Magnetic Resonance in Medicine

Cover image for Vol. 71 Issue 4

April 2014

Volume 71, Issue 4

Pages spcone–spcone, 1349–1656

  1. Cover Image

    1. Top of page
    2. Cover Image
    3. Masthead
    4. Spectroscopic Methodology—Rapid Communication
    5. Spectroscopic Methodology—Full Paper
    6. Spectroscopic Methodology—Note
    7. Imaging Methodology—Rapid Communication
    8. Imaging Methodology—Full Papers
    9. Imaging Methodology—Notes
    10. Preclinical and Clinical Imaging—Mini Review
    11. Preclinical and Clinical Imaging—Full Papers
    12. Preclinical and Clinical Imaging—Note
    13. Biophysics and Basic Biomedical Research—Full Paper
    14. Biophysics and Basic Biomedical Research—Notes
    15. Computer Processing and Modeling—Full Papers
    16. Hardware and Instrumentation—Full Papers
    17. ESR—Full Paper
  2. Masthead

    1. Top of page
    2. Cover Image
    3. Masthead
    4. Spectroscopic Methodology—Rapid Communication
    5. Spectroscopic Methodology—Full Paper
    6. Spectroscopic Methodology—Note
    7. Imaging Methodology—Rapid Communication
    8. Imaging Methodology—Full Papers
    9. Imaging Methodology—Notes
    10. Preclinical and Clinical Imaging—Mini Review
    11. Preclinical and Clinical Imaging—Full Papers
    12. Preclinical and Clinical Imaging—Note
    13. Biophysics and Basic Biomedical Research—Full Paper
    14. Biophysics and Basic Biomedical Research—Notes
    15. Computer Processing and Modeling—Full Papers
    16. Hardware and Instrumentation—Full Papers
    17. ESR—Full Paper
    1. Masthead, Volume 71, Issue 4 (page spcone)

      Article first published online: 19 MAR 2014 | DOI: 10.1002/mrm.25231

  3. Spectroscopic Methodology—Rapid Communication

    1. Top of page
    2. Cover Image
    3. Masthead
    4. Spectroscopic Methodology—Rapid Communication
    5. Spectroscopic Methodology—Full Paper
    6. Spectroscopic Methodology—Note
    7. Imaging Methodology—Rapid Communication
    8. Imaging Methodology—Full Papers
    9. Imaging Methodology—Notes
    10. Preclinical and Clinical Imaging—Mini Review
    11. Preclinical and Clinical Imaging—Full Papers
    12. Preclinical and Clinical Imaging—Note
    13. Biophysics and Basic Biomedical Research—Full Paper
    14. Biophysics and Basic Biomedical Research—Notes
    15. Computer Processing and Modeling—Full Papers
    16. Hardware and Instrumentation—Full Papers
    17. ESR—Full Paper
  4. Spectroscopic Methodology—Full Paper

    1. Top of page
    2. Cover Image
    3. Masthead
    4. Spectroscopic Methodology—Rapid Communication
    5. Spectroscopic Methodology—Full Paper
    6. Spectroscopic Methodology—Note
    7. Imaging Methodology—Rapid Communication
    8. Imaging Methodology—Full Papers
    9. Imaging Methodology—Notes
    10. Preclinical and Clinical Imaging—Mini Review
    11. Preclinical and Clinical Imaging—Full Papers
    12. Preclinical and Clinical Imaging—Note
    13. Biophysics and Basic Biomedical Research—Full Paper
    14. Biophysics and Basic Biomedical Research—Notes
    15. Computer Processing and Modeling—Full Papers
    16. Hardware and Instrumentation—Full Papers
    17. ESR—Full Paper
    1. MRSI of the medial temporal lobe at 7 T in explosive blast mild traumatic brain injury (pages 1358–1367)

      Hoby P. Hetherington, Hamada Hamid, Joseph Kulas, Geoffrey Ling, Faris Bandak, Nihal C. de Lanerolle and Jullie W. Pan

