Fitting of Bone Mineral Density with Consideration of Anthropometric Parameters

David F. Short, Babette S. Zemel, Vicente Gilsanz, Heidi J. Kalkwarf, Joan M. Lappe, Soroosh Mahboubi, Sharon Oberfield, John A. Shepherd, Karen K. Winer, Thomas N. Hangartner

Research output: Contribution to journalArticlepeer-review

Abstract

Summary A new model describing normal values of bone mineral density in children has been evaluated, which includes not only the traditional parameters of age, gender, and race, but also weight, height, percent body fat, and sexual maturity. This model may constitute a better comparative norm for a specific child with given anthropometric values.

Introduction Previous descriptions of children’s bone mineral density (BMD) by age have focused on segmenting diverse populations by race and gender without adjusting for anthropometric variables or have included the effects of anthropometric variables over a relatively homogeneous population.

Methods Multivariate semi-metric smoothing (MS 2 ) provides a way to describe a diverse population using a model that includes multiple effects and their interactions while producing a result that can be smoothed with respect to age in order to provide connected percentiles. We applied MS 2 to spine BMD data from the Bone Mineral Density in Childhood Study to evaluate which of gender, race, age, height, weight, percent body fat, and sexual maturity explain variations in the population’s BMD values. By balancing high adjusted R 2 values and low mean square errors with clinical needs, a model using age, gender, race, weight, and percent body fat is proposed and examined.

Results This model provides narrower distributions and slight shifts of BMD values compared to the traditional model, which includes only age, gender, and race. Thus, the proposed model might constitute a better comparative standard for a specific child with given anthropometric values and should be less dependent on the anthropometric characteristics of the cohort used to devise the model. Conclusions The inclusion of multiple explanatory variables in the model, while creating smooth output curves, makes the MS 2 method attractive in modeling practically sized data sets. The clinical use of this model by the bone research community has yet to be fully established.

Original languageAmerican English
JournalOsteoporosis International
Volume22
DOIs
StatePublished - Apr 1 2011

Keywords

  • Bone
  • Bone growth
  • Bone mineral density
  • Model fitting
  • Orthogonal transformation
  • Smoothing

Disciplines

  • Biomedical Engineering and Bioengineering
  • Engineering
  • Industrial Engineering
  • Operations Research, Systems Engineering and Industrial Engineering

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