Literature DB >> 16705630

Parallel RF transmission in MRI.

Ulrich Katscher1, Peter Börnert.   

Abstract

Following the development of parallel imaging, parallel transmission describes the use of multiple RF transmit coils. Parallel transmission can be applied to improve RF excitation, in particular, multidimensional, spatially selective RF excitation. For instance, parallel transmission is able to shorten spatially selective RF pulses in two or three dimensions, or to minimize the occurring SAR. One potential major application might be the compensation of patient-induced B(1) inhomogeneities, particularly at high main fields. This paper provides an overview of selected aspects of this new transmission approach. The basic principles of parallel transmission are discussed, initial experimental proofs are described, and the impact of error propagation on coil design for parallel transmission is outlined. Copyright (c) 2006 John Wiley & Sons, Ltd.

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Year:  2006        PMID: 16705630     DOI: 10.1002/nbm.1049

Source DB:  PubMed          Journal:  NMR Biomed        ISSN: 0952-3480            Impact factor:   4.044


  50 in total

1.  Improved B1 homogeneity of 3 Tesla breast MRI using dual-source parallel radiofrequency excitation.

Authors:  Habib Rahbar; Savannah C Partridge; Wendy B Demartini; Robert L Gutierrez; Sana Parsian; Constance D Lehman
Journal:  J Magn Reson Imaging       Date:  2012-01-26       Impact factor: 4.813

2.  Designing multichannel, multidimensional, arbitrary flip angle RF pulses using an optimal control approach.

Authors:  Dan Xu; Kevin F King; Yudong Zhu; Graeme C McKinnon; Zhi-Pei Liang
Journal:  Magn Reson Med       Date:  2008-03       Impact factor: 4.668

3.  Reducing metallic artefacts in post-operative spinal imaging: slice encoding for metal artefact correction with dual-source parallel radiofrequency excitation MRI at 3.0 T.

Authors:  K D Song; Y C Yoon; J Park
Journal:  Br J Radiol       Date:  2013-07       Impact factor: 3.039

4.  Combining RF encoding with parallel imaging: a simulation study.

Authors:  Rita G Nunes; Joseph V Hajnal; David J Larkman
Journal:  MAGMA       Date:  2009-12-19       Impact factor: 2.310

Review 5.  State-of-the-art MRI techniques in neuroradiology: principles, pitfalls, and clinical applications.

Authors:  Magalie Viallon; Victor Cuvinciuc; Benedicte Delattre; Laura Merlini; Isabelle Barnaure-Nachbar; Seema Toso-Patel; Minerva Becker; Karl-Olof Lovblad; Sven Haller
Journal:  Neuroradiology       Date:  2015-04-10       Impact factor: 2.804

6.  T1 mapping using saturation recovery single-shot acquisition at 3-tesla magnetic resonance imaging in hypertrophic cardiomyopathy: comparison to late gadolinium enhancement.

Authors:  Ryo Ogawa; Tomoyuki Kido; Masashi Nakamura; Teruhito Kido; Akira Kurata; Teruyoshi Uetani; Akiyoshi Ogimoto; Masao Miyagawa; Teruhito Mochizuki
Journal:  Jpn J Radiol       Date:  2017-01-19       Impact factor: 2.374

Review 7.  Toward cardiovascular MRI at 7 T: clinical needs, technical solutions and research promises.

Authors:  Thoralf Niendorf; Daniel K Sodickson; Gabriele A Krombach; Jeanette Schulz-Menger
Journal:  Eur Radiol       Date:  2010-07-31       Impact factor: 5.315

Review 8.  The future of acquisition speed, coverage, sensitivity, and resolution.

Authors:  Lawrence L Wald
Journal:  Neuroimage       Date:  2012-03-06       Impact factor: 6.556

9.  Precompensation for mutual coupling between array elements in parallel excitation.

Authors:  Yong Pang; Xiaoliang Zhang
Journal:  Quant Imaging Med Surg       Date:  2011-12

10.  Specific absorption rate studies of the parallel transmission of inner-volume excitations at 7T.

Authors:  Adam C Zelinski; Leonardo M Angelone; Vivek K Goyal; Giorgio Bonmassar; Elfar Adalsteinsson; Lawrence L Wald
Journal:  J Magn Reson Imaging       Date:  2008-10       Impact factor: 4.813
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