration of ‘omics’ data in aging research: from biomarkers to systems biology

et al. 2015

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SummaryAge is the strongest risk factor for many diseases including neurodegenerative disorders, coronary heart disease, type 2 diabetes and cancer. Due to increasing life expectancy and low birth rates, the incidence of age‐related diseases is increasing in industrialized countries. Therefore, understanding the relationship between diseases and aging and facilitating healthy aging are major goals in medical research. In the last decades, the dimension of biological data has drastically increased with high‐throughput technologies now measuring thousands of (epi) genetic, expression and metabolic variables. The most common and so far successful approach to the analysis of these data is the so‐called reductionist approach. It consists of separately testing each variable for association with the phenotype of interest such as age or age‐related disease. However, a large portion of the observed phenotypic variance remains unexplained and a comprehensive understanding of most complex phenotypes is lacking. Systems biology aims to integrate data from different experiments to gain an understanding of the system as a whole rather than focusing on individual factors. It thus allows deeper insights into the mechanisms of complex traits, which are caused by the joint influence of several, interacting changes in the biological system. In this review, we look at the current progress of applying omics technologies to identify biomarkers of aging. We then survey existing systems biology approaches that allow for an integration of different types of data and highlight the need for further developments in this area to improve epidemiologic investigations.

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Changes in Bone Mineral Density with Age in Men and Women: A Longitudinal Study

Cited by 300 publications

References 26 publications

Genetic influences on bone loss in the San Antonio Family Osteoporosis study

Genetic influences on bone loss in the San Antonio Family Osteoporosis study

Muscle strength is a determinant of bone mineral content in the hemiparetic upper extremity: Implications for stroke rehabilitation

Integration of ‘omics’ data in aging research: from biomarkers to systems biology

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