动脉首过CT心肌灌注成像的最佳图像采集时机
Optimal timing of image acquisition for arterial first pass CT myocardial perfusion imaging.
作者信息
Pelgrim G J, Nieuwenhuis E R, Duguay T M, van der Geest R J, Varga-Szemes A, Slump C H, Fuller S R, Oudkerk M, Schoepf U J, Vliegenthart R
机构信息
University of Groningen, University Medical Center Groningen, Center for Medical Imaging North East Netherlands (CMI-nen), Hanzeplein 1, 9713 GZ Groningen, The Netherlands.
University of Groningen, University Medical Center Groningen, Center for Medical Imaging North East Netherlands (CMI-nen), Hanzeplein 1, 9713 GZ Groningen, The Netherlands; University of Twente, P.O. Box 217, 7500 AE, Enschede, The Netherlands.
出版信息
Eur J Radiol. 2017 Jan;86:227-233. doi: 10.1016/j.ejrad.2016.11.024. Epub 2016 Nov 23.
PURPOSE
To determine the optimal timing of arterial first pass computed tomography (CT) myocardial perfusion imaging (CTMPI) based on dynamic CTMPI acquisitions.
METHODS AND MATERIALS
Twenty-five patients (59±8.4years, 14 male)underwent adenosine-stress dynamic CTMPI on second-generation dual-source CT in shuttle mode (30s at 100kV and 300mAs). Stress perfusion magnetic resonance imaging (MRI) was used as reference standard for differentiation of non-ischemic and ischemic segments. The left ventricle (LV) wall was manually segmented according to the AHA 16-segment model. Hounsfield units (HU) in myocardial segments and ascending (AA) and descending aorta (AD) were monitored over time. Time difference between peak AA and peak AD and peak myocardial enhancement was calculated, as well as the, time delay from fixed HU thresholds of 150 and 250 HU in the AA and AD to a minimal difference of 15 HU between normal and ischemic segments. Furthermore, the duration of the 15 HU difference between ischemic and non-ischemic segments was calculated.
RESULTS
Myocardial ischemia was observed by MRI in 10 patients (56.3±9.0years; 8 male). The delay between the maximum HU in the AA and AD and maximal HU in the non-ischemic segments was 2.8s [2.2-4.3] and 0.0s [0.0-2.8], respectively. Differentiation between ischemic and non-ischemic myocardial segments in CT was best during a time window of 8.6±3.8s. Time delays for AA triggering were 4.5s [2.2-5.6] and 2.2s [0-2.8] for the 150 HU and 250 HU thresholds, respectively. While for AD triggering, time delays were 2.4s [0.0-4.8] and 0.0s [-2.2-2.6] for the 150 HU and 250 HU thresholds, respectively.
CONCLUSION
In CTMPI, the differentiation between normal and ischemic myocardium is best accomplished during a time interval of 8.6±3.8s. This time window can be utilized by a test bolus or bolus tracking in the AA or AD using the time delays identified here.
目的
基于动态CT心肌灌注成像(CTMPI)采集确定动脉首过CT心肌灌注成像的最佳时机。
方法和材料
25例患者(年龄59±8.4岁,男性14例)在第二代双源CT上以穿梭模式(100kV、300mAs下30秒)接受腺苷负荷动态CTMPI检查。负荷灌注磁共振成像(MRI)用作区分非缺血和缺血节段的参考标准。根据美国心脏协会(AHA)16节段模型手动分割左心室(LV)壁。随时间监测心肌节段以及升主动脉(AA)和降主动脉(AD)中的亨氏单位(HU)。计算AA峰值与AD峰值以及心肌增强峰值之间的时间差,以及从AA和AD中150 HU和250 HU的固定HU阈值到正常节段与缺血节段之间最小差值15 HU的时间延迟。此外,计算缺血节段与非缺血节段之间15 HU差值的持续时间。
结果
MRI观察到10例患者存在心肌缺血(年龄56.3±9.0岁;男性8例)。AA和AD中的最大HU与非缺血节段中的最大HU之间的延迟分别为2.8秒[2.2 - 4.3]和0.0秒[0.0 - 2.8]。CT中缺血和非缺血心肌节段的区分在8.6±3.8秒的时间窗内最佳。对于150 HU和250 HU阈值,AA触发的时间延迟分别为4.5秒[2.2 - 5.6]和2.2秒[0 - 2.8]。而对于AD触发,150 HU和250 HU阈值的时间延迟分别为2.4秒[0.0 - 4.8]和0.0秒[-2.2 - 2.6]。
结论
在CTMPI中,正常心肌与缺血心肌之间的区分在8.6±3.8秒的时间间隔内最佳。该时间窗可通过使用此处确定的时间延迟在AA或AD中进行试验性团注或团注追踪来利用。
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