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An illustrated comparison of processing methods for MR phase imaging and QSM: combining array coil signals and phase unwrapping

Journal article

S. Robinson, K. Bredies, Diana Khabipova, B. Dymerska, J. Marques, F. Schweser
NMR in biomedicine, 2016
Semantic Scholar DOI PubMedCentral PubMed
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APA   Click to copy
Robinson, S., Bredies, K., Khabipova, D., Dymerska, B., Marques, J., & Schweser, F. (2016). An illustrated comparison of processing methods for MR phase imaging and QSM: combining array coil signals and phase unwrapping. NMR in Biomedicine.

Chicago/Turabian   Click to copy
Robinson, S., K. Bredies, Diana Khabipova, B. Dymerska, J. Marques, and F. Schweser. “An Illustrated Comparison of Processing Methods for MR Phase Imaging and QSM: Combining Array Coil Signals and Phase Unwrapping.” NMR in biomedicine (2016).

MLA   Click to copy
Robinson, S., et al. “An Illustrated Comparison of Processing Methods for MR Phase Imaging and QSM: Combining Array Coil Signals and Phase Unwrapping.” NMR in Biomedicine, 2016.

BibTeX   Click to copy 

@article{s2016a,
  title = {An illustrated comparison of processing methods for MR phase imaging and QSM: combining array coil signals and phase unwrapping},
  year = {2016},
  journal = {NMR in biomedicine},
  author = {Robinson, S. and Bredies, K. and Khabipova, Diana and Dymerska, B. and Marques, J. and Schweser, F.}
}

Abstract

Phase imaging benefits from strong susceptibility effects at very high field and the high signal‐to‐noise ratio (SNR) afforded by multi‐channel coils. Combining the information from coils is not trivial, however, as the phase that originates in local field effects (the source of interesting contrast) is modified by the inhomogeneous sensitivity of each coil. This has historically been addressed by referencing individual coil sensitivities to that of a volume coil, but alternative approaches are required for ultra‐high field systems in which no such coil is available. An additional challenge in phase imaging is that the phase that develops up to the echo time is “wrapped” into a range of 2π radians. Phase wraps need to be removed in order to reveal the underlying phase distribution of interest.