Literature DB >> 25440183

Peak Bone Mass and Patterns of Change in Total Bone Mineral Density and Bone Mineral Contents From Childhood Into Young Adulthood.

Juan Lu1, Yongyun Shin2, Miao-Shan Yen2, Shumei S Sun3.   

Abstract

The literature has not reached a consensus on the age when peak bone mass is achieved. This study examines growth patterns of total bone mineral content (TBMC) and total bone mineral density (TBMD), peak bone mass, effect of concurrent anthropometry measures, and physical activity on growth patterns in a sample of 312 white males and 343 females aged 8-30 yr. We analyzed data from participants enrolled in Fels Longitudinal Study. Descriptive analysis was used to ascertain characteristics of participants and growth patterns of TBMC and TBMD. Mixed effects models were applied to predict ages at attainment of peak TBMC and TBMD and assess the effects of height, weight, body mass index (BMI), and habitual physical activity on the attainment. Significant differences between sexes were observed for measures of TBMC and TBMD, and differences varied with age. For females, predicted median ages at peak TBMC and TBMD attainments are 21.96 yr (interquartile range [IQR]: 21.81-22.21) and 22.31 yr (IQR: 21.95-22.59), respectively. For males, predicted median ages are 23.34 yr (IQR: 24.34-26.19) and 26.86 yr (IQR: 25.14-27.98) respectively. For females, height, weight, and BMI, but not physical activity, had significant influences on attainment of TBMC and TBMD (p<0.01). For males, weight and BMI, but not height and physical activity, exerted significant influence on attainment of TBMC and TBMD (p<0.01), and also modified correlations between age and peak TBMC and TBMD. Our results suggest that (1) for both sexes, trajectories of TBMC and TBMD follow a curvilinear pattern between ages 8 and 30 yr; (2) predicted ages at peak TBMC and TBMD are from early to late 20s for both white males and females, with females reaching their peaks significantly earlier than males; and (3) concurrent height, weight, and BMI, but not habitual physical activity, exert significant effects on trajectories of TBMC and TBMD.
Copyright © 2016 The International Society for Clinical Densitometry. Published by Elsevier Inc. All rights reserved.

Entities:  

Keywords:  Body bone mineral content; body bone mineral density; dual-energy X-ray absorptiometry

Mesh:

Year:  2014        PMID: 25440183      PMCID: PMC4402109          DOI: 10.1016/j.jocd.2014.08.001

Source DB:  PubMed          Journal:  J Clin Densitom        ISSN: 1094-6950            Impact factor:   2.617


  32 in total

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  17 in total

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Authors:  E How Shing Koy; A Amouzougan; E Biver; R Chapurlat; T Chevalley; S L Ferrari; A Fouilloux; H Locrelle; H Marotte; M Normand; R Rizzoli; L Vico; T Thomas
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Review 3.  Similarities Between Disuse and Age-Induced Bone Loss.

Authors:  Evan G Buettmann; Galen M Goldscheitter; Gabriel A Hoppock; Michael A Friedman; Larry J Suva; Henry J Donahue
Journal:  J Bone Miner Res       Date:  2022-07-28       Impact factor: 6.390

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5.  Skeletal Effects of Nine Months of Physical Activity in Obese and Healthy Weight Children.

Authors:  Vineel Kondiboyina; Lauren B Raine; Arthur F Kramer; Naiman A Khan; Charles H Hillman; Sandra J Shefelbine
Journal:  Med Sci Sports Exerc       Date:  2020-02

Review 6.  Preclinical models for investigating how bone marrow adipocytes influence bone and hematopoietic cellularity.

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7.  Comparison of Measurements of Bone Mineral Density in Young and Middle-Aged Adult Women in Relation to Dietary, Anthropometric and Reproductive Variables.

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8.  Physical exercise associated with improved BMD independently of sex and vitamin D levels in young adults.

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9.  AKAP11 gene polymorphism is associated with bone mass measured by quantitative ultrasound in young adults.

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10.  A Case Report of Mixed Osteomalacia and Low Bone Density from Vitamin D Deficiency as a Cause of Bilateral Tibial Stress Fractures in a Young Male Military Recruit from Singapore.

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