多GPU系统上运动的高性能MRI模拟。

High performance MRI simulations of motion on multi-GPU systems.

作者信息

Xanthis Christos G, Venetis Ioannis E, Aletras Anthony H

机构信息

Department of Computer Science and Biomedical Informatics, University of Thessaly, Lamia, Greece.

出版信息

J Cardiovasc Magn Reson. 2014 Jul 4;16(1):48. doi: 10.1186/1532-429X-16-48.

DOI:10.1186/1532-429X-16-48

PMID:24996972

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4107941/

Abstract

BACKGROUND

MRI physics simulators have been developed in the past for optimizing imaging protocols and for training purposes. However, these simulators have only addressed motion within a limited scope. The purpose of this study was the incorporation of realistic motion, such as cardiac motion, respiratory motion and flow, within MRI simulations in a high performance multi-GPU environment.

METHODS

Three different motion models were introduced in the Magnetic Resonance Imaging SIMULator (MRISIMUL) of this study: cardiac motion, respiratory motion and flow. Simulation of a simple Gradient Echo pulse sequence and a CINE pulse sequence on the corresponding anatomical model was performed. Myocardial tagging was also investigated. In pulse sequence design, software crushers were introduced to accommodate the long execution times in order to avoid spurious echoes formation. The displacement of the anatomical model isochromats was calculated within the Graphics Processing Unit (GPU) kernel for every timestep of the pulse sequence. Experiments that would allow simulation of custom anatomical and motion models were also performed. Last, simulations of motion with MRISIMUL on single-node and multi-node multi-GPU systems were examined.

RESULTS

Gradient Echo and CINE images of the three motion models were produced and motion-related artifacts were demonstrated. The temporal evolution of the contractility of the heart was presented through the application of myocardial tagging. Better simulation performance and image quality were presented through the introduction of software crushers without the need to further increase the computational load and GPU resources. Last, MRISIMUL demonstrated an almost linear scalable performance with the increasing number of available GPU cards, in both single-node and multi-node multi-GPU computer systems.

CONCLUSIONS

MRISIMUL is the first MR physics simulator to have implemented motion with a 3D large computational load on a single computer multi-GPU configuration. The incorporation of realistic motion models, such as cardiac motion, respiratory motion and flow may benefit the design and optimization of existing or new MR pulse sequences, protocols and algorithms, which examine motion related MR applications.

摘要

背景

过去已开发出MRI物理模拟器，用于优化成像协议和培训目的。然而，这些模拟器仅解决了有限范围内的运动问题。本研究的目的是在高性能多GPU环境下的MRI模拟中纳入逼真的运动，如心脏运动、呼吸运动和血流。

方法

本研究在磁共振成像模拟器（MRISIMUL）中引入了三种不同的运动模型：心脏运动、呼吸运动和血流。在相应的解剖模型上对简单梯度回波脉冲序列和电影脉冲序列进行了模拟。还研究了心肌标记。在脉冲序列设计中，引入了软件去耦器以适应较长的执行时间，从而避免伪回波的形成。在脉冲序列的每个时间步长内，在图形处理单元（GPU）内核中计算解剖模型等色线的位移。还进行了允许模拟自定义解剖和运动模型的实验。最后，研究了在单节点和多节点多GPU系统上使用MRISIMUL进行运动模拟的情况。

结果

生成了三种运动模型的梯度回波和电影图像，并展示了与运动相关的伪影。通过应用心肌标记展示了心脏收缩性的时间演变。通过引入软件去耦器，在无需进一步增加计算负荷和GPU资源的情况下，呈现了更好的模拟性能和图像质量。最后，在单节点和多节点多GPU计算机系统中，随着可用GPU卡数量的增加，MRISIMUL展示了几乎线性的可扩展性能。

结论

MRISIMUL是首个在单计算机多GPU配置上实现具有三维大计算负荷运动的MR物理模拟器。纳入逼真的运动模型，如心脏运动、呼吸运动和血流，可能有利于现有或新的MR脉冲序列、协议和算法的设计和优化，这些序列、协议和算法用于研究与运动相关的MR应用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4b21/4107941/0e46b65dfdd2/1532-429X-16-48-1.jpg

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多GPU系统上运动的高性能MRI模拟。

High performance MRI simulations of motion on multi-GPU systems.

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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