Simultaneous 3D aortic lumen and vessel wall imaging at 0.55 T at either systole or diastole

Purpose To evaluate the feasibility of a novel, non‐contrast enhanced, 3D, simultaneous bright‐blood, and black‐blood sequence (iT2prep‐BOOST) for aortic imaging at 0.55 T at either systole or diastole. Methods Simultaneous contrast‐free 3D aortic lumen and vessel wall imaging at 0.55 T is achieved...

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Published inMagnetic resonance in medicine Vol. 94; no. 5; pp. 1982 - 1996
Main Authors Paredes, Matias, Castillo‐Passi, Carlos, Kunze, Karl P., Fotaki, Anastasia, Littlewood, Simon, Botnar, René M., Prieto, Claudia
Format Journal Article
LanguageEnglish
Published United States Wiley Subscription Services, Inc 01.11.2025
Subjects
Adiabatic
Adiabatic flow
Adult
Algorithms
Aorta
Aorta - diagnostic imaging
aortic MRI
Blood
Blood vessels
bright and black blood
Cardiovascular diseases
Diameters
Diastole
Feasibility Studies
Female
free‐breathing
Humans
Image acquisition
Image Interpretation, Computer-Assisted - methods
Image Processing, Computer-Assisted - methods
Image quality
Imaging, Three-Dimensional - methods
low‐field
lumen
Magnetic Resonance Angiography - methods
Male
Medical imaging
Middle Aged
Myocardium
Phantoms, Imaging
Systole
systole and diastole
vessel wall
vessel wall
free‐breathing
lumen
aortic MRI
systole and diastole
low‐field
bright and black blood
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Abstract Purpose To evaluate the feasibility of a novel, non‐contrast enhanced, 3D, simultaneous bright‐blood, and black‐blood sequence (iT2prep‐BOOST) for aortic imaging at 0.55 T at either systole or diastole. Methods Simultaneous contrast‐free 3D aortic lumen and vessel wall imaging at 0.55 T is achieved using the recently introduced iT2prep‐BOOST framework that interleaves the acquisition of two bright blood images (with inversion recovery T2 preparation [T2prep‐IR] and no preparation). To enable either systolic or diastolic aortic imaging, three T2 preparation pulses were investigated—an adiabatic RF pulse and two Malcolm‐Levitt (MLEV) pulses (MLEV4 and MLEV8)—to improve image quality in regions with high flow and susceptibility. The proposed approach was evaluated in phantom, 10 healthy subjects and 3 patients with suspected cardiovascular disease. Bright‐ and black‐blood images resulting from the three different T2 preparation pulses were compared both qualitatively and quantitatively, using a 4‐point Likert scale for vessel sharpness and presence of blood artifacts. Additionally, the contrast ratio between the lumen and myocardium was computed. Aortic measurements, including the aortic annulus area at systole and diastole, cusp‐commissure measurement at the aortic root level during diastole, and aortic diameter at the ascending aortic level during diastole were also performed. Results Excellent or good image quality scores were obtained for both bright‐ and black‐blood images with iT2prep‐BOOST at 0.55 T with all three preparation pulses. The use of MLEV8 T2 preparation scheme improves systolic image quality, reducing the presence of artifacts with a significant difference (p < 0.05) at the mid descending aorta level. This scheme also increases the contrast ratio between aortic lumen and myocardium, compared to the previously used adiabatic RF T2 preparation. The aortic root diameter and area were consistent with values reported in the literature for healthy subjects at 1.5 T. Conclusion The feasibility of a novel, non‐contrast‐enhanced, 3D aortic imaging framework for simultaneous bright‐blood and black‐blood imaging was demonstrated at 0.55 T for either systole or diastole, with a scan time of 7 min. Good image quality scores and aortic measurements in agreement with literature values at 1.5 T were achieved with the MLEV8 T2 preparation. Studies in a larger cohort of healthy subjects and patients with aortopathies are warranted.
