Optimized MLAA for quantitative non-TOF PET/MR of the brain

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

Optimized MLAA for quantitative non-TOF PET/MR of the brain. / Benoit, Didier; Ladefoged, Claes N.; Rezaei, Ahmadreza; Keller, Sune H.; Andersen, Flemming L; Højgaard, Liselotte; Hansen, Adam Espe; Holm, Søren; Nuyts, Johan.

In: Physics in Medicine and Biology, Vol. 61, No. 24, 8854, 02.12.2016.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Benoit, D, Ladefoged, CN, Rezaei, A, Keller, SH, Andersen, FL, Højgaard, L, Hansen, AE, Holm, S & Nuyts, J 2016, 'Optimized MLAA for quantitative non-TOF PET/MR of the brain', Physics in Medicine and Biology, vol. 61, no. 24, 8854. https://doi.org/10.1088/1361-6560/61/24/8854

APA

Benoit, D., Ladefoged, C. N., Rezaei, A., Keller, S. H., Andersen, F. L., Højgaard, L., Hansen, A. E., Holm, S., & Nuyts, J. (2016). Optimized MLAA for quantitative non-TOF PET/MR of the brain. Physics in Medicine and Biology, 61(24), [8854]. https://doi.org/10.1088/1361-6560/61/24/8854

Vancouver

Benoit D, Ladefoged CN, Rezaei A, Keller SH, Andersen FL, Højgaard L et al. Optimized MLAA for quantitative non-TOF PET/MR of the brain. Physics in Medicine and Biology. 2016 Dec 2;61(24). 8854. https://doi.org/10.1088/1361-6560/61/24/8854

Author

Benoit, Didier ; Ladefoged, Claes N. ; Rezaei, Ahmadreza ; Keller, Sune H. ; Andersen, Flemming L ; Højgaard, Liselotte ; Hansen, Adam Espe ; Holm, Søren ; Nuyts, Johan. / Optimized MLAA for quantitative non-TOF PET/MR of the brain. In: Physics in Medicine and Biology. 2016 ; Vol. 61, No. 24.

Bibtex

@article{a3cbf46217494cec9c9d7a43af655a8b,
title = "Optimized MLAA for quantitative non-TOF PET/MR of the brain",
abstract = "For quantitative tracer distribution in positron emission tomography, attenuation correction is essential. In a hybrid PET/CT system the CT images serve as a basis for generation of the attenuation map, but in PET/MR, the MR images do not have a similarly simple relationship with the attenuation map. Hence attenuation correction in PET/MR systems is more challenging. Typically either of two MR sequences are used: the Dixon or the ultra-short time echo (UTE) techniques. However these sequences have some well-known limitations. In this study, a reconstruction technique based on a modified and optimized non-TOF MLAA is proposed for PET/MR brain imaging. The idea is to tune the parameters of the MLTR applying some information from an attenuation image computed from the UTE sequences and a T1w MR image. In this MLTR algorithm, an [Formula: see text] parameter is introduced and optimized in order to drive the algorithm to a final attenuation map most consistent with the emission data. Because the non-TOF MLAA is used, a technique to reduce the cross-talk effect is proposed. In this study, the proposed algorithm is compared to the common reconstruction methods such as OSEM using a CT attenuation map, considered as the reference, and OSEM using the Dixon and UTE attenuation maps. To show the robustness and the reproducibility of the proposed algorithm, a set of 204 [(18)F]FDG patients, 35 [(11)C]PiB patients and 1 [(18)F]FET patient are used. The results show that by choosing an optimized value of [Formula: see text] in MLTR, the proposed algorithm improves the results compared to the standard MR-based attenuation correction methods (i.e. OSEM using the Dixon or the UTE attenuation maps), and the cross-talk and the scale problem are limited.",
keywords = "Journal Article",
author = "Didier Benoit and Ladefoged, {Claes N.} and Ahmadreza Rezaei and Keller, {Sune H.} and Andersen, {Flemming L} and Liselotte H{\o}jgaard and Hansen, {Adam Espe} and S{\o}ren Holm and Johan Nuyts",
year = "2016",
month = dec,
day = "2",
doi = "10.1088/1361-6560/61/24/8854",
language = "English",
volume = "61",
journal = "Physics in Medicine and Biology",
issn = "0031-9155",
publisher = "Institute of Physics Publishing Ltd",
number = "24",

}

RIS

TY - JOUR

T1 - Optimized MLAA for quantitative non-TOF PET/MR of the brain

AU - Benoit, Didier

AU - Ladefoged, Claes N.

