Estimating Aggregate Cardiomyocyte Strain Using In Vivo Diffusion and Displacement Encoded MRI.

IF 8.9 1区 医学 Q1 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
IEEE Transactions on Medical Imaging Pub Date : 2020-03-01 Epub Date: 2019-08-08 DOI:10.1109/TMI.2019.2933813
Ilya A Verzhbinsky, Luigi E Perotti, Kevin Moulin, Tyler E Cork, Michael Loecher, Daniel B Ennis
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引用次数: 0

Abstract

Changes in left ventricular (LV) aggregate cardiomyocyte orientation and deformation underlie cardiac function and dysfunction. As such, in vivo aggregate cardiomyocyte "myofiber" strain ( [Formula: see text]) has mechanistic significance, but currently there exists no established technique to measure in vivo [Formula: see text]. The objective of this work is to describe and validate a pipeline to compute in vivo [Formula: see text] from magnetic resonance imaging (MRI) data. Our pipeline integrates LV motion from multi-slice Displacement ENcoding with Stimulated Echoes (DENSE) MRI with in vivo LV microstructure from cardiac Diffusion Tensor Imaging (cDTI) data. The proposed pipeline is validated using an analytical deforming heart-like phantom. The phantom is used to evaluate 3D cardiac strains computed from a widely available, open-source DENSE Image Analysis Tool. Phantom evaluation showed that a DENSE MRI signal-to-noise ratio (SNR) ≥20 is required to compute [Formula: see text] with near-zero median strain bias and within a strain tolerance of 0.06. Circumferential and longitudinal strains are also accurately measured under the same SNR requirements, however, radial strain exhibits a median epicardial bias of -0.10 even in noise-free DENSE data. The validated framework is applied to experimental DENSE MRI and cDTI data acquired in eight ( N=8 ) healthy swine. The experimental study demonstrated that [Formula: see text] has decreased transmural variability compared to radial and circumferential strains. The spatial uniformity and mechanistic significance of in vivo [Formula: see text] make it a compelling candidate for characterization and early detection of cardiac dysfunction.

用$In~Vivo$扩散和位移编码MRI估计聚集性心肌细胞应变
左心室(LV)聚集心肌细胞定向和变形的变化是心脏功能和功能障碍的基础。因此,体内聚集心肌细胞“肌纤维”菌株(${E}_{\text{ff}}$)具有机制意义,但目前还没有建立的体内测量技术${E}_{\text{ff}}$。这项工作的目的是描述和验证体内计算的管道${E}_{\text{ff}}$来自磁共振成像(MRI)数据。我们的管道将多层置换ENcoding的左心室运动与刺激回波(DENSE)MRI以及心脏扩散张量成像(cDTI)数据的体内左心室微观结构相结合。使用分析变形的类心体模对所提出的管道进行了验证。该体模用于评估通过广泛可用的开源DENSE图像分析工具计算的3D心脏应变。体模评估显示,需要DENSE MRI信噪比(SNR)≥20才能计算${E}_{\text{ff}}$,具有接近零的中值应变偏差和0.06的应变容限。在相同的SNR要求下,也可以准确测量周向和纵向应变,然而,即使在无噪声的DENSE数据中,径向应变也表现出-0.10的心外膜中值偏差。验证的框架应用于在八只(${N}={8}$)健康猪中获得的实验性DENSE MRI和cDTI数据。实验研究表明${E}_{\text{ff}}$与径向应变和周向应变相比,透壁变异性降低。体内的空间均匀性及其机制意义${E}_{\text{ff}}$使其成为表征和早期检测心脏功能障碍的有力候选者。
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来源期刊
IEEE Transactions on Medical Imaging
IEEE Transactions on Medical Imaging 医学-成像科学与照相技术
CiteScore
21.80
自引率
5.70%
发文量
637
审稿时长
5.6 months
期刊介绍: The IEEE Transactions on Medical Imaging (T-MI) is a journal that welcomes the submission of manuscripts focusing on various aspects of medical imaging. The journal encourages the exploration of body structure, morphology, and function through different imaging techniques, including ultrasound, X-rays, magnetic resonance, radionuclides, microwaves, and optical methods. It also promotes contributions related to cell and molecular imaging, as well as all forms of microscopy. T-MI publishes original research papers that cover a wide range of topics, including but not limited to novel acquisition techniques, medical image processing and analysis, visualization and performance, pattern recognition, machine learning, and other related methods. The journal particularly encourages highly technical studies that offer new perspectives. By emphasizing the unification of medicine, biology, and imaging, T-MI seeks to bridge the gap between instrumentation, hardware, software, mathematics, physics, biology, and medicine by introducing new analysis methods. While the journal welcomes strong application papers that describe novel methods, it directs papers that focus solely on important applications using medically adopted or well-established methods without significant innovation in methodology to other journals. T-MI is indexed in Pubmed® and Medline®, which are products of the United States National Library of Medicine.
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