AbstractList To evaluate the feasibility of a novel, non-contrast enhanced, 3D, simultaneous bright-blood, and black-blood sequence (iT2prep-BOOST) for aortic imaging at 0.55 T at either systole or diastole.PURPOSETo evaluate the feasibility of a novel, non-contrast enhanced, 3D, simultaneous bright-blood, and black-blood sequence (iT2prep-BOOST) for aortic imaging at 0.55 T at either systole or diastole.Simultaneous contrast-free 3D aortic lumen and vessel wall imaging at 0.55 T is achieved using the recently introduced iT2prep-BOOST framework that interleaves the acquisition of two bright blood images (with inversion recovery T2 preparation [T2prep-IR] and no preparation). To enable either systolic or diastolic aortic imaging, three T2 preparation pulses were investigated-an adiabatic RF pulse and two Malcolm-Levitt (MLEV) pulses (MLEV4 and MLEV8)-to improve image quality in regions with high flow and susceptibility. The proposed approach was evaluated in phantom, 10 healthy subjects and 3 patients with suspected cardiovascular disease. Bright- and black-blood images resulting from the three different T2 preparation pulses were compared both qualitatively and quantitatively, using a 4-point Likert scale for vessel sharpness and presence of blood artifacts. Additionally, the contrast ratio between the lumen and myocardium was computed. Aortic measurements, including the aortic annulus area at systole and diastole, cusp-commissure measurement at the aortic root level during diastole, and aortic diameter at the ascending aortic level during diastole were also performed.METHODSSimultaneous contrast-free 3D aortic lumen and vessel wall imaging at 0.55 T is achieved using the recently introduced iT2prep-BOOST framework that interleaves the acquisition of two bright blood images (with inversion recovery T2 preparation [T2prep-IR] and no preparation). To enable either systolic or diastolic aortic imaging, three T2 preparation pulses were investigated-an adiabatic RF pulse and two Malcolm-Levitt (MLEV) pulses (MLEV4 and MLEV8)-to improve image quality in regions with high flow and susceptibility. The proposed approach was evaluated in phantom, 10 healthy subjects and 3 patients with suspected cardiovascular disease. Bright- and black-blood images resulting from the three different T2 preparation pulses were compared both qualitatively and quantitatively, using a 4-point Likert scale for vessel sharpness and presence of blood artifacts. Additionally, the contrast ratio between the lumen and myocardium was computed. Aortic measurements, including the aortic annulus area at systole and diastole, cusp-commissure measurement at the aortic root level during diastole, and aortic diameter at the ascending aortic level during diastole were also performed.Excellent or good image quality scores were obtained for both bright- and black-blood images with iT2prep-BOOST at 0.55 T with all three preparation pulses. The use of MLEV8 T2 preparation scheme improves systolic image quality, reducing the presence of artifacts with a significant difference (p < 0.05) at the mid descending aorta level. This scheme also increases the contrast ratio between aortic lumen and myocardium, compared to the previously used adiabatic RF T2 preparation. The aortic root diameter and area were consistent with values reported in the literature for healthy subjects at 1.5 T.RESULTSExcellent or good image quality scores were obtained for both bright- and black-blood images with iT2prep-BOOST at 0.55 T with all three preparation pulses. The use of MLEV8 T2 preparation scheme improves systolic image quality, reducing the presence of artifacts with a significant difference (p < 0.05) at the mid descending aorta level. This scheme also increases the contrast ratio between aortic lumen and myocardium, compared to the previously used adiabatic RF T2 preparation. The aortic root diameter and area were consistent with values reported in the literature for healthy subjects at 1.5 T.The feasibility of a novel, non-contrast-enhanced, 3D aortic imaging framework for simultaneous bright-blood and black-blood imaging was demonstrated at 0.55 T for either systole or diastole, with a scan time of 7 min. Good image quality scores and aortic measurements in agreement with literature values at 1.5 T were achieved with the MLEV8 T2 preparation. Studies in a larger cohort of healthy subjects and patients with aortopathies are warranted.CONCLUSIONThe feasibility of a novel, non-contrast-enhanced, 3D aortic imaging framework for simultaneous bright-blood and black-blood imaging was demonstrated at 0.55 T for either systole or diastole, with a scan time of 7 min. Good image quality scores and aortic measurements in agreement with literature values at 1.5 T were achieved with the MLEV8 T2 preparation. Studies in a larger cohort of healthy subjects and patients with aortopathies are warranted.
