用于定量神经学FDG PET研究的两种基于人群的输入函数评估。

Evaluation of two population-based input functions for quantitative neurological FDG PET studies.

作者信息

Eberl S, Anayat A R, Fulton R R, Hooper P K, Fulham M J

机构信息

PET Department, Royal Prince Alfred Hospital, Sydney, Australia.

出版信息

Eur J Nucl Med. 1997 Mar;24(3):299-304. doi: 10.1007/BF01728767.

DOI:10.1007/BF01728767

PMID:9143468

Abstract

The conventional measurement of the regional cerebral metabolic rate of glucose (rCMRGlc) with fluorodeoxyglucose (FDG) and positron emission tomography (PET) requires arterial or arterialised-venous (a-v) blood sampling at frequent intervals to obtain the plasma input function (IF). We evaluated the accuracy of rCMR-Glc measurements using population-based IFs that were calibrated with two a-v blood samples. Population-based IFs were derived from: (1) the average of a-v IFs from 26 patients (Standard IF) and (2) a published model of FDG plasma concentration (Feng IF). Values for rCMRGlc calculated from the population-based IFs were compared with values obtained with IFs derived from frequent a-v blood sampling in 20 non-diabetic and six diabetic patients. Values for rCMRGlc calculated with the different IFs were highly correlated for both patient groups (r > or = 0.992) and root mean square residuals about the regression line were less than 0.24 mg/min/100 g. The Feng IF tended to underestimate high rCMRGlc. Both population-based IFs simplify the measurement of rCMRGlc with minimal loss in accuracy and require only two a-v blood samples for calibration. The reduced blood sampling requirements markedly reduce radiation exposure to the blood sampler.

摘要

使用氟脱氧葡萄糖（FDG）和正电子发射断层扫描（PET）对局部脑葡萄糖代谢率（rCMRGlc）进行传统测量时，需要频繁采集动脉血或动脉化静脉血（a-v）样本以获取血浆输入函数（IF）。我们使用基于人群的IF对rCMR-Glc测量的准确性进行了评估，这些IF是通过两份a-v血样校准得到的。基于人群的IF来自：（1）26名患者的a-v IF的平均值（标准IF）和（2）一个已发表的FDG血浆浓度模型（Feng IF）。将基于人群的IF计算得到的rCMRGlc值与20名非糖尿病患者和6名糖尿病患者通过频繁采集a-v血样得到的IF计算得到的值进行比较。对于两组患者，不同IF计算得到的rCMRGlc值高度相关（r≥0.992），且回归线的均方根残差小于0.24mg/min/100g。Feng IF倾向于低估高rCMRGlc值。两种基于人群的IF都简化了rCMRGlc的测量，准确性损失最小，且仅需两份a-v血样进行校准。减少的血样采集需求显著降低了对采血者的辐射暴露。

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用于定量神经学FDG PET研究的两种基于人群的输入函数评估。

Evaluation of two population-based input functions for quantitative neurological FDG PET studies.

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