通用电气/路娜笔式和扇形束双能骨密度仪的交叉校准——骨矿物质密度和身体成分研究

Cross-calibration of GE/Lunar pencil and fan-beam dual energy densitometers--bone mineral density and body composition studies.

作者信息

Oldroyd B, Smith A H, Truscott J G

机构信息

Centre for Bone and Body Composition Research, University of Leeds, UK.

出版信息

Eur J Clin Nutr. 2003 Aug;57(8):977-87. doi: 10.1038/sj.ejcn.1601633.

DOI:10.1038/sj.ejcn.1601633

PMID:12879093

Abstract

OBJECTIVE

In vitro and in vivo comparisons of bone mineral density (BMD) and body composition between GE/Lunar pencil (DPXL) and fan-beam (PRODIGY) absorptiometers.

DESIGN

Comparison of BMD, bone mineral content (BMC) and area of lumbar spine (L2-L4), femoral neck and total body. Total body composition compartments tissue (TBTissue), fat (TBF), lean tissue (TBLean) and %TBF were also compared.

SETTING

Centre for Bone and Body Composition Research, University of Leeds. PHANTOMS/SUBJECTS: A range of spine phantoms, a variable composition phantom (VCP) and total body phantom. A total of 72 subjects were included for the in vivo study.

RESULTS

In vitro: A small significant underestimation of BMD by the Prodigy compared to the DPXL ranging from 0.7 to 2% (p<0.05-0.001) for the spine phantoms. The Prodigy underestimated the VCP %Fat. Although the Prodigy underestimated phantom TBBMD by 1.1+/-1.0%, TBBMC and area were reduced by 8.2+/-1.4 and 7.3+/-1.0%, respectively. The Prodigy overestimated TBTissue 1508 g (2.2%), TBLean 588 g (1.2%), TBF 919 g (4.8%) and %TBF (0.8%). In vivo: BMD cross-calibration was only required in the femoral neck, DPXL(BMD)=0.08+0.906PRODIGY(BMD). The Prodigy had higher estimates for TBTissue 1360 g (2.3%), TBLean 840 g (2.0%), TBF 519 g (3.4%), TBBMC 32.8 g (1.3%) and %TBF (0.3%). Cross-calibration equations were required for TBTissue(DPXL)=-1158+0.997TBTissue(PRODIGY) and TBBMC(DPXL)= 89.7+0.949*TBBMC(PRODIGY).

CONCLUSIONS

Small differences between the two absorptiometers for both BMD and body composition can be made compatible by use of cross-calibration equations and factors. The discrepancy in body composition compartments requires further research.

摘要

目的

对GE/Lunar笔式（DPXL）和扇形束（PRODIGY）骨密度仪的骨矿物质密度（BMD）和身体成分进行体外和体内比较。

设计

比较腰椎（L2-L4）、股骨颈和全身的骨密度（BMD）、骨矿物质含量（BMC）和面积。还比较了全身成分各组织（TBTissue）、脂肪（TBF）、瘦组织（TBLean）和TBF百分比。

地点

利兹大学骨与身体成分研究中心。

模型/受试者：一系列脊柱模型、可变成分模型（VCP）和全身模型。共有72名受试者纳入体内研究。

结果

体外：与DPXL相比，Prodigy对脊柱模型的BMD有轻微但显著的低估，范围为0.7%至2%（p<0.05-0.001）。Prodigy低估了VCP的脂肪百分比。尽管Prodigy将模型的全身骨密度（TBBMD）低估了1.1±1.0%，但全身骨矿物质含量（TBBMC）和面积分别减少了8.2±1.4%和7.3±1.0%。Prodigy高估了TBTissue 1508克（2.2%）、TBLean 588克（1.2%）、TBF 919克（4.8%）和TBF百分比（0.8%）。体内：仅在股骨颈需要进行BMD交叉校准，DPXL（BMD）=0.08 + 0.906×PRODIGY（BMD）。Prodigy对TBTissue的估计值更高，为1360克（2.3%）、TBLean为840克（2.0%）、TBF为519克（3.4%）、TBBMC为32.8克（1.3%）和TBF百分比为（0.3%）。TBTissue（DPXL）=-1158 + 0.997×TBTissue（PRODIGY）和TBBMC（DPXL）= 89.7 + 0.949×TBBMC（PRODIGY）需要交叉校准方程。

结论

通过使用交叉校准方程和系数，可以使两种骨密度仪在BMD和身体成分方面的微小差异变得兼容。身体成分各部分的差异需要进一步研究。

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通用电气/路娜笔式和扇形束双能骨密度仪的交叉校准——骨矿物质密度和身体成分研究

Cross-calibration of GE/Lunar pencil and fan-beam dual energy densitometers--bone mineral density and body composition studies.

作者信息

机构信息

出版信息

OBJECTIVE

DESIGN

SETTING

RESULTS

CONCLUSIONS

目的

设计

地点

结果

结论

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