To evaluate the feasibility of a novel, non-contrast enhanced, 3D, simultaneous bright-blood, and black-blood sequence (iT2prep-BOOST) for aortic imaging at 0.55 T at either systole or diastole. Simultaneous contrast-free 3D aortic lumen and vessel wall imaging at 0.55 T is achieved using the recently introduced iT2prep-BOOST framework that interleaves the acquisition of two bright blood images (with inversion recovery T preparation [T2prep-IR] and no preparation). To enable either systolic or diastolic aortic imaging, three T preparation pulses were investigated-an adiabatic RF pulse and two Malcolm-Levitt (MLEV) pulses (MLEV4 and MLEV8)-to improve image quality in regions with high flow and susceptibility. The proposed approach was evaluated in phantom, 10 healthy subjects and 3 patients with suspected cardiovascular disease. Bright- and black-blood images resulting from the three different T preparation pulses were compared both qualitatively and quantitatively, using a 4-point Likert scale for vessel sharpness and presence of blood artifacts. Additionally, the contrast ratio between the lumen and myocardium was computed. Aortic measurements, including the aortic annulus area at systole and diastole, cusp-commissure measurement at the aortic root level during diastole, and aortic diameter at the ascending aortic level during diastole were also performed. Excellent or good image quality scores were obtained for both bright- and black-blood images with iT2prep-BOOST at 0.55 T with all three preparation pulses. The use of MLEV8 T preparation scheme improves systolic image quality, reducing the presence of artifacts with a significant difference (p < 0.05) at the mid descending aorta level. This scheme also increases the contrast ratio between aortic lumen and myocardium, compared to the previously used adiabatic RF T preparation. The aortic root diameter and area were consistent with values reported in the literature for healthy subjects at 1.5 T. The feasibility of a novel, non-contrast-enhanced, 3D aortic imaging framework for simultaneous bright-blood and black-blood imaging was demonstrated at 0.55 T for either systole or diastole, with a scan time of 7 min. Good image quality scores and aortic measurements in agreement with literature values at 1.5 T were achieved with the MLEV8 T preparation. Studies in a larger cohort of healthy subjects and patients with aortopathies are warranted.
Purpose To evaluate the feasibility of a novel, non‐contrast enhanced, 3D, simultaneous bright‐blood, and black‐blood sequence (iT2prep‐BOOST) for aortic imaging at 0.55 T at either systole or diastole. Methods Simultaneous contrast‐free 3D aortic lumen and vessel wall imaging at 0.55 T is achieved using the recently introduced iT2prep‐BOOST framework that interleaves the acquisition of two bright blood images (with inversion recovery T2 preparation [T2prep‐IR] and no preparation). To enable either systolic or diastolic aortic imaging, three T2 preparation pulses were investigated—an adiabatic RF pulse and two Malcolm‐Levitt (MLEV) pulses (MLEV4 and MLEV8)—to improve image quality in regions with high flow and susceptibility. The proposed approach was evaluated in phantom, 10 healthy subjects and 3 patients with suspected cardiovascular disease. Bright‐ and black‐blood images resulting from the three different T2 preparation pulses were compared both qualitatively and quantitatively, using a 4‐point Likert scale for vessel sharpness and presence of blood artifacts. Additionally, the contrast ratio between the lumen and myocardium was computed. Aortic measurements, including the aortic annulus area at systole and diastole, cusp‐commissure measurement at the aortic root level during diastole, and aortic diameter at the ascending aortic level during diastole were also performed. Results Excellent or good image quality scores were obtained for both bright‐ and black‐blood images with iT2prep‐BOOST at 0.55 T with all three preparation pulses. The use of MLEV8 T2 preparation scheme improves systolic image quality, reducing the presence of artifacts with a significant difference (p < 0.05) at the mid descending aorta level. This scheme also increases the contrast ratio between aortic lumen and myocardium, compared to the previously used adiabatic RF T2 preparation. The aortic root diameter and area were consistent with values reported in the literature for healthy subjects at 1.5 T. Conclusion The feasibility of a novel, non‐contrast‐enhanced, 3D aortic imaging framework for simultaneous bright‐blood and black‐blood imaging was demonstrated at 0.55 T for either systole or diastole, with a scan time of 7 min. Good image quality scores and aortic measurements in agreement with literature values at 1.5 T were achieved with the MLEV8 T2 preparation. Studies in a larger cohort of healthy subjects and patients with aortopathies are warranted.
