Recent Developments in Diffusion Tensor Imaging of Brain.

Radiology - open journal Pub Date : 2015-01-01 Epub Date: 2015-12-11 DOI:10.17140/roj-1-101

Mansi Bharat Parekh, Abhijit Achyut Gurjarpadhye, Martin A C Manoukian, Arita Dubnika, Jayakumar Rajadas, Mohammed Inayathullah

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引用次数: 8

Abstract

Magnetic resonance imaging (MRI) has come to be known as a unique radiological imaging modality because of its ability to perform tomographic imaging of body without the use of any harmful ionizing radiation. The radiologists use MRI to gain insight into the anatomy of organs, including the brain, while biomedical researchers explore the modality to gain better understanding of the brain structure and function. However, due to limited resolution and contrast, the conventional MRI fails to show the brain microstructure. Diffusion tensor imaging (DTI) harnesses the power of conventional MRI to deduce the diffusion dynamics of water molecules within the tissue and indirectly create a three-dimensional sketch of the brain anatomy. DTI enables visualization of brain tissue microstructure, which is extremely helpful in understanding various neuropathologies and neurodegenerative disorders. In this review, we briefly discuss the background and operating principles of DTI, followed by current trends in DTI applications for biomedical and clinical investigation of various brain diseases and disorders.

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脑弥散张量成像的最新进展。

磁共振成像(MRI)已经被称为一种独特的放射成像方式，因为它能够在不使用任何有害的电离辐射的情况下对人体进行断层成像。放射科医生使用核磁共振成像来深入了解器官的解剖结构，包括大脑，而生物医学研究人员则探索这种方式，以更好地了解大脑的结构和功能。然而，由于分辨率和对比度的限制，传统的MRI无法显示大脑的微观结构。扩散张量成像(DTI)利用传统MRI的力量来推断组织内水分子的扩散动力学，并间接创建大脑解剖结构的三维草图。DTI能够实现脑组织微观结构的可视化，这对理解各种神经病理和神经退行性疾病非常有帮助。在本文中，我们简要讨论了DTI的背景和工作原理，然后介绍了DTI在各种脑疾病和障碍的生物医学和临床研究中的应用趋势。

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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Radiology - open journal

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