Head, Neck, Trunk, and Pelvis Tissue Mass Predictions for Older Adults using Anthropometric Measures and Dual-Energy X-Ray Absorptiometry

Q3 Health Professions

International Journal of Kinesiology and Sports Science Pub Date : 2020-07-31 DOI:10.7575/aiac.ijkss.v.8n.3p.14

Charles Kahelin, Nicole C. George, Danielle L. Gyemi, D. Andrews

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引用次数: 1

Abstract

Background: Regression equations using anthropometric measurements to predict soft (fat mass [FM], lean mass [LM], wobbling mass [WM]) and rigid (bone mineral content [BMC]) tissue masses of the extremities and core body segments have been developed for younger adults (16-35 years), but not older adults (36-65 years). Tissue mass estimates such as these would facilitate biomechanical modeling and analyses of older adults following fall or collision-related impacts that might occur during sport and recreational activities. Purpose: The purpose of this study was to expand on the previously established tissue mass prediction equations of the head, neck, trunk, and pelvis for healthy, younger adults by generating a comparable set of equations for an older adult population. Methods: A generation sample (38 males, 38 females) was used to create head, neck, trunk, and pelvis tissue mass prediction equations via multiple linear stepwise regression. A validation sample (13 males, 12 females) was used to assess equation accuracy; actual tissue masses were acquired from manually segmented full body Dual-Energy X-ray Absorptiometry scans. Results: Adjusted R2 values for the prediction equations ranged from 0.326 to 0.949, where BMC equations showed the lowest explained variances overall. Mean relative errors between actual and predicted masses ranged from –2.6% to 6.1% for trunk LM and FM, respectively. All actual tissue masses except head BMC (R2 = 0.092) were significantly correlated to those predicted from the equations (R2 = 0.403 to 0.963). Conclusion: This research provides a simple and effective method for predicting head, neck, trunk, and pelvis tissue masses in older adults that can be incorporated into biomechanical models for analyzing sport and recreational activities. Future work with this population should aim to improve core segment BMC predictions and develop equations for the extremities.

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使用人体测量和双能X射线吸收法预测老年人的头、颈、躯干和骨盆组织质量

背景:使用人体测量的回归方程来预测四肢和核心身体部分的软(脂肪量[FM]，瘦质量[LM]，摇摆质量[WM])和刚性(骨矿物质含量[BMC])组织质量已经为年轻人(16-35岁)开发，但没有老年人(36-65岁)。诸如此类的组织质量估计将有助于对老年人在运动和娱乐活动中可能发生的跌倒或碰撞相关影响进行生物力学建模和分析。目的:本研究的目的是通过生成一组适用于老年人的可比方程，扩展先前建立的健康年轻人的头部、颈部、躯干和骨盆组织质量预测方程。方法:采用多元线性逐步回归方法建立头、颈、躯干和骨盆组织质量预测方程。采用验证样本(男性13人，女性12人)评估方程准确性;实际组织肿块通过人工分割的全身双能x线吸收仪扫描获得。结果:预测方程调整后的R2值在0.326 ~ 0.949之间，BMC方程总体上解释方差最低。主干LM和FM的实际质量和预测质量之间的平均相对误差分别在-2.6%到6.1%之间。除头部BMC (R2 = 0.092)外，所有实际组织质量与方程预测值(R2 = 0.403 ~ 0.963)显著相关。结论:本研究为预测老年人头部、颈部、躯干和骨盆组织肿块提供了一种简单有效的方法，可将其纳入生物力学模型，用于分析运动和娱乐活动。未来与这一人群的工作应该旨在改善核心段BMC预测和发展四肢方程。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Kinesiology and Sports Science Health Professions-Physical Therapy, Sports Therapy and Rehabilitation

CiteScore

1.80

自引率

0.00%

发文量