Free‐breathing self‐gated continuous‐IR spiral T1 mapping: Comparison of dual flip‐angle and Bloch‐Siegert B1‐corrected techniques

Purpose To develop a B1‐corrrected single flip‐angle continuous acquisition strategy with free‐breathing and cardiac self‐gating for spiral T1 mapping, and compare it to a previous dual flip‐angle technique. Methods Data were continuously acquired using a spiral‐out trajectory, rotated by the golden...

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Published inMagnetic resonance in medicine Vol. 88; no. 3; pp. 1068 - 1080
Main Authors Zhou, Ruixi, Wang, Junyu, Weller, Daniel S., Yang, Yang, Mugler, John P., Salerno, Michael
Format Journal Article
LanguageEnglish
Published United States Wiley Subscription Services, Inc 01.09.2022
John Wiley and Sons Inc
Subjects
B1 mapping
cardiac MRI
Data acquisition
dictionary learning
free‐breathing
Gating
Mapping
motion‐correction
Recovery
self‐gating
spiral trajectory
s–Imaging Methodology
T1 mapping
cardiac MRI
motion-correction
B1 mapping
free-breathing
dictionary learning
self-gating
T1 mapping
spiral trajectory
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Abstract Purpose To develop a B1‐corrrected single flip‐angle continuous acquisition strategy with free‐breathing and cardiac self‐gating for spiral T1 mapping, and compare it to a previous dual flip‐angle technique. Methods Data were continuously acquired using a spiral‐out trajectory, rotated by the golden angle in time. During the first 2 s, off‐resonance Fermi RF pulses were applied to generate a Bloch‐Siegert shift B1 map, and the subsequent data were acquired with an inversion RF pulse applied every 4 s to create a T1* map. The final T1 map was generated from the B1 and the T1* maps by using a look‐up table that accounted for slice profile effects, yielding more accurate T1 values. T1 values were compared to those from inversion recovery (IR) spin echo (phantom only), MOLLI, SAturation‐recovery single‐SHot Acquisition (SASHA), and previously proposed dual flip‐angle results. This strategy was evaluated in a phantom and 25 human subjects. Results The proposed technique showed good agreement with IR spin‐echo results in the phantom experiment. For in‐vivo studies, the proposed technique and the previously proposed dual flip‐angle method were more similar to SASHA results than to MOLLI results. Conclusions B1‐corrected single flip‐angle T1 mapping successfully acquired B1 and T1 maps in a free‐breathing, continuous‐IR spiral acquisition, providing a method with improved accuracy to measure T1 using a continuous Look‐Locker acquisition, as compared to the previously proposed dual excitation flip‐angle technique.
AbstractList PurposeTo develop a B1‐corrrected single flip‐angle continuous acquisition strategy with free‐breathing and cardiac self‐gating for spiral T1 mapping, and compare it to a previous dual flip‐angle technique.MethodsData were continuously acquired using a spiral‐out trajectory, rotated by the golden angle in time. During the first 2 s, off‐resonance Fermi RF pulses were applied to generate a Bloch‐Siegert shift B1 map, and the subsequent data were acquired with an inversion RF pulse applied every 4 s to create a T1* map. The final T1 map was generated from the B1 and the T1* maps by using a look‐up table that accounted for slice profile effects, yielding more accurate T1 values. T1 values were compared to those from inversion recovery (IR) spin echo (phantom only), MOLLI, SAturation‐recovery single‐SHot Acquisition (SASHA), and previously proposed dual flip‐angle results. This strategy was evaluated in a phantom and 25 human subjects.ResultsThe proposed technique showed good agreement with IR spin‐echo results in the phantom experiment. For in‐vivo studies, the proposed technique and the previously proposed dual flip‐angle method were more similar to SASHA results than to MOLLI results.ConclusionsB1‐corrected single flip‐angle T1 mapping successfully acquired B1 and T1 maps in a free‐breathing, continuous‐IR spiral acquisition, providing a method with improved accuracy to measure T1 using a continuous Look‐Locker acquisition, as compared to the previously proposed dual excitation flip‐angle technique.
