向5d心脏模型迈进

IF 0.8 Q4 ENGINEERING, MECHANICAL

JOURNAL OF FLOW VISUALIZATION AND IMAGE PROCESSING Pub Date : 2019-01-01 DOI:10.1615/JFLOWVISIMAGEPROC.2018027194

Houneida Sakly, R. Mahmoudi, M. Akil, Mourad Said, M. Tagina

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引用次数: 8

摘要

医学诊断过程需要几个步骤来识别心脏病变的类型。分割步骤用于确定MRI获得的4D短轴上心脏异常的测量，但该阶段仍然局限于血流序列。MRI模式允许专家量化主动脉血流狭窄和反流。从血流序列中提取的参数，经过分割后，可以识别出瓣膜病变，但这些参数不足以完成医学预后，而且这些测量缺乏精度。在本文中，我们建议通过配准和重建技术将4D心脏切口与血流研究耦合起来。的血流量作为第五维度的目的是改善心脏参数的准确性和测量数据的提取valvulopathies援助过程中专家的决定一个例子介绍了在这种情况下通过云服务的开发特定的模拟血液流经主动脉瓣以及OsiriX 5 d可视化软件,结合4 d序列和功能流维度。在这个框架中，我们提出了一个通向5D解决方案的处理链。另一个问题是如何选择合适的结构来解决混合并行化处理心脏图像的问题。为了测试5D概念的时间限制，我们需要一个在MRI中获得的GPU图形处理器，以及一个CPU处理器来执行计算的复杂性和应用于图像处理算法的操作。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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MOVING TOWARDS A 5D CARDIAC MODEL

Abstract— The medical diagnosis process requires several steps to identify the types of cardiac pathologies. The segmentation step is used to determine the measurements for cardiac abnormalities on the short axis of the 4D acquired in MRI, but this phase remains limited on the blood flow sequences. The MRI modality allow to the experts to quantify the stenosis and the regurgitation of aortic blood flow. The parameters extracted from the flow sequences, after segmentation, make it possible to identify the valvular pathologies, but they are not sufficient to complete the medical prognosis as well as the lack of precision of these measurements. In this paper, we propose to make a coupling between the 4D cardiac cuts with their study of blood flow through the technique of registration and reconstruction. The interest of the purpose of the blood flow as fifth dimension is to improve the accuracy of the cardiac parameters and the extracting of measurements for valvulopathies in the process of assistance to the decision for the experts An example was introduced in this context through the development of cloud services for patient-specific simulations of blood flows through aortic valves as well as an OsiriX software for 5D visualization that combines a 4D sequence and the functional flow dimension. In this framework, we proposed a processing chain to lead towards a 5D solution. Another problem is raised is the choice of the appropriate architecture to solve the problem of hybrid parallelization for the processing of these cardiac images. To test the constraints of time of the concept of 5D, we need a GPU graphics processor acquired in MRI, as well as a CPU processor to perform the complexity of calculation and the operations applied to the algorithms of image processing.

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来源期刊

JOURNAL OF FLOW VISUALIZATION AND IMAGE PROCESSING Multiple-

CiteScore

1.30

自引率

16.70%

发文量

期刊介绍： The Journal of Flow Visualization and Image Processing is a quarterly refereed research journal that publishes original papers to disseminate and exchange knowledge and information on the principles and applications of flow visualization techniques and related image processing algorithms. Flow visualization and quantification have emerged as powerful tools in velocity, pressure, temperature and species concentration measurements, combustion diagnostics, and process monitoring related to physical, biomedical, and engineering sciences. Measurements were initially based on lasers but have expanded to include a wider electromagnetic spectrum. Numerical simulation is a second source of data amenable to image analysis. Direct visualization in the form of high speed, high resolution imaging supplements optical measurements. A combination of flow visualization and image processing holds promise to breach the holy grail of extracting instantaneous three dimensional data in transport phenomena. Optical methods can be enlarged to cover a wide range of measurements, first by factoring in the applicable physical laws and next, by including the principle of image formation itself. These steps help in utilizing incomplete data and imperfect visualization for reconstructing a complete scenario of the transport process.[...] The journal will promote academic and industrial advancement and improvement of flow imaging techniques internationally. It seeks to convey practical information in this field covering all areas in science, technology, and medicine for engineers, scientists, and researchers in industry, academia, and government.