      Article first published online: 5 AUG 2013 | DOI: 10.1002/mrm.24814

  5. Spectroscopic Methodology—Note

    1. Top of page
    2. Cover Image
    3. Masthead
    4. Spectroscopic Methodology—Rapid Communication
    5. Spectroscopic Methodology—Full Paper
    6. Spectroscopic Methodology—Note
    7. Imaging Methodology—Rapid Communication
    8. Imaging Methodology—Full Papers
    9. Imaging Methodology—Notes
    10. Preclinical and Clinical Imaging—Mini Review
    11. Preclinical and Clinical Imaging—Full Papers
    12. Preclinical and Clinical Imaging—Note
    13. Biophysics and Basic Biomedical Research—Full Paper
    14. Biophysics and Basic Biomedical Research—Notes
    15. Computer Processing and Modeling—Full Papers
    16. Hardware and Instrumentation—Full Papers
    17. ESR—Full Paper
  6. Imaging Methodology—Rapid Communication

    1. Top of page
    2. Cover Image
    3. Masthead
    4. Spectroscopic Methodology—Rapid Communication
    5. Spectroscopic Methodology—Full Paper
    6. Spectroscopic Methodology—Note
    7. Imaging Methodology—Rapid Communication
    8. Imaging Methodology—Full Papers
    9. Imaging Methodology—Notes
    10. Preclinical and Clinical Imaging—Mini Review
    11. Preclinical and Clinical Imaging—Full Papers
    12. Preclinical and Clinical Imaging—Note
    13. Biophysics and Basic Biomedical Research—Full Paper
    14. Biophysics and Basic Biomedical Research—Notes
    15. Computer Processing and Modeling—Full Papers
    16. Hardware and Instrumentation—Full Papers
    17. ESR—Full Paper
  7. Imaging Methodology—Full Papers

    1. Top of page
    2. Cover Image
    3. Masthead
    4. Spectroscopic Methodology—Rapid Communication
    5. Spectroscopic Methodology—Full Paper
    6. Spectroscopic Methodology—Note
    7. Imaging Methodology—Rapid Communication
    8. Imaging Methodology—Full Papers
    9. Imaging Methodology—Notes
    10. Preclinical and Clinical Imaging—Mini Review
    11. Preclinical and Clinical Imaging—Full Papers
    12. Preclinical and Clinical Imaging—Note
    13. Biophysics and Basic Biomedical Research—Full Paper
    14. Biophysics and Basic Biomedical Research—Notes
    15. Computer Processing and Modeling—Full Papers
    16. Hardware and Instrumentation—Full Papers
    17. ESR—Full Paper
    1. Toward real-time availability of 3D temperature maps created with temporally constrained reconstruction (pages 1394–1404)

      Nick Todd, Jaya Prakash, Henrik Odéen, Josh de Bever, Allison Payne, Phaneendra Yalavarthy and Dennis L. Parker

      Article first published online: 13 MAY 2013 | DOI: 10.1002/mrm.24783

    2. Mapping mean and fluctuating velocities by Bayesian multipoint MR velocity encoding-validation against 3D particle tracking velocimetry (pages 1405–1415)

      Verena Knobloch, Christian Binter, Utku Gülan, Andreas Sigfridsson, Markus Holzner, Beat Lüthi and Sebastian Kozerke

      Article first published online: 13 MAY 2013 | DOI: 10.1002/mrm.24785

    3. Simultaneous multislice excitation by parallel transmission (pages 1416–1427)

      Benedikt A. Poser, Robert James Anderson, Bastien Guérin, Kawin Setsompop, Weiran Deng, Azma Mareyam, Peter Serano, Lawrence L. Wald and V. Andrew Stenger

      Article first published online: 28 MAY 2013 | DOI: 10.1002/mrm.24791

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      Adiabatic inversion pulses for myocardial T1 mapping (pages 1428–1434)

      Peter Kellman, Daniel A. Herzka and Michael Schacht Hansen

      Article first published online: 30 MAY 2013 | DOI: 10.1002/mrm.24793

    5. You have free access to this content
    6. Improving T2-weighted imaging at high field through the use of kT-points (pages 1478–1488)

