Dual‐excitation flip‐angle simultaneous cine and T1 mapping using spiral acquisition with respiratory and cardiac self‐gating

Purpose To develop a free‐breathing cardiac self‐gated technique that provides cine images and B1+ slice profile–corrected T1 maps from a single acquisition. Methods Without breath‐holding or electrocardiogram gating, data were acquired continuously on a 3T scanner using a golden‐angle gradient‐echo...

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Published in	Magnetic resonance in medicine Vol. 86; no. 1; pp. 82 - 96
Main Authors	Zhou, Ruixi, Weller, Daniel S., Yang, Yang, Wang, Junyu, Jeelani, Haris, Mugler, John P., Salerno, Michael
Format	Journal Article
Language	English
Published	Hoboken Wiley Subscription Services, Inc 01.07.2021
Subjects	cardiac MRI cine Convexity Data acquisition dictionary learning EKG Electrocardiography Excitation Gating Heart Human subjects Image acquisition Image quality Image reconstruction Inversions Mapping Navigators self‐gating Signal quality spiral trajectory T1 mapping
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ISSN	0740-3194 1522-2594 1522-2594
DOI	10.1002/mrm.28675

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Abstract	Purpose To develop a free‐breathing cardiac self‐gated technique that provides cine images and B1+ slice profile–corrected T1 maps from a single acquisition. Methods Without breath‐holding or electrocardiogram gating, data were acquired continuously on a 3T scanner using a golden‐angle gradient‐echo spiral pulse sequence, with an inversion RF pulse applied every 4 seconds. Flip angles of 3° and 15° were used for readouts after the first four and second four inversions. Self‐gating cardiac triggers were extracted from heart image navigators, and respiratory motion was corrected by rigid registration on each heartbeat. Cine images were reconstructed from the steady‐state portion of 15° readouts using a low‐rank plus sparse reconstruction. The T1 maps were fit using a projection onto convex sets approach from images reconstructed using slice profile–corrected dictionary learning. This strategy was evaluated in a phantom and 14 human subjects. Results The self‐gated signal demonstrated close agreement with the acquired electrocardiogram signal. The image quality for the proposed cine images and standard clinical balanced SSFP images were 4.31 (±0.50) and 4.65 (±0.30), respectively. The slice profile–corrected T1 values were similar to those of the inversion‐recovery spin‐echo technique in phantom, and had a higher global T1 value than that of MOLLI in human subjects. Conclusions Cine and T1 mapping using spiral acquisition with respiratory and cardiac self‐gating successfully acquired T1 maps and cine images in a single acquisition without the need for electrocardiogram gating or breath‐holding. This dual‐excitation flip‐angle approach provides a novel approach for measuring T1 while accounting for B1+ and slice profile effect on the apparent T1∗.
AbstractList	PurposeTo develop a free‐breathing cardiac self‐gated technique that provides cine images and B1+ slice profile–corrected T1 maps from a single acquisition.MethodsWithout breath‐holding or electrocardiogram gating, data were acquired continuously on a 3T scanner using a golden‐angle gradient‐echo spiral pulse sequence, with an inversion RF pulse applied every 4 seconds. Flip angles of 3° and 15° were used for readouts after the first four and second four inversions. Self‐gating cardiac triggers were extracted from heart image navigators, and respiratory motion was corrected by rigid registration on each heartbeat. Cine images were reconstructed from the steady‐state portion of 15° readouts using a low‐rank plus sparse reconstruction. The T1 maps were fit using a projection onto convex sets approach from images reconstructed using slice profile–corrected dictionary learning. This strategy was evaluated in a phantom and 14 human subjects.ResultsThe self‐gated signal demonstrated close agreement with the acquired electrocardiogram signal. The image quality for the proposed cine images and standard clinical balanced SSFP images were 4.31 (±0.50) and 4.65 (±0.30), respectively. The slice profile–corrected T1 values were similar to those of the inversion‐recovery spin‐echo technique in phantom, and had a higher global T1 value than that of MOLLI in human subjects.ConclusionsCine and T1 mapping using spiral acquisition with respiratory and cardiac self‐gating successfully acquired T1 maps and cine images in a single acquisition without the need for electrocardiogram gating or breath‐holding. This dual‐excitation flip‐angle approach provides a novel approach for measuring T1 while accounting for B1+ and slice profile effect on the apparent T1∗. Purpose To develop a free‐breathing cardiac self‐gated technique that provides cine images and B1+ slice profile–corrected T1 maps from a single acquisition. Methods Without breath‐holding or electrocardiogram gating, data were acquired continuously