Application of a novel T1 retrospective quantification using internal references (T1-REQUIRE) algorithm to derive quantitative T1 relaxation maps of the brain

IF 3 4区计算机科学 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

International Journal of Imaging Systems and Technology Pub Date : 2022-06-13 DOI:10.1002/ima.22768

Adam Hasse, Julian Bertini, Sean Foxley, Yong Jeong, Adil Javed, Timothy J. Carroll

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引用次数: 0

Abstract

Most MRI sequences used clinically are qualitative or weighted. While such images provide useful information for clinicians to diagnose and monitor disease progression, they lack the ability to quantify tissue damage for more objective assessment. In this study, an algorithm referred to as the T1-REQUIRE is presented as a proof-of-concept which uses nonlinear transformations to retrospectively estimate T1 relaxation times in the brain using T1-weighted MRIs, the appropriate signal equation, and internal, healthy tissues as references. T1-REQUIRE was applied to two T1-weighted MR sequences, a spin-echo and a MPRAGE, and validated with a reference standard T1 mapping algorithm in vivo. In addition, a multiscanner study was run using MPRAGE images to determine the effectiveness of T1-REQUIRE in conforming the data from different scanners into a more uniform way of analyzing T1-relaxation maps. The T1-REQUIRE algorithm shows good agreement with the reference standard (Lin's concordance correlation coefficients of 0.884 for the spin-echo and 0.838 for the MPRAGE) and with each other (Lin's concordance correlation coefficient of 0.887). The interscanner studies showed improved alignment of cumulative distribution functions after T1-REQUIRE was performed. T1-REQUIRE was validated with a reference standard and shown to be an effective estimate of T1 over a clinically relevant range of T1 values. In addition, T1-REQUIRE showed excellent data conformity across different scanners, providing evidence that T1-REQUIRE could be a useful addition to big data pipelines.

Abstract Image

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应用一种新颖的T1回顾性量化使用内部参考(T1- require)算法来获得定量的大脑T1松弛图

临床上使用的大多数MRI序列是定性的或加权的。虽然这些图像为临床医生诊断和监测疾病进展提供了有用的信息，但它们缺乏量化组织损伤以进行更客观评估的能力。在这项研究中，一种被称为T1- require的算法被提出作为概念验证，该算法使用非线性变换来回顾性地估计大脑中的T1松弛时间，使用T1加权mri，适当的信号方程和内部健康组织作为参考。T1- require应用于两个T1加权MR序列，一个自旋回波和一个MPRAGE，并使用参考标准T1定位算法在体内进行验证。此外，使用MPRAGE图像进行了一项多扫描仪研究，以确定T1-REQUIRE在将来自不同扫描仪的数据整合到更统一的t1松弛图分析方法中的有效性。T1-REQUIRE算法与参考标准(自旋回波的Lin’s一致性相关系数为0.884,MPRAGE的Lin’s一致性相关系数为0.838)和与参考标准(Lin’s一致性相关系数为0.887)具有较好的一致性。扫描间研究表明，T1-REQUIRE后，累积分布函数的对齐得到了改善。用参考标准对T1- require进行了验证，并证明在临床相关的T1值范围内对T1进行了有效的估计。此外，T1-REQUIRE在不同的扫描仪上显示了出色的数据一致性，这证明了T1-REQUIRE可以成为大数据管道的有用补充。

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来源期刊

International Journal of Imaging Systems and Technology 工程技术-成像科学与照相技术

CiteScore

6.90

自引率

6.10%

发文量

138

审稿时长

3 months

期刊介绍： The International Journal of Imaging Systems and Technology (IMA) is a forum for the exchange of ideas and results relevant to imaging systems, including imaging physics and informatics. The journal covers all imaging modalities in humans and animals. IMA accepts technically sound and scientifically rigorous research in the interdisciplinary field of imaging, including relevant algorithmic research and hardware and software development, and their applications relevant to medical research. The journal provides a platform to publish original research in structural and functional imaging. The journal is also open to imaging studies of the human body and on animals that describe novel diagnostic imaging and analyses methods. Technical, theoretical, and clinical research in both normal and clinical populations is encouraged. Submissions describing methods, software, databases, replication studies as well as negative results are also considered. The scope of the journal includes, but is not limited to, the following in the context of biomedical research: Imaging and neuro-imaging modalities: structural MRI, functional MRI, PET, SPECT, CT, ultrasound, EEG, MEG, NIRS etc.; Neuromodulation and brain stimulation techniques such as TMS and tDCS; Software and hardware for imaging, especially related to human and animal health; Image segmentation in normal and clinical populations; Pattern analysis and classification using machine learning techniques; Computational modeling and analysis; Brain connectivity and connectomics; Systems-level characterization of brain function; Neural networks and neurorobotics; Computer vision, based on human/animal physiology; Brain-computer interface (BCI) technology; Big data, databasing and data mining.