¹⁸F-氟化物 PET 骨骼动力学研究在评估骨代谢中的准确性。

Precision of ¹⁸F-fluoride PET skeletal kinetic studies in the assessment of bone metabolism.

机构信息

Osteoporosis Screening & Research Unit, Guy's Hospital, King's College London, 1st Floor, Tower Wing, London, SE1 9RT, UK.

出版信息

Osteoporos Int. 2012 Oct;23(10):2535-41. doi: 10.1007/s00198-011-1889-2. Epub 2012 Jan 12.

DOI:10.1007/s00198-011-1889-2

PMID:22237817

Abstract

UNLABELLED

We assessed the precision of lumbar spine (18)F-PET measurements based on 58 scans performed on 20 postmenopausal women. The percentage coefficient of variation (%CV) (95% confidence interval) was 9.2% (7.5-11.8) for standardised uptake values, 11.7% (9.5-14.9) for plasma clearance measurements using the Patlak method and 14.5% (11.7-18.5) for plasma clearance measurements using the Hawkins three-compartment model.

INTRODUCTION

(18)F-Fluoride positron emission tomography ((18)F-PET) is a non-invasive technique that allows the assessment of regional bone turnover in patients with metabolic bone disease. Knowledge of the precision errors of (18)F-PET measurements is important for planning the number of subjects required for research studies.

METHODS

Twenty osteoporotic postmenopausal women had (18)F-PET scans of the lumbar spine at 0, 6 and 12 months after stopping long-term bisphosphonate treatment. No significant changes in the PET measurements were seen over the 12-month period, and the data were deemed suitable for a precision study. Precision errors were evaluated for standardised uptake values (SUVs) and for the fluoride plasma clearance to bone mineral (K (i)) determined using the Patlak and Hawkins methods. Precision errors were expressed as the %CV and were calculated for the mean L1-L4 region and for individual vertebrae.

RESULTS

%CV (95% confidence interval) for the L1-L4 region was 9.2% (7.5-11.8) for SUV, 11.7% (9.5-14.9) for K (i) measured using the Patlak method and 14.5% (11.7-18.5) for K (i) measured using the Hawkins method. There was no significant difference between precision errors obtained for the L1-L4 region and those obtained for a single vertebra.

CONCLUSIONS

SUV measurements showed the smallest precision error followed by the Patlak method, while the Hawkins method gave the largest error. Measuring a smaller region of interest did not increase the precision error, suggesting that the factor determining the errors may be scanner calibration.

摘要

未加标签

我们评估了基于 20 名绝经后女性 58 次腰椎扫描的（18）F-PET 测量的精密度。标准化摄取值的变异系数（%CV）（95%置信区间）为 9.2%（7.5-11.8），Patlak 法的血浆清除率测量为 11.7%（9.5-14.9），Hawkins 三房室模型的血浆清除率测量为 14.5%（11.7-18.5）。

引言

（18）F-氟化物正电子发射断层扫描（（18）F-PET）是一种非侵入性技术，可评估代谢性骨病患者的局部骨转换。了解（18）F-PET 测量的精密度误差对于规划研究研究所需的受试者数量很重要。

方法

20 名骨质疏松绝经后女性在停止长期双膦酸盐治疗后 0、6 和 12 个月时进行腰椎（18）F-PET 扫描。在 12 个月期间，PET 测量未见明显变化，数据适合精密度研究。使用 Patlak 和 Hawkins 方法分别评估标准化摄取值（SUV）和氟化物血浆清除至骨矿物质（K（i））的精密度误差。精密度误差表示为%CV，并计算 L1-L4 区域的平均值和各个椎体的精密度误差。

结果

L1-L4 区域的%CV（95%置信区间）为 SUV 为 9.2%（7.5-11.8），Patlak 法测定的 K（i）为 11.7%（9.5-14.9），Hawkins 法测定的 K（i）为 14.5%（11.7-18.5）。L1-L4 区域的精密度误差与单个椎体的精密度误差无显著差异。

结论

SUV 测量的精密度误差最小，其次是 Patlak 法，而 Hawkins 法的误差最大。测量较小的感兴趣区域不会增加精密度误差，这表明决定误差的因素可能是扫描仪校准。

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¹⁸F-氟化物 PET 骨骼动力学研究在评估骨代谢中的准确性。

Precision of ¹⁸F-fluoride PET skeletal kinetic studies in the assessment of bone metabolism.

机构信息

出版信息

UNLABELLED

INTRODUCTION

METHODS

RESULTS

CONCLUSIONS

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引言

方法

结果

结论

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