on a 3T scanner using a golden‐angle gradient‐echo spiral pulse sequence, with an inversion RF pulse applied every 4 seconds. Flip angles of 3° and 15° were used for readouts after the first four and second four inversions. Self‐gating cardiac triggers were extracted from heart image navigators, and respiratory motion was corrected by rigid registration on each heartbeat. Cine images were reconstructed from the steady‐state portion of 15° readouts using a low‐rank plus sparse reconstruction. The T1 maps were fit using a projection onto convex sets approach from images reconstructed using slice profile–corrected dictionary learning. This strategy was evaluated in a phantom and 14 human subjects. Results The self‐gated signal demonstrated close agreement with the acquired electrocardiogram signal. The image quality for the proposed cine images and standard clinical balanced SSFP images were 4.31 (±0.50) and 4.65 (±0.30), respectively. The slice profile–corrected T1 values were similar to those of the inversion‐recovery spin‐echo technique in phantom, and had a higher global T1 value than that of MOLLI in human subjects. Conclusions Cine and T1 mapping using spiral acquisition with respiratory and cardiac self‐gating successfully acquired T1 maps and cine images in a single acquisition without the need for electrocardiogram gating or breath‐holding. This dual‐excitation flip‐angle approach provides a novel approach for measuring T1 while accounting for B1+ and slice profile effect on the apparent T1∗. To develop a free-breathing cardiac self-gated technique that provides cine images and B1+ slice profile-corrected T1 maps from a single acquisition.PURPOSETo develop a free-breathing cardiac self-gated technique that provides cine images and B1+ slice profile-corrected T1 maps from a single acquisition.Without breath-holding or electrocardiogram gating, data were acquired continuously on a 3T scanner using a golden-angle gradient-echo spiral pulse sequence, with an inversion RF pulse applied every 4 seconds. Flip angles of 3° and 15° were used for readouts after the first four and second four inversions. Self-gating cardiac triggers were extracted from heart image navigators, and respiratory motion was corrected by rigid registration on each heartbeat. Cine images were reconstructed from the steady-state portion of 15° readouts using a low-rank plus sparse reconstruction. The T1 maps were fit using a projection onto convex sets approach from images reconstructed using slice profile-corrected dictionary learning. This strategy was evaluated in a phantom and 14 human subjects.METHODSWithout breath-holding or electrocardiogram gating, data were acquired continuously on a 3T scanner using a golden-angle gradient-echo spiral pulse sequence, with an inversion RF pulse applied every 4 seconds. Flip angles of 3° and 15° were used for readouts after the first four and second four inversions. Self-gating cardiac triggers were extracted from heart image navigators, and respiratory motion was corrected by rigid registration on each heartbeat. Cine images were reconstructed from the steady-state portion of 15° readouts using a low-rank plus sparse reconstruction. The T1 maps were fit using a projection onto convex sets approach from images reconstructed using slice profile-corrected dictionary learning. This strategy was evaluated in a phantom and 14 human subjects.The self-gated signal demonstrated close agreement with the acquired electrocardiogram signal. The image quality for the proposed cine images and standard clinical balanced SSFP images were 4.31 (±0.50) and 4.65 (±0.30), respectively. The slice profile-corrected T1 values were similar to those of the inversion-recovery spin-echo technique in phantom, and had a higher global T1 value than that of MOLLI in human subjects.RESULTSThe self-gated signal demonstrated close agreement with the acquired electrocardiogram signal. The image quality for the proposed cine images and standard clinical balanced SSFP images were 4.31 (±0.50) and 4.65 (±0.30), respectively. The slice profile-corrected T1 values were similar to those of the inversion-recovery spin-echo technique in phantom, and had a higher global T1 value than that of MOLLI in human subjects.Cine and T1 mapping using spiral acquisition with respiratory and cardiac self-gating successfully acquired T1 maps and cine images in a single acquisition without the need for electrocardiogram gating or breath-holding. This dual-excitation flip-angle approach provides a novel approach for measuring T1 while accounting for B1+ and slice profile effect on the apparent T1∗ .CONCLUSIONSCine and T1 mapping using spiral acquisition with respiratory and cardiac self-gating successfully acquired T1 maps and cine images in a single acquisition without the need for electrocardiogram gating or breath-holding. This dual-excitation flip-angle approach provides a novel approach for measuring T1 while accounting for B1+ and slice profile effect on the apparent T1∗ .
