利用超高场磁共振成像对急性和慢性猪心肌梗塞的心脏功能和疤痕大小进行精确成像。

IF 5.4 Q1 MEDICINE, RESEARCH & EXPERIMENTAL
David Lohr, Alena Kollmann, Maya Bille, Maxim Terekhov, Ibrahim Elabyad, Michael Hock, Steffen Baltes, Theresa Reiter, Florian Schnitter, Wolfgang Rudolf Bauer, Ulrich Hofmann, Laura Maria Schreiber
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引用次数: 0

摘要

背景:7 T 心脏磁共振成像(MRI)研究可提高心功能、心室质量等临床指标的精确度。更高的精确度可在临床实践和临床前研究中早期发现功能障碍并早期评估治疗反应:方法:在心肌梗塞发生前和发生后的三个时间点(3-4 天、7-10 天和约 60 天),使用内部开发和制造的全身 7 T 系统和三个射频线圈对七只雌性德国兰德猪进行扫描,以伴随动物的生长:专用射频硬件和 7 T MRI 的结合实现了猪急性和慢性心肌梗塞模型的纵向研究,在测量心脏功能时提供了一致的血液组织对比度和高信噪比 (SNR),以及射血分数(CoVintra-observer:2%,CoVinter-observer:3.8%)和梗塞大小(CoVintra-observer:8.4%,CoVinter-observer:3.8%)的低变异系数 (CoV),尽管动物急剧长大:结论:手动分割可获得最佳效果。我们为 7 T 下的大型动物研究定义了最先进的程序。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Precision imaging of cardiac function and scar size in acute and chronic porcine myocardial infarction using ultrahigh-field MRI

Precision imaging of cardiac function and scar size in acute and chronic porcine myocardial infarction using ultrahigh-field MRI
7 T cardiac magnetic resonance imaging (MRI) studies may enable higher precision in clinical metrics like cardiac function, ventricular mass, and more. Higher precision may allow early detection of functional impairment and early evaluation of treatment responses in clinical practice and pre-clinical studies. Methods: Seven female German Landrace pigs were scanned prior to and at three time points (3–4 days, 7–10 days, and ~60 days) post myocardial infarction using a whole body 7 T system and three radiofrequency (RF) coils developed and built in-house to accompany animal growth. Results: The combination of dedicated RF hardware and 7 T MRI enables a longitudinal study in a pig model of acute and chronic infarction, providing consistent blood tissue contrast and high signal-to-noise ratio (SNR) in measurements of cardiac function, as well as low coefficients of variation (CoV) for ejection fraction (CoVintra-observer: 2%, CoVinter-observer: 3.8%) and infarct size (CoVintra-observer: 8.4%, CoVinter-observer: 3.8%), despite drastic animal growth. Conclusions: Best results are achieved via manual segmentation. We define state-of-the-art procedures for large animal studies at 7 T. In magnetic resonance imaging (MRI), scanners use magnets to generate detailed images of structures in the body, such as the heart. Stronger magnets can produce stronger magnetic fields, which can be leveraged for better image quality and developing new methods for disease diagnosis. In clinical practice, such systems using strong magnets are not yet used for imaging of the heart and some safety aspects remain challenging. We apply such an imaging approach in pigs, in which heart structure and function are similar to humans. We focus on the most important clinical imaging aspects following a heart attack, namely heart function and scar detection. We demonstrate that the high magnetic strength system enabled consistent image quality and accuracy. These findings may help to guide future developments in MRI of the heart, for example in patients who have had a heart attack. Lohr et al. demonstrate that 7 T cardiac MRI in conjunction with dedicated radiofrequency hardware enables high precision imaging of cardiac function and scar size in a large animal model of acute and chronic myocardial infarction. High precision is achieved based on consistent blood tissue contrast and SNR in measurements of cardiac function.
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