To develop a B1-corrrected single flip-angle continuous acquisition strategy with free-breathing and cardiac self-gating for spiral T1 mapping, and compare it to a previous dual flip-angle technique.PURPOSETo develop a B1-corrrected single flip-angle continuous acquisition strategy with free-breathing and cardiac self-gating for spiral T1 mapping, and compare it to a previous dual flip-angle technique.Data were continuously acquired using a spiral-out trajectory, rotated by the golden angle in time. During the first 2 s, off-resonance Fermi RF pulses were applied to generate a Bloch-Siegert shift B1 map, and the subsequent data were acquired with an inversion RF pulse applied every 4 s to create a T1* map. The final T1 map was generated from the B1 and the T1* maps by using a look-up table that accounted for slice profile effects, yielding more accurate T1 values. T1 values were compared to those from inversion recovery (IR) spin echo (phantom only), MOLLI, SAturation-recovery single-SHot Acquisition (SASHA), and previously proposed dual flip-angle results. This strategy was evaluated in a phantom and 25 human subjects.METHODSData were continuously acquired using a spiral-out trajectory, rotated by the golden angle in time. During the first 2 s, off-resonance Fermi RF pulses were applied to generate a Bloch-Siegert shift B1 map, and the subsequent data were acquired with an inversion RF pulse applied every 4 s to create a T1* map. The final T1 map was generated from the B1 and the T1* maps by using a look-up table that accounted for slice profile effects, yielding more accurate T1 values. T1 values were compared to those from inversion recovery (IR) spin echo (phantom only), MOLLI, SAturation-recovery single-SHot Acquisition (SASHA), and previously proposed dual flip-angle results. This strategy was evaluated in a phantom and 25 human subjects.The proposed technique showed good agreement with IR spin-echo results in the phantom experiment. For in-vivo studies, the proposed technique and the previously proposed dual flip-angle method were more similar to SASHA results than to MOLLI results.RESULTSThe proposed technique showed good agreement with IR spin-echo results in the phantom experiment. For in-vivo studies, the proposed technique and the previously proposed dual flip-angle method were more similar to SASHA results than to MOLLI results.B1-corrected single flip-angle T1 mapping successfully acquired B1 and T1 maps in a free-breathing, continuous-IR spiral acquisition, providing a method with improved accuracy to measure T1 using a continuous Look-Locker acquisition, as compared to the previously proposed dual excitation flip-angle technique.CONCLUSIONSB1-corrected single flip-angle T1 mapping successfully acquired B1 and T1 maps in a free-breathing, continuous-IR spiral acquisition, providing a method with improved accuracy to measure T1 using a continuous Look-Locker acquisition, as compared to the previously proposed dual excitation flip-angle technique.
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To develop a B1-corrrected single flip-angle continuous acquisition strategy with free-breathing and cardiac self-gating for spiral T1 mapping, and compare it to a previous dual flip-angle technique. Data were continuously acquired using a spiral-out trajectory, rotated by the golden angle in time. During the first 2 s, off-resonance Fermi RF pulses were applied to generate a Bloch-Siegert shift B1 map, and the subsequent data were acquired with an inversion RF pulse applied every 4 s to create a T1* map. The final T1 map was generated from the B1 and the T1* maps by using a look-up table that accounted for slice profile effects, yielding more accurate T1 values. T1 values were compared to those from inversion recovery (IR) spin echo (phantom only), MOLLI, SAturation-recovery single-SHot Acquisition (SASHA), and previously proposed dual flip-angle results. This strategy was evaluated in a phantom and 25 human subjects. The proposed technique showed good agreement with IR spin-echo results in the phantom experiment. For in-vivo studies, the proposed technique and the previously proposed dual flip-angle method were more similar to SASHA results than to MOLLI results. B1-corrected single flip-angle T1 mapping successfully acquired B1 and T1 maps in a free-breathing, continuous-IR spiral acquisition, providing a method with improved accuracy to measure T1 using a continuous Look-Locker acquisition, as compared to the previously proposed dual excitation flip-angle technique.