Author	Weller, Daniel S. Zhou, Ruixi Mugler, John P. Salerno, Michael Wang, Junyu Yang, Yang Jeelani, Haris
AuthorAffiliation	1 Department of Biomedical Engineering, University of Virginia Health System, Charlottesville, VA, United States 3 Biomedical Engineering and Imaging Institute and Department of Radiology, Icahn School of Medicine at Mount Sinai, New York, NY, United States 2 Department of Electrical and Computer Engineering, University of Virginia, Charlottesville, VA, United States 5 Cardiology, Radiology & Medical Imaging, Biomedical Engineering, University of Virginia Health System, Charlottesville, VA, United States 4 Radiology & Medical Imaging, Biomedical Engineering, University of Virginia Health System, Charlottesville, VA, United States
AuthorAffiliation_xml	– name: 2 Department of Electrical and Computer Engineering, University of Virginia, Charlottesville, VA, United States – name: 3 Biomedical Engineering and Imaging Institute and Department of Radiology, Icahn School of Medicine at Mount Sinai, New York, NY, United States – name: 1 Department of Biomedical Engineering, University of Virginia Health System, Charlottesville, VA, United States – name: 5 Cardiology, Radiology & Medical Imaging, Biomedical Engineering, University of Virginia Health System, Charlottesville, VA, United States – name: 4 Radiology & Medical Imaging, Biomedical Engineering, University of Virginia Health System, Charlottesville, VA, United States
Author_xml	– sequence: 1 givenname: Ruixi orcidid: 0000-0001-9231-4987 surname: Zhou fullname: Zhou, Ruixi organization: University of Virginia Health System – sequence: 2 givenname: Daniel S. orcidid: 0000-0001-9818-7325 surname: Weller fullname: Weller, Daniel S. organization: University of Virginia – sequence: 3 givenname: Yang surname: Yang fullname: Yang, Yang organization: Icahn School of Medicine at Mount Sinai – sequence: 4 givenname: Junyu orcidid: 0000-0001-8314-4525 surname: Wang fullname: Wang, Junyu organization: University of Virginia Health System – sequence: 5 givenname: Haris surname: Jeelani fullname: Jeelani, Haris organization: Icahn School of Medicine at Mount Sinai – sequence: 6 givenname: John P. surname: Mugler fullname: Mugler, John P. organization: University of Virginia Health System – sequence: 7 givenname: Michael orcidid: 0000-0001-7051-1031 surname: Salerno fullname: Salerno, Michael email: ms5pc@virginia.edu organization: University of Virginia Health System
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Snippet	Purpose To develop a free‐breathing cardiac self‐gated technique that provides cine images and B1+ slice profile–corrected T1 maps from a single acquisition.... PurposeTo develop a free‐breathing cardiac self‐gated technique that provides cine images and B1+ slice profile–corrected T1 maps from a single... To develop a free-breathing cardiac self-gated technique that provides cine images and B1+ slice profile-corrected T1 maps from a single acquisition.PURPOSETo...
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SubjectTerms	cardiac MRI cine Convexity Data acquisition dictionary learning EKG Electrocardiography Excitation Gating Heart Human subjects Image acquisition Image quality Image reconstruction Inversions Mapping Navigators self‐gating Signal quality spiral trajectory T1 mapping
Title	Dual‐excitation flip‐angle simultaneous cine and T1 mapping using spiral acquisition with respiratory and cardiac self‐gating
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