Diffusion-weighted MR imaging of anisotropic water diffusion in cat central nervous system.

Moseley, Michael E.; Cohen, Yoram; Kucharczyk, John; Mintorovitch, Jan; Asgari, H S; Wendland, Michael F.; Tsuruda, Jay S.; Norman, David

doi:10.1148/radiology.176.2.2367658

Cited by 1,020 publications

(592 citation statements)

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“…1(A)] and that the orientation of the largest principal axis aligns to the predominant axonal orientation. 3,[44][45][46][47] However, when studying axonal architecture using DTI, it is very important to understand the limitations arising from the inhomogeneity of the water environment. First, the conventional DTI data acquisition and processing methods may not be able to properly handle a voxel containing more than one population of axonal tracts with different orientations.…”

Section: Cellular Architecture Superimposes Orientation On the Randommentioning

confidence: 99%

“…3 In the last decade, the quantitative description of this anisotropy with diffusion tensor imaging (DTI) has become well established in the research environment and its first applications in the clinic are now being reported. These applications employ both the directional anisotropy that can be measured by DTI 4,5 as well as removal of this anisotropy through the use of the tensor trace.…”

Section: Introductionmentioning

confidence: 99%

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Fiber tracking: principles and strategies – a technical review

2002

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The state of the art of reconstruction of the axonal tracts in the central nervous system (CNS) using diffusion tensor imaging (DTI) is reviewed. This relatively new technique has generated much enthusiasm and high expectations because it presently is the only approach available to non-invasively study the three-dimensional architecture of white matter tracts. While there is no doubt that DTI fiber tracking is providing exciting new opportunities to study CNS anatomy, it is very important to understand its limitations. In this review we therefore assess the basic principles and the assumptions that need to be made for each step of the study, including both data acquisition and the elaborate fiber reconstruction algorithms. Special attention is paid to situations where complications may arise, and possible solutions are reviewed. Validation issues and potential future directions and improvements are also discussed.

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Section: Cellular Architecture Superimposes Orientation On the Randommentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Fiber tracking: principles and strategies – a technical review

2002

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“…isotropic), it is usually sufficient to characterize the diffusion characteristics with a single (scalar) apparent diffusion coefficient (ADC). However, in anisotropic media, such as skeletal and cardiac muscle [6][7][8] and in white matter, [9][10][11] where the measured diffusivity is known to depend upon the orientation of the tissue, no single ADC can characterize the orientation-dependent water mobility in these tissues. The next most complex model of diffusion that can describe anisotropic diffusion is to replace the scalar diffusion coefficient with a symmetric effective or apparent diffusion tensor of water, D. 12 which could lead to additional attenuation of the NMR signal.…”

Section: Characterizing Diffusion In Biological Systemsmentioning

confidence: 99%

Diffusion‐tensor MRI: theory, experimental design and data analysis – a technical review

2002

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This article treats the theoretical underpinnings of diffusion-tensor magnetic resonance imaging (DT-MRI), as well as experimental design and data analysis issues. We review the mathematical model underlying DT-MRI, discuss the quantitative parameters that are derived from the measured effective diffusion tensor, and describe artifacts thet arise in typical DT-MRI acquisitions. We also discuss difficulties in identifying appropriate models to describe water diffusion in heterogeneous tissues, as well as in interpreting experimental data obtained in such issues. Finally, we describe new statistical methods that have been developed to analyse DT-MRI data, and their potential uses in clinical and multi-site studies.

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“…[48][49][50][51] In isolated nerves it has been shown that the magnetization decay curve, measured by the pulsed gradient spin echo (PGSE) sequence, is resolved into two or more exponentials, 51,52 each representing a different water population. The 2 H DQF technique is unique and enables measurement of the diffusion of water in each nerve compartment independently.…”

Section: Na In Biological Tissuesmentioning

confidence: 99%

Multiquantum filters and order in tissues

et al. 2001

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In ordered systems, where the molecular motion is anisotropic, quadrupolar and dipolar interactions are not averaged to zero. In such cases, double quantum (DQ) coherences can be formed. This review deals mainly with the effect of anisotropic motion of water molecules and sodium ions in intact biological tissues on 2 H, 1 H and 23 Na NMR spectroscopy and its application to NMR imaging (MRI).Double quantum filtered (DQF) spectra of water molecules and sodium ions were detected in a variety of ordered biological tissues. In collagen-containing tissues such as ligaments, tendons, cartilage, skin, blood vessels and nerves, the DQ coherences are formed as a result of the interaction with the collagen fibers. In red blood cells and presumably also in nerve axons it stems from the interaction with the cytoskeleton.For 23 Na, an I = 3/2 nucleus, the DQ coherences can also be formed in isotropic media. By a judicial choice of the pulse angle in the DQ pulse sequence only the DQ coherences arising from anisotropic motion are detected. For I = 1 nuclei such as 2 H, DQF spectra can be observed only in ordered structures. Thus, the observation of 2 H DQF spectra is an indication of order. The same is true for pairs of equivalent 1 H nuclei.The dependence of the DQF signal on the creation time of the double quantum coherences is characteristic to each tissue and allows signals to be resolved from different tissues by performing the measurements at different creation times. In this way, the 2 H DQF signals of the different compartments of sciatic nerve were resolved and water diffusion in each compartment was studied independently. In the axon, the diffusion was heavily restricted perpendicular to the axon's long axis, a result from which the axon diameter could be deduced. In blood vessel walls, this characteristic enabled the different layers of the vessel to be viewed and studied under strain.For 2 H, a DQF spectroscopic imaging sequence was used to study the orientation of the collagen fibers in the different zones of articular cartilage and bone plug. The effect of pressure on the fibers and their return to equilibrium was studied as well. In blood vessels, a DQF image was obtained and strain maps of the different layers were calculated.The efficiency of the 1 H DQF imaging technique was demonstrated on a phantom of rat tail where only the four tendons were detected at short creation times. 1 H DQF imaging and spectroscopy followed the healing of a rabbit's ruptured Achilles tendon and the results were far more sensitive to the process than conventional imaging. Finally, the method was implemented on a commercial whole body MRI spectrometer. Images of human wrist and ankle showed a positive contrast for the tendons and ligaments, indicating the potential of the method for clinical imaging.

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Diffusion-weighted MR imaging of anisotropic water diffusion in cat central nervous system.

Cited by 1,020 publications

References 0 publications

Fiber tracking: principles and strategies – a technical review

Fiber tracking: principles and strategies – a technical review

Diffusion‐tensor MRI: theory, experimental design and data analysis – a technical review

Multiquantum filters and order in tissues

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