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MRXCAT2.0:通过结合左心室形状学习、生物物理模拟和组织纹理生成来合成逼真的数值体模。

MRXCAT2.0: Synthesis of realistic numerical phantoms by combining left-ventricular shape learning, biophysical simulations and tissue texture generation.

机构信息

Institute for Biomedical Engineering, ETH Zurich and University Zurich, Zurich, Switzerland.

出版信息

J Cardiovasc Magn Reson. 2023 Apr 20;25(1):25. doi: 10.1186/s12968-023-00934-z.

DOI:10.1186/s12968-023-00934-z
PMID:37076840
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10116689/
Abstract

BACKGROUND

Standardised performance assessment of image acquisition, reconstruction and processing methods is limited by the absence of images paired with ground truth reference values. To this end, we propose MRXCAT2.0 to generate synthetic data, covering healthy and pathological function, using a biophysical model. We exemplify the approach by generating cardiovascular magnetic resonance (CMR) images of healthy, infarcted, dilated and hypertrophic left-ventricular (LV) function.

METHOD

In MRXCAT2.0, the XCAT torso phantom is coupled with a statistical shape model, describing population (patho)physiological variability, and a biophysical model, providing known and detailed functional ground truth of LV morphology and function. CMR balanced steady-state free precession images are generated using MRXCAT2.0 while realistic image appearance is ensured by assigning texturized tissue properties to the phantom labels.

FINDING

Paired CMR image and ground truth data of LV function were generated with a range of LV masses (85-140 g), ejection fractions (34-51%) and peak radial and circumferential strains (0.45 to 0.95 and - 0.18 to - 0.13, respectively). These ranges cover healthy and pathological cases, including infarction, dilated and hypertrophic cardiomyopathy. The generation of the anatomy takes a few seconds and it improves on current state-of-the-art models where the pathological representation is not explicitly addressed. For the full simulation framework, the biophysical models require approximately two hours, while image generation requires a few minutes per slice.

CONCLUSION

MRXCAT2.0 offers synthesis of realistic images embedding population-based anatomical and functional variability and associated ground truth parameters to facilitate a standardized assessment of CMR acquisition, reconstruction and processing methods.

摘要

背景

由于缺乏与真实参考值配对的图像,因此对图像采集、重建和处理方法的标准化性能评估受到限制。为此,我们提出了 MRXCAT2.0,该方法使用生物物理模型生成涵盖健康和病理功能的合成数据。我们通过生成健康、梗死、扩张和肥厚性左心室(LV)功能的心血管磁共振(CMR)图像来举例说明该方法。

方法

在 MRXCAT2.0 中,XCAT 体模与描述人群(病理)生理变异性的统计形状模型以及提供 LV 形态和功能已知详细功能真实值的生物物理模型相结合。使用 MRXCAT2.0 生成 CMR 平衡稳态自由进动图像,同时通过向体模标签分配纹理组织属性来确保逼真的图像外观。

发现

生成了一系列 LV 质量(85-140g)、射血分数(34-51%)和峰值径向和周向应变(分别为 0.45 至 0.95 和-0.18 至-0.13)的 LV 功能的配对 CMR 图像和真实值数据。这些范围涵盖了健康和病理情况,包括梗死、扩张性和肥厚性心肌病。解剖结构的生成只需几秒钟,并且改进了当前的最先进模型,其中病理表示未明确解决。对于完整的仿真框架,生物物理模型大约需要两个小时,而每张切片的图像生成则需要几分钟。

结论

MRXCAT2.0 提供了嵌入基于人群的解剖和功能变异性以及相关真实值参数的逼真图像的合成,以促进 CMR 采集、重建和处理方法的标准化评估。

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