Phantom-based gradient waveform measurements with compensated variable-prephasing: Description and application to EPI at 7T

arXiv - PHYS - Medical Physics Pub Date : 2024-09-11 DOI:arxiv-2409.07203

Hannah Scholten, Tobias Wech, Istvan Homolya, Herbert Köstler

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Abstract

Purpose: Introducing "compensated variable-prephasing" (CVP), a phantom-based method for gradient waveform measurements. The technique is based on the "variable-prephasing" (VP) method, but takes into account the effects of all gradients involved in the measurement. Methods: We conducted measurements of a trapezoidal test gradient, and of an EPI readout gradient train with three approaches: VP, CVP, and "fully compensated variable-prephasing" (FCVP). We compared them to one another and to predictions based on the gradient system transfer function. Furthermore, we used the measured and predicted EPI gradients for trajectory corrections in phantom images on a 7T scanner. Results: The VP gradient measurements are confounded by lingering oscillations of the prephasing gradients, which are compensated in the CVP and FCVP measurements. FCVP is vulnerable to a sign asymmetry in the gradient chain. However, the trajectories determined by all three methods resulted in comparably high EPI image quality. Conclusion: We present a new approach allowing for phantom-based gradient waveform measurements with high precision, which can be useful for trajectory corrections in non-Cartesian or single-shot imaging techniques. In our experimental setup, the proposed "compensated variable-prephasing" method provided the most reliable gradient measurements of the different techniques we compared.

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采用补偿可变相位的基于幻影的梯度波形测量：描述并应用于 7T EPI

目的：介绍 "补偿可变相位"（CVP），这是一种基于幻影的梯度波形测量方法。该技术以 "可变相位"（VP）方法为基础，但考虑了测量中涉及的所有梯度的影响。测量方法我们采用三种方法对梯形测试梯度和EPI 读出梯度序列进行了测量：VP、CVP 和 "完全补偿可变相位"（FCVP）。我们将它们相互比较，并与基于梯度系统传递函数的预测结果进行比较。此外，我们还在 7T 扫描仪上使用测量和预测的 EPI 梯度对假象图像进行轨迹校正。结果：VP 梯度测量受到预相位梯度挥之不去的振荡的干扰，而这在 CVP 和 FCVP 测量中得到了补偿。FCVP 容易受到梯度链符号不对称的影响。不过，这三种方法确定的轨迹都能产生无可比拟的高 EPI 图像质量。结论：我们提出了一种新方法，可基于模型进行高精度梯度波形测量，这对非笛卡尔或单次成像技术中的轨迹校正非常有用。在我们的实验设置中，所提出的 "补偿可变相位 "方法在我们比较的不同技术中提供了最可靠的梯度测量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Medical Physics

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