Purpose To develop a B1‐corrrected single flip‐angle continuous acquisition strategy with free‐breathing and cardiac self‐gating for spiral T1 mapping, and compare it to a previous dual flip‐angle technique. Methods Data were continuously acquired using a spiral‐out trajectory, rotated by the golden angle in time. During the first 2 s, off‐resonance Fermi RF pulses were applied to generate a Bloch‐Siegert shift B1 map, and the subsequent data were acquired with an inversion RF pulse applied every 4 s to create a T1* map. The final T1 map was generated from the B1 and the T1* maps by using a look‐up table that accounted for slice profile effects, yielding more accurate T1 values. T1 values were compared to those from inversion recovery (IR) spin echo (phantom only), MOLLI, SAturation‐recovery single‐SHot Acquisition (SASHA), and previously proposed dual flip‐angle results. This strategy was evaluated in a phantom and 25 human subjects. Results The proposed technique showed good agreement with IR spin‐echo results in the phantom experiment. For in‐vivo studies, the proposed technique and the previously proposed dual flip‐angle method were more similar to SASHA results than to MOLLI results. Conclusions B1‐corrected single flip‐angle T1 mapping successfully acquired B1 and T1 maps in a free‐breathing, continuous‐IR spiral acquisition, providing a method with improved accuracy to measure T1 using a continuous Look‐Locker acquisition, as compared to the previously proposed dual excitation flip‐angle technique.
Author Weller, Daniel S.
Wang, Junyu
Zhou, Ruixi
Mugler, John P.
Salerno, Michael
Yang, Yang
AuthorAffiliation 1 Department of Artificial Intelligence Beijing University of Posts and Telecommunications Beijing China
2 Department of Biomedical Engineering University of Virginia Health System Charlottesville Virginia USA
3 KLA Tencor, GPG/AI Charlottesville Virginia USA
4 Biomedical Engineering and Imaging Institute and Department of Radiology Icahn School of Medicine at Mount Sinai New York New York USA
6 Department of Medicine, Cardiovascular Medicine and Department of Radiology, Cardiovascular Imaging Stanford University Palo Alto California USA
7 Department of Medicine, Cardiology Division, Radiology and Medical Imaging, and Biomedical Imaging University of Virginia Health System Charlottesville Virginia USA
5 Radiology & Medical Imaging, Biomedical Engineering University of Virginia Health System Charlottesville Virginia USA
AuthorAffiliation_xml – name: 5 Radiology & Medical Imaging, Biomedical Engineering University of Virginia Health System Charlottesville Virginia USA
– name: 7 Department of Medicine, Cardiology Division, Radiology and Medical Imaging, and Biomedical Imaging University of Virginia Health System Charlottesville Virginia USA
– name: 4 Biomedical Engineering and Imaging Institute and Department of Radiology Icahn School of Medicine at Mount Sinai New York New York USA
– name: 2 Department of Biomedical Engineering University of Virginia Health System Charlottesville Virginia USA
– name: 3 KLA Tencor, GPG/AI Charlottesville Virginia USA
– name: 1 Department of Artificial Intelligence Beijing University of Posts and Telecommunications Beijing China
– name: 6 Department of Medicine, Cardiovascular Medicine and Department of Radiology, Cardiovascular Imaging Stanford University Palo Alto California USA
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BackLink https://www.ncbi.nlm.nih.gov/pubmed/35481596$$D View this record in MEDLINE/PubMed
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CitedBy_id crossref_primary_10_1002_mrm_29846
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Issue 3
Keywords cardiac MRI
motion-correction
B1 mapping
free-breathing
dictionary learning
self-gating
T1 mapping
spiral trajectory
Language English
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Funding information NIH R01 HL131919, NIH R01 HL155962, Wallace H. Coulter Foundation Grant, American Heart Association Predoctoral Fellowship (19PRE34370037).
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Snippet Purpose To develop a B1‐corrrected single flip‐angle continuous acquisition strategy with free‐breathing and cardiac self‐gating for spiral T1 mapping, and...
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To develop a B1-corrrected single flip-angle continuous acquisition strategy with free-breathing and cardiac self-gating for spiral T1 mapping, and compare it...
PurposeTo develop a B1‐corrrected single flip‐angle continuous acquisition strategy with free‐breathing and cardiac self‐gating for spiral T1 mapping, and...
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SubjectTerms B1 mapping
cardiac MRI
Data acquisition
dictionary learning
free‐breathing
Gating
Mapping
motion‐correction
Recovery
self‐gating
spiral trajectory
s–Imaging Methodology
T1 mapping
Title Free‐breathing self‐gated continuous‐IR spiral T1 mapping: Comparison of dual flip‐angle and Bloch‐Siegert B1‐corrected techniques
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fmrm.29269
https://www.ncbi.nlm.nih.gov/pubmed/35481596
https://www.proquest.com/docview/2681640267
https://www.proquest.com/docview/2656756425
https://pubmed.ncbi.nlm.nih.gov/PMC9325422
Volume 88
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