MR Biophysics Lab

Buffalo Neuroimaging Analysis Center

SAR in Parallel Transmission


Journal article


I. Graesslin, D. Glaesel, S. Biederer, F. Schweser, P. Vernickel, Peter Börnert, B. Annighoefer, H. Stahl, H. Dingemans, G. Mens, P. Harvey, U. Katscher
2008

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APA   Click to copy
Graesslin, I., Glaesel, D., Biederer, S., Schweser, F., Vernickel, P., Börnert, P., … Katscher, U. (2008). SAR in Parallel Transmission.


Chicago/Turabian   Click to copy
Graesslin, I., D. Glaesel, S. Biederer, F. Schweser, P. Vernickel, Peter Börnert, B. Annighoefer, et al. “SAR in Parallel Transmission” (2008).


MLA   Click to copy
Graesslin, I., et al. SAR in Parallel Transmission. 2008.


BibTeX   Click to copy

@article{i2008a,
  title = {SAR in Parallel Transmission},
  year = {2008},
  author = {Graesslin, I. and Glaesel, D. and Biederer, S. and Schweser, F. and Vernickel, P. and Börnert, Peter and Annighoefer, B. and Stahl, H. and Dingemans, H. and Mens, G. and Harvey, P. and Katscher, U.}
}

Abstract

Parallel transmission bears the potential of compensating B1 fleld inhomogeneities induced by wave propagation efiects in (ultra) high fleld whole body MR imaging. However, with increasing fleld strength, the RF power deposition and the associated local speciflc absorption rate (SAR) represent an important attention point with respect to patient safety. This paper presents simulations of a 3T whole body eight-channel transmit/receive body coil loaded with a human bio-mesh model. Phantom SAR simulations were carried out and validated by temperature measurements. A good correlation between SAR simulations and measured temperature was obtained, so that the FDTD method can be considered to be a valuable tool in determining (local) SAR for patient safety in multi-channel transmission MRI systems.