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用于改进超短回波时间成像的斜坡式混合编码

Ramped hybrid encoding for improved ultrashort echo time imaging.

作者信息

Jang Hyungseok, Wiens Curtis N, McMillan Alan B

机构信息

Department of Radiology, Wisconsin Institute for Medical Research, University of Wisconsin, Madison, Wisconsin, USA.

Department of Electrical and Computer Engineering, University of Wisconsin, Madison, Wisconsin, USA.

出版信息

Magn Reson Med. 2016 Sep;76(3):814-25. doi: 10.1002/mrm.25977. Epub 2015 Sep 18.

DOI:10.1002/mrm.25977
PMID:26381890
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4798926/
Abstract

PURPOSE

We propose a new acquisition to minimize the per-excitation encoding duration and improve the imaging capability for short T2 * species.

METHODS

In the proposed ramped hybrid encoding (RHE) technique, gradients are applied before the radiofrequency (RF) pulse as in pointwise encoding time reduction with radial acquisition (PETRA) and zero echo time (ZTE) imaging. However, in RHE, gradients are rapidly ramped after RF excitation to the maximum amplitude to minimize encoding duration. To acquire central k-space data not measured during RF deadtime, RHE uses a hybrid encoding scheme similar to PETRA. A new gradient calibration method based on single-point imaging was developed to estimate the k-space trajectory and enable robust and high quality reconstruction.

RESULTS

RHE enables a shorter per-excitation encoding time and provides the highest spatial resolution among ultrashort T2 * imaging methods. In phantom and in vivo experiments, RHE exhibited robust imaging with negligible chemical shift or blurriness caused by T2 * decay and unwanted slice selection.

CONCLUSION

RHE allows the shortest per-excitation encoding time for ultrashort T2 * imaging, which alleviates the impact of fast T2 * decay occurring during encoding, and enables improved spatial resolution. Magn Reson Med 76:814-825, 2016. © 2015 Wiley Periodicals, Inc.

摘要

目的

我们提出一种新的采集方法,以最小化每次激发的编码持续时间,并提高对短T2*物质的成像能力。

方法

在所提出的斜坡混合编码(RHE)技术中,梯度在射频(RF)脉冲之前施加,如同在逐点编码时间减少的径向采集(PETRA)和零回波时间(ZTE)成像中那样。然而,在RHE中,梯度在RF激发后迅速上升到最大幅度,以最小化编码持续时间。为了采集在RF死时间期间未测量的中心k空间数据,RHE使用类似于PETRA的混合编码方案。开发了一种基于单点成像的新梯度校准方法,以估计k空间轨迹并实现稳健且高质量的重建。

结果

RHE实现了更短的每次激发编码时间,并在超短T2成像方法中提供了最高的空间分辨率。在体模和体内实验中,RHE表现出稳健的成像,由T2衰减和不需要的层面选择引起的化学位移或模糊可忽略不计。

结论

RHE允许超短T2成像的每次激发编码时间最短,这减轻了编码期间快速T2衰减的影响,并提高了空间分辨率。《磁共振医学》76:814 - 825,2016年。© 2015威利期刊公司。

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