Diffusionsgewichtete bildgebung beim akuten hirnschlag

P. M. Jakob; K. O. Lövblad; J. Weber; H. J. Laubach; L. Remonda; F. Gönner; O. Heid; H. P. Mattle; G. Schroth; R. R. Edelman; S. Warach

doi:10.1007/s001150050329

Diffusionsgewichtete bildgebung beim akuten hirnschlag

Translated title of the contribution: Diffusion-weighted MR-tomography in acute stroke

P. M. Jakob, K. O. Lövblad, J. Weber, H. J. Laubach, L. Remonda, F. Gönner, O. Heid, H. P. Mattle, G. Schroth, R. R. Edelman, S. Warach

Neurology & Neurotherapeutics

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Magnetic resonance imaging represents today the most important tool in neuroradiology for both clinical practice and research. MRI allows imaging of the human body in 2 or 3 dimensions with variable tissue contrast. The natural diffusion of tissue protons can now be used as a supplementary contrast mechanism. Different MRI techniques can be used to obtain clinically useful diffusion-on-weighted images. These techniques all require the use of strong gradient pulses in order to obtain the diffusion contrast. In the current article, the most important physical principles of diffusion measurement are presented. After a short introduction into the basic physical principles, we will present the prerequisites and limitations of clinically relevant applications today. Finally a few select examples of clinical use of these techniques in the acute diagnosis of stroke will be presented.

Translated title of the contribution	Diffusion-weighted MR-tomography in acute stroke
Original language	German
Pages (from-to)	683-693
Number of pages	11
Journal	Nervenarzt
Volume	69
Issue number	8
DOIs	https://doi.org/10.1007/s001150050329
State	Published - Aug 1998

Keywords

Cerebral ischemia
Diffusion
Echo-planar
MRI

ASJC Scopus subject areas

Neurology
Clinical Neurology
Psychiatry and Mental health

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10.1007/s001150050329

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title = "Diffusionsgewichtete bildgebung beim akuten hirnschlag",

abstract = "Magnetic resonance imaging represents today the most important tool in neuroradiology for both clinical practice and research. MRI allows imaging of the human body in 2 or 3 dimensions with variable tissue contrast. The natural diffusion of tissue protons can now be used as a supplementary contrast mechanism. Different MRI techniques can be used to obtain clinically useful diffusion-on-weighted images. These techniques all require the use of strong gradient pulses in order to obtain the diffusion contrast. In the current article, the most important physical principles of diffusion measurement are presented. After a short introduction into the basic physical principles, we will present the prerequisites and limitations of clinically relevant applications today. Finally a few select examples of clinical use of these techniques in the acute diagnosis of stroke will be presented.",

keywords = "Cerebral ischemia, Diffusion, Echo-planar, MRI",

author = "Jakob, {P. M.} and L{\"o}vblad, {K. O.} and J. Weber and Laubach, {H. J.} and L. Remonda and F. G{\"o}nner and O. Heid and Mattle, {H. P.} and G. Schroth and Edelman, {R. R.} and S. Warach",

year = "1998",

month = aug,

doi = "10.1007/s001150050329",

language = "German",

volume = "69",

pages = "683--693",

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AU - Jakob, P. M.

AU - Lövblad, K. O.

AU - Weber, J.

AU - Laubach, H. J.

AU - Remonda, L.

AU - Gönner, F.

AU - Heid, O.

AU - Mattle, H. P.

AU - Schroth, G.

AU - Edelman, R. R.

AU - Warach, S.

PY - 1998/8

Y1 - 1998/8

N2 - Magnetic resonance imaging represents today the most important tool in neuroradiology for both clinical practice and research. MRI allows imaging of the human body in 2 or 3 dimensions with variable tissue contrast. The natural diffusion of tissue protons can now be used as a supplementary contrast mechanism. Different MRI techniques can be used to obtain clinically useful diffusion-on-weighted images. These techniques all require the use of strong gradient pulses in order to obtain the diffusion contrast. In the current article, the most important physical principles of diffusion measurement are presented. After a short introduction into the basic physical principles, we will present the prerequisites and limitations of clinically relevant applications today. Finally a few select examples of clinical use of these techniques in the acute diagnosis of stroke will be presented.

AB - Magnetic resonance imaging represents today the most important tool in neuroradiology for both clinical practice and research. MRI allows imaging of the human body in 2 or 3 dimensions with variable tissue contrast. The natural diffusion of tissue protons can now be used as a supplementary contrast mechanism. Different MRI techniques can be used to obtain clinically useful diffusion-on-weighted images. These techniques all require the use of strong gradient pulses in order to obtain the diffusion contrast. In the current article, the most important physical principles of diffusion measurement are presented. After a short introduction into the basic physical principles, we will present the prerequisites and limitations of clinically relevant applications today. Finally a few select examples of clinical use of these techniques in the acute diagnosis of stroke will be presented.

KW - Cerebral ischemia

KW - Diffusion

KW - Echo-planar

KW - MRI

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Diffusionsgewichtete bildgebung beim akuten hirnschlag

Abstract

Keywords

ASJC Scopus subject areas

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