      Florent Eggenschwiler, Kieran R. O'Brien, Rolf Gruetter and José P. Marques

      Article first published online: 20 JUN 2013 | DOI: 10.1002/mrm.24805

    7. Fast noniterative calibration of an external motion tracking device (pages 1489–1500)

      Benjamin Zahneisen, Chris Lovell-Smith, Michael Herbst, Maxim Zaitsev, Oliver Speck, Brian Armstrong and Thomas Ernst

      Article first published online: 20 JUN 2013 | DOI: 10.1002/mrm.24806

    8. Real-time 3D magnetic resonance imaging of the pharyngeal airway in sleep apnea (pages 1501–1510)

      Yoon-Chul Kim, R. Marc Lebel, Ziyue Wu, Sally L. Davidson Ward, Michael C.K. Khoo and Krishna S. Nayak

      Article first published online: 20 JUN 2013 | DOI: 10.1002/mrm.24808

  8. Imaging Methodology—Notes

    1. Top of page
    2. Cover Image
    3. Masthead
    4. Spectroscopic Methodology—Rapid Communication
    5. Spectroscopic Methodology—Full Paper
    6. Spectroscopic Methodology—Note
    7. Imaging Methodology—Rapid Communication
    8. Imaging Methodology—Full Papers
    9. Imaging Methodology—Notes
    10. Preclinical and Clinical Imaging—Mini Review
    11. Preclinical and Clinical Imaging—Full Papers
    12. Preclinical and Clinical Imaging—Note
    13. Biophysics and Basic Biomedical Research—Full Paper
    14. Biophysics and Basic Biomedical Research—Notes
    15. Computer Processing and Modeling—Full Papers
    16. Hardware and Instrumentation—Full Papers
    17. ESR—Full Paper
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      Homogenous fat suppression for bilateral breast imaging using independent shims (pages 1511–1517)

      Misung Han, Charles H. Cunningham, John M. Pauly, Bruce L. Daniel and Brian A. Hargreaves

      Article first published online: 2 JUL 2013 | DOI: 10.1002/mrm.24803

    2. Slice accelerated diffusion-weighted imaging at ultra-high field strength (pages 1518–1525)

      Cornelius Eichner, Kawin Setsompop, Peter J. Koopmans, Ralf Lützkendorf, David G. Norris, Robert Turner, Lawrence L. Wald and Robin M. Heidemann

      Article first published online: 24 JUN 2013 | DOI: 10.1002/mrm.24809

  9. Preclinical and Clinical Imaging—Mini Review

    1. Top of page
    2. Cover Image
    3. Masthead
    4. Spectroscopic Methodology—Rapid Communication
    5. Spectroscopic Methodology—Full Paper
    6. Spectroscopic Methodology—Note
    7. Imaging Methodology—Rapid Communication
    8. Imaging Methodology—Full Papers
    9. Imaging Methodology—Notes
    10. Preclinical and Clinical Imaging—Mini Review
    11. Preclinical and Clinical Imaging—Full Papers
    12. Preclinical and Clinical Imaging—Note
    13. Biophysics and Basic Biomedical Research—Full Paper
    14. Biophysics and Basic Biomedical Research—Notes
    15. Computer Processing and Modeling—Full Papers
    16. Hardware and Instrumentation—Full Papers
    17. ESR—Full Paper
    1. You have free access to this content
  10. Preclinical and Clinical Imaging—Full Papers

    1. Top of page
    2. Cover Image
    3. Masthead
    4. Spectroscopic Methodology—Rapid Communication
    5. Spectroscopic Methodology—Full Paper
    6. Spectroscopic Methodology—Note
    7. Imaging Methodology—Rapid Communication
    8. Imaging Methodology—Full Papers
    9. Imaging Methodology—Notes
    10. Preclinical and Clinical Imaging—Mini Review
    11. Preclinical and Clinical Imaging—Full Papers
    12. Preclinical and Clinical Imaging—Note
    13. Biophysics and Basic Biomedical Research—Full Paper
    14. Biophysics and Basic Biomedical Research—Notes
    15. Computer Processing and Modeling—Full Papers
    16. Hardware and Instrumentation—Full Papers
    17. ESR—Full Paper
    1. 4D flow magnetic resonance imaging in bicuspid aortic valve disease demonstrates altered distribution of aortic blood flow helicity (pages 1542–1553)

