Practical issues and limitations of brain attenuation correction on a simultaneous PET-MR scanner

BACKGROUND: Despite the advent of clinical PET-MR imaging for routine use in 2011 and the development of several methods to address the problem of attenuation correction, some challenges remain. We have identified and investigated several issues that might affect the reliability and accuracy of curr...

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Autores principales: Mackewn, J. E., Stirling, J., Jeljeli, S., Gould, S-M., Johnstone, R. I., Merida, I., Pike, L. C., McGinnity, C. J., Beck, K., Howes, O., Hammers, A., Marsden, P. K.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Springer International Publishing 2020
Materias:
Original Research
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7200964/
https://www.ncbi.nlm.nih.gov/pubmed/32372135
http://dx.doi.org/10.1186/s40658-020-00295-x
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author Mackewn, J. E.
Stirling, J.
Jeljeli, S.
Gould, S-M.
Johnstone, R. I.
Merida, I.
Pike, L. C.
McGinnity, C. J.
Beck, K.
Howes, O.
Hammers, A.
Marsden, P. K.
author_facet Mackewn, J. E.
Stirling, J.
Jeljeli, S.
Gould, S-M.
Johnstone, R. I.
Merida, I.
Pike, L. C.
McGinnity, C. J.
Beck, K.
Howes, O.
Hammers, A.
Marsden, P. K.
author_sort Mackewn, J. E.
collection PubMed
description BACKGROUND: Despite the advent of clinical PET-MR imaging for routine use in 2011 and the development of several methods to address the problem of attenuation correction, some challenges remain. We have identified and investigated several issues that might affect the reliability and accuracy of current attenuation correction methods when these are implemented for clinical and research studies of the brain. These are (1) the accuracy of converting CT Hounsfield units, obtained from an independently acquired CT scan, to 511 keV linear attenuation coefficients; (2) the effect of padding used in the MR head coil; (3) the presence of close-packed hair; (4) the effect of headphones. For each of these, we have examined the effect on reconstructed PET images and evaluated practical mitigating measures. RESULTS: Our major findings were (1) for both Siemens and GE PET-MR systems, CT data from either a Siemens or a GE PET-CT scanner may be used, provided the conversion to 511 keV μ-map is performed by the PET-MR vendor’s own method, as implemented on their PET-CT scanner; (2) the effect of the head coil pads is minimal; (3) the effect of dense hair in the field of view is marked (> 10% error in reconstructed PET images); and (4) using headphones and not including them in the attenuation map causes significant errors in reconstructed PET images, but the risk of scanning without them may be acceptable following sound level measurements. CONCLUSIONS: It is important that the limitations of attenuation correction in PET-MR are considered when designing research and clinical PET-MR protocols in order to enable accurate quantification of brain PET scans. Whilst the effect of pads is not significant, dense hair, the use of headphones and the use of an independently acquired CT-scan can all lead to non-negligible effects on PET quantification. Although seemingly trivial, these effects add complications to setting up protocols for clinical and research PET-MR studies that do not occur with PET-CT. In the absence of more sophisticated PET-MR brain attenuation correction, the effect of all of the issues above can be minimised if the pragmatic approaches presented in this work are followed.
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spelling pubmed-72009642020-05-12 Practical issues and limitations of brain attenuation correction on a simultaneous PET-MR scanner Mackewn, J. E. Stirling, J. Jeljeli, S. Gould, S-M. Johnstone, R. I. Merida, I. Pike, L. C. McGinnity, C. J. Beck, K. Howes, O. Hammers, A. Marsden, P. K. EJNMMI Phys Original Research BACKGROUND: Despite the advent of clinical PET-MR imaging for routine use in 2011 and the development of several methods to address the problem of attenuation correction, some challenges remain. We have identified and investigated several issues that might affect the reliability and accuracy of current attenuation correction methods when these are implemented for clinical and research studies of the brain. These are (1) the accuracy of converting CT Hounsfield units, obtained from an independently acquired CT scan, to 511 keV linear attenuation coefficients; (2) the effect of padding used in the MR head coil; (3) the presence of close-packed hair; (4) the effect of headphones. For each of these, we have examined the effect on reconstructed PET images and evaluated practical mitigating measures. RESULTS: Our major findings were (1) for both Siemens and GE PET-MR systems, CT data from either a Siemens or a GE PET-CT scanner may be used, provided the conversion to 511 keV μ-map is performed by the PET-MR vendor’s own method, as implemented on their PET-CT scanner; (2) the effect of the head coil pads is minimal; (3) the effect of dense hair in the field of view is marked (> 10% error in reconstructed PET images); and (4) using headphones and not including them in the attenuation map causes significant errors in reconstructed PET images, but the risk of scanning without them may be acceptable following sound level measurements. CONCLUSIONS: It is important that the limitations of attenuation correction in PET-MR are considered when designing research and clinical PET-MR protocols in order to enable accurate quantification of brain PET scans. Whilst the effect of pads is not significant, dense hair, the use of headphones and the use of an independently acquired CT-scan can all lead to non-negligible effects on PET quantification. Although seemingly trivial, these effects add complications to setting up protocols for clinical and research PET-MR studies that do not occur with PET-CT. In the absence of more sophisticated PET-MR brain attenuation correction, the effect of all of the issues above can be minimised if the pragmatic approaches presented in this work are followed. Springer International Publishing 2020-05-05 /pmc/articles/PMC7200964/ /pubmed/32372135 http://dx.doi.org/10.1186/s40658-020-00295-x Text en © The Author(s) 2020, corrected publication 2020 Open AccessThis article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
spellingShingle Original Research
Mackewn, J. E.
Stirling, J.
Jeljeli, S.
Gould, S-M.
Johnstone, R. I.
Merida, I.
Pike, L. C.
McGinnity, C. J.
Beck, K.
Howes, O.
Hammers, A.
Marsden, P. K.
Practical issues and limitations of brain attenuation correction on a simultaneous PET-MR scanner
title Practical issues and limitations of brain attenuation correction on a simultaneous PET-MR scanner
title_full Practical issues and limitations of brain attenuation correction on a simultaneous PET-MR scanner
title_fullStr Practical issues and limitations of brain attenuation correction on a simultaneous PET-MR scanner
title_full_unstemmed Practical issues and limitations of brain attenuation correction on a simultaneous PET-MR scanner
title_short Practical issues and limitations of brain attenuation correction on a simultaneous PET-MR scanner
title_sort practical issues and limitations of brain attenuation correction on a simultaneous pet-mr scanner
topic Original Research
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7200964/
https://www.ncbi.nlm.nih.gov/pubmed/32372135
http://dx.doi.org/10.1186/s40658-020-00295-x
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