AU - Rezaei, Ahmadreza

AU - Keller, Sune H.

AU - Andersen, Flemming L

AU - Højgaard, Liselotte

AU - Hansen, Adam Espe

AU - Holm, Søren

AU - Nuyts, Johan

PY - 2016/12/2

Y1 - 2016/12/2

N2 - For quantitative tracer distribution in positron emission tomography, attenuation correction is essential. In a hybrid PET/CT system the CT images serve as a basis for generation of the attenuation map, but in PET/MR, the MR images do not have a similarly simple relationship with the attenuation map. Hence attenuation correction in PET/MR systems is more challenging. Typically either of two MR sequences are used: the Dixon or the ultra-short time echo (UTE) techniques. However these sequences have some well-known limitations. In this study, a reconstruction technique based on a modified and optimized non-TOF MLAA is proposed for PET/MR brain imaging. The idea is to tune the parameters of the MLTR applying some information from an attenuation image computed from the UTE sequences and a T1w MR image. In this MLTR algorithm, an [Formula: see text] parameter is introduced and optimized in order to drive the algorithm to a final attenuation map most consistent with the emission data. Because the non-TOF MLAA is used, a technique to reduce the cross-talk effect is proposed. In this study, the proposed algorithm is compared to the common reconstruction methods such as OSEM using a CT attenuation map, considered as the reference, and OSEM using the Dixon and UTE attenuation maps. To show the robustness and the reproducibility of the proposed algorithm, a set of 204 [(18)F]FDG patients, 35 [(11)C]PiB patients and 1 [(18)F]FET patient are used. The results show that by choosing an optimized value of [Formula: see text] in MLTR, the proposed algorithm improves the results compared to the standard MR-based attenuation correction methods (i.e. OSEM using the Dixon or the UTE attenuation maps), and the cross-talk and the scale problem are limited.

AB - For quantitative tracer distribution in positron emission tomography, attenuation correction is essential. In a hybrid PET/CT system the CT images serve as a basis for generation of the attenuation map, but in PET/MR, the MR images do not have a similarly simple relationship with the attenuation map. Hence attenuation correction in PET/MR systems is more challenging. Typically either of two MR sequences are used: the Dixon or the ultra-short time echo (UTE) techniques. However these sequences have some well-known limitations. In this study, a reconstruction technique based on a modified and optimized non-TOF MLAA is proposed for PET/MR brain imaging. The idea is to tune the parameters of the MLTR applying some information from an attenuation image computed from the UTE sequences and a T1w MR image. In this MLTR algorithm, an [Formula: see text] parameter is introduced and optimized in order to drive the algorithm to a final attenuation map most consistent with the emission data. Because the non-TOF MLAA is used, a technique to reduce the cross-talk effect is proposed. In this study, the proposed algorithm is compared to the common reconstruction methods such as OSEM using a CT attenuation map, considered as the reference, and OSEM using the Dixon and UTE attenuation maps. To show the robustness and the reproducibility of the proposed algorithm, a set of 204 [(18)F]FDG patients, 35 [(11)C]PiB patients and 1 [(18)F]FET patient are used. The results show that by choosing an optimized value of [Formula: see text] in MLTR, the proposed algorithm improves the results compared to the standard MR-based attenuation correction methods (i.e. OSEM using the Dixon or the UTE attenuation maps), and the cross-talk and the scale problem are limited.

KW - Journal Article

U2 - 10.1088/1361-6560/61/24/8854

DO - 10.1088/1361-6560/61/24/8854

M3 - Journal article

C2 - 27910823

VL - 61

JO - Physics in Medicine and Biology

JF - Physics in Medicine and Biology

SN - 0031-9155

IS - 24

M1 - 8854

ER -

ID: 179311489