      R. Lorenz, J. Bock, A. J. Barker, F. von Knobelsdorff-Brenkenhoff, W. Wallis, J. G. Korvink, M. M. Bissell, J. Schulz-Menger and M. Markl

      Article first published online: 28 MAY 2013 | DOI: 10.1002/mrm.24802

  11. Preclinical and Clinical Imaging—Note

    1. Top of page
    2. Cover Image
    3. Masthead
    4. Spectroscopic Methodology—Rapid Communication
    5. Spectroscopic Methodology—Full Paper
    6. Spectroscopic Methodology—Note
    7. Imaging Methodology—Rapid Communication
    8. Imaging Methodology—Full Papers
    9. Imaging Methodology—Notes
    10. Preclinical and Clinical Imaging—Mini Review
    11. Preclinical and Clinical Imaging—Full Papers
    12. Preclinical and Clinical Imaging—Note
    13. Biophysics and Basic Biomedical Research—Full Paper
    14. Biophysics and Basic Biomedical Research—Notes
    15. Computer Processing and Modeling—Full Papers
    16. Hardware and Instrumentation—Full Papers
    17. ESR—Full Paper
    1. Tumor perfusion-related parameter of diffusion-weighted magnetic resonance imaging: Correlation with histological microvessel density (pages 1554–1558)

      Hye-Jeong Lee, Sun Young Rha, Yong Eun Chung, Hyo Sub Shim, Young Jin Kim, Jin Hur, Yoo Jin Hong and Byoung Wook Choi

      Article first published online: 24 JUN 2013 | DOI: 10.1002/mrm.24810

  12. Biophysics and Basic Biomedical Research—Full Paper

    1. Top of page
    2. Cover Image
    3. Masthead
    4. Spectroscopic Methodology—Rapid Communication
    5. Spectroscopic Methodology—Full Paper
    6. Spectroscopic Methodology—Note
    7. Imaging Methodology—Rapid Communication
    8. Imaging Methodology—Full Papers
    9. Imaging Methodology—Notes
    10. Preclinical and Clinical Imaging—Mini Review
    11. Preclinical and Clinical Imaging—Full Papers
    12. Preclinical and Clinical Imaging—Note
    13. Biophysics and Basic Biomedical Research—Full Paper
    14. Biophysics and Basic Biomedical Research—Notes
    15. Computer Processing and Modeling—Full Papers
    16. Hardware and Instrumentation—Full Papers
    17. ESR—Full Paper
    1. Intersubject local SAR variation for 7T prostate MR imaging with an eight-channel single-side adapted dipole antenna array (pages 1559–1567)

      Özlem Ipek, Alexander J. Raaijmakers, Jan J. Lagendijk, Peter R. Luijten and Cornelis A. T. van den Berg

      Article first published online: 10 JUN 2013 | DOI: 10.1002/mrm.24794

  13. Biophysics and Basic Biomedical Research—Notes

    1. Top of page
    2. Cover Image
    3. Masthead
    4. Spectroscopic Methodology—Rapid Communication
    5. Spectroscopic Methodology—Full Paper
    6. Spectroscopic Methodology—Note
    7. Imaging Methodology—Rapid Communication
    8. Imaging Methodology—Full Papers
    9. Imaging Methodology—Notes
    10. Preclinical and Clinical Imaging—Mini Review
    11. Preclinical and Clinical Imaging—Full Papers
    12. Preclinical and Clinical Imaging—Note
    13. Biophysics and Basic Biomedical Research—Full Paper
    14. Biophysics and Basic Biomedical Research—Notes
    15. Computer Processing and Modeling—Full Papers
    16. Hardware and Instrumentation—Full Papers
    17. ESR—Full Paper
    1. Temperature-induced changes of magnetic resonance relaxation times in the human brain: A postmortem study (pages 1575–1580)

