磁共振成像采集参数对小腔血管模型中相位对比测量准确度和精确度的影响。

IF 3.7 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
Maria Correia de Verdier, Johan Berglund, Johan Wikström
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引用次数: 0

摘要

背景:相位对比磁共振成像(PC-MRI)可无创量化血流和血流速度。由于血管较小,在神经血管疾病中会遇到挑战。我们在小腔血管模型中评估了体素大小、信号平均值数量(NSA)和速度编码(VENC)对 PC-MRI 测量准确度和精确度的影响:我们使用内径为 2.2 毫米的塑料管构建了一个恒定流速的体外模型。一个带有重量刻度和计时器的蓄水池被用作标准参考。梯度回波 T1 加权 PC-MRI 序列在 3-T 扫描仪上进行,体素大小(2.5、5.0、7.5 mm3)、NSA(1、2、3)和 VENC(200、300、400 cm/s)各不相同。我们在每种设置下重复测量九次,计算平均流速、最大速度和最小可检测差异(LDD):结果:PC-MRI 流量测量值高于标准参考值(平均值为 7.3 至 9.5 mL/s,而标准参考值为 6.6 mL/s)。缩小体素尺寸提高了准确性,使流速测量值从 9.5 mL/s 降至 7.3 mL/s。流速和速度的 LDD 变化范围在 1% 到 5% 之间。流速的 LDD 随体素尺寸和 NSA 的增加而降低(p = 0.033 和 0.042)。流速的 LDD 随体素大小的增加而降低(p -16)。当 VENC 变化时,未观察到任何变化:结论:PC-MRI 高估了血流。然而,在流速恒定的小血管模型中,PC-MRI 的精确度很高。随着空间分辨率(更小的体素)的提高,准确性也会提高。随着信噪比的增加(更大的体素和/或更高的 NSA),精确度也会提高:相位对比 MRI 在临床上用于大血管。为了进一步研究将相位对比 MRI 用于神经血管疾病中较小颅内血管的可能性,我们需要了解采集参数如何影响相位对比 MRI 测量的小血管中的流速和血流速度:- PC-MRI 可高精度测量小腔模型中的流量和流速,但会高估流速。- PC-MRI 测量的精度与流速测量的标准参考精度相匹配。- 优化 PC-MRI 设置可提高流速和速度测量的准确性和精确度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Effect of MRI acquisition parameters on accuracy and precision of phase-contrast measurements in a small-lumen vessel phantom.

Effect of MRI acquisition parameters on accuracy and precision of phase-contrast measurements in a small-lumen vessel phantom.

Background: Phase-contrast magnetic resonance imaging (PC-MRI) quantifies blood flow and velocity noninvasively. Challenges arise in neurovascular disorders due to small vessels. We evaluated the impact of voxel size, number of signal averages (NSA), and velocity encoding (VENC) on PC-MRI measurement accuracy and precision in a small-lumen vessel phantom.

Methods: We constructed an in vitro model with a constant flow rate using a 2.2-mm inner diameter plastic tube. A reservoir with a weight scale and timer was used as standard reference. Gradient-echo T1 weighted PC-MRI sequence was performed on a 3-T scanner with varying voxel size (2.5, 5.0, 7.5 mm3), NSA (1, 2, 3), and VENC (200, 300, 400 cm/s). We repeated measurements nine times per setting, calculating mean flow rate, maximum velocity, and least detectable difference (LDD).

Results: PC-MRI flow measurements were higher than standard reference values (mean ranging from 7.3 to 9.5 mL/s compared with 6.6 mL/s). Decreased voxel size improved accuracy, reducing flow rate measurements from 9.5 to 7.3 mL/s. The LDD for flow rate and velocity varied between 1 and 5%. The LDD for flow rate decreased with increased voxel size and NSA (p = 0.033 and 0.042). The LDD for velocity decreased with increased voxel size (p < 10-16). No change was observed when VENC varied.

Conclusions: PC-MRI overestimated flow. However, it has high precision in a small-vessel phantom with constant flow rate. Improved accuracy was obtained with increasing spatial resolution (smaller voxels). Improved precision was obtained with increasing signal-to-noise ratio (larger voxels and/or higher NSA).

Relevance statement: Phase-contrast MRI is clinically used in large vessels. To further investigate the possibility of using phase-contrast MRI for smaller intracranial vessels in neurovascular disorders, we need to understand how acquisition parameters affect phase-contrast MRI-measured flow rate and velocity in small vessels.

Key points: • PC-MRI measures flow and velocity in a small lumen phantom with high precision but overestimates flow rate. • The precision of PC-MRI measurements matches the precision of standard reference for flow rate measurements. • Optimizing PC-MRI settings can enhance accuracy and precision in flow rate and velocity measurements.

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来源期刊
European Radiology Experimental
European Radiology Experimental Medicine-Radiology, Nuclear Medicine and Imaging
CiteScore
6.70
自引率
2.60%
发文量
56
审稿时长
18 weeks
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