      Christoph Birkl, Christian Langkammer, Johannes Haybaeck, Christina Ernst, Rudolf Stollberger, Franz Fazekas and Stefan Ropele

      Article first published online: 28 MAY 2013 | DOI: 10.1002/mrm.24799

  14. Computer Processing and Modeling—Full Papers

    1. Top of page
    2. Cover Image
    3. Masthead
    4. Spectroscopic Methodology—Rapid Communication
    5. Spectroscopic Methodology—Full Paper
    6. Spectroscopic Methodology—Note
    7. Imaging Methodology—Rapid Communication
    8. Imaging Methodology—Full Papers
    9. Imaging Methodology—Notes
    10. Preclinical and Clinical Imaging—Mini Review
    11. Preclinical and Clinical Imaging—Full Papers
    12. Preclinical and Clinical Imaging—Note
    13. Biophysics and Basic Biomedical Research—Full Paper
    14. Biophysics and Basic Biomedical Research—Notes
    15. Computer Processing and Modeling—Full Papers
    16. Hardware and Instrumentation—Full Papers
    17. ESR—Full Paper
    1. Constrained diffusion kurtosis imaging using ternary quartics & MLE (pages 1581–1591)

      Aurobrata Ghosh, Tristan Milne and Rachid Deriche

      Article first published online: 2 JUL 2013 | DOI: 10.1002/mrm.24781

    2. DCE-MRI analysis methods for predicting the response of breast cancer to neoadjuvant chemotherapy: Pilot study findings (pages 1592–1602)

      Xia Li, Lori R. Arlinghaus, Gregory D. Ayers, A. Bapsi Chakravarthy, Richard G. Abramson, Vandana G. Abramson, Nkiruka Atuegwu, Jaime Farley, Ingrid A. Mayer, Mark C. Kelley, Ingrid M. Meszoely, Julie Means-Powell, Ana M. Grau, Melinda Sanders, Sandeep R. Bhave and Thomas E. Yankeelov

      Article first published online: 9 MAY 2013 | DOI: 10.1002/mrm.24782

  15. Hardware and Instrumentation—Full Papers

    1. Top of page
    2. Cover Image
    3. Masthead
    4. Spectroscopic Methodology—Rapid Communication
    5. Spectroscopic Methodology—Full Paper
    6. Spectroscopic Methodology—Note
    7. Imaging Methodology—Rapid Communication
    8. Imaging Methodology—Full Papers
    9. Imaging Methodology—Notes
    10. Preclinical and Clinical Imaging—Mini Review
    11. Preclinical and Clinical Imaging—Full Papers
    12. Preclinical and Clinical Imaging—Note
    13. Biophysics and Basic Biomedical Research—Full Paper
    14. Biophysics and Basic Biomedical Research—Notes
    15. Computer Processing and Modeling—Full Papers
    16. Hardware and Instrumentation—Full Papers
    17. ESR—Full Paper
    1. Improved steering of the RF field of traveling wave MR with a multimode, coaxial waveguide (pages 1641–1649)

      A. Andreychenko, H. Kroeze, V. O. Boer, J. J. W. Lagendijk, P. R. Luijten and C. A. T. van den Berg

      Article first published online: 20 JUN 2013 | DOI: 10.1002/mrm.24807

  16. ESR—Full Paper

    1. Top of page
    2. Cover Image
    3. Masthead
    4. Spectroscopic Methodology—Rapid Communication
    5. Spectroscopic Methodology—Full Paper
    6. Spectroscopic Methodology—Note
    7. Imaging Methodology—Rapid Communication
    8. Imaging Methodology—Full Papers
    9. Imaging Methodology—Notes
    10. Preclinical and Clinical Imaging—Mini Review
    11. Preclinical and Clinical Imaging—Full Papers
    12. Preclinical and Clinical Imaging—Note
    13. Biophysics and Basic Biomedical Research—Full Paper
    14. Biophysics and Basic Biomedical Research—Notes
    15. Computer Processing and Modeling—Full Papers
    16. Hardware and Instrumentation—Full Papers
    17. ESR—Full Paper

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