Purpose To evaluate the feasibility of a novel, non‐contrast enhanced, 3D, simultaneous bright‐blood, and black‐blood sequence (iT2prep‐BOOST) for aortic imaging at 0.55 T at either systole or diastole. Methods Simultaneous contrast‐free 3D aortic lumen and vessel wall imaging at 0.55 T is achieved using the recently introduced iT2prep‐BOOST framework that interleaves the acquisition of two bright blood images (with inversion recovery T2 preparation [T2prep‐IR] and no preparation). To enable either systolic or diastolic aortic imaging, three T2 preparation pulses were investigated—an adiabatic RF pulse and two Malcolm‐Levitt (MLEV) pulses (MLEV4 and MLEV8)—to improve image quality in regions with high flow and susceptibility. The proposed approach was evaluated in phantom, 10 healthy subjects and 3 patients with suspected cardiovascular disease. Bright‐ and black‐blood images resulting from the three different T2 preparation pulses were compared both qualitatively and quantitatively, using a 4‐point Likert scale for vessel sharpness and presence of blood artifacts. Additionally, the contrast ratio between the lumen and myocardium was computed. Aortic measurements, including the aortic annulus area at systole and diastole, cusp‐commissure measurement at the aortic root level during diastole, and aortic diameter at the ascending aortic level during diastole were also performed. Results Excellent or good image quality scores were obtained for both bright‐ and black‐blood images with iT2prep‐BOOST at 0.55 T with all three preparation pulses. The use of MLEV8 T2 preparation scheme improves systolic image quality, reducing the presence of artifacts with a significant difference (p < 0.05) at the mid descending aorta level. This scheme also increases the contrast ratio between aortic lumen and myocardium, compared to the previously used adiabatic RF T2 preparation. The aortic root diameter and area were consistent with values reported in the literature for healthy subjects at 1.5 T. Conclusion The feasibility of a novel, non‐contrast‐enhanced, 3D aortic imaging framework for simultaneous bright‐blood and black‐blood imaging was demonstrated at 0.55 T for either systole or diastole, with a scan time of 7 min. Good image quality scores and aortic measurements in agreement with literature values at 1.5 T were achieved with the MLEV8 T2 preparation. Studies in a larger cohort of healthy subjects and patients with aortopathies are warranted.
Author Botnar, René M.
Fotaki, Anastasia
Prieto, Claudia
Paredes, Matias
Kunze, Karl P.
Littlewood, Simon
Castillo‐Passi, Carlos
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Keywords vessel wall
free‐breathing
lumen
aortic MRI
systole and diastole
low‐field
bright and black blood
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Snippet Purpose To evaluate the feasibility of a novel, non‐contrast enhanced, 3D, simultaneous bright‐blood, and black‐blood sequence (iT2prep‐BOOST) for aortic...
To evaluate the feasibility of a novel, non-contrast enhanced, 3D, simultaneous bright-blood, and black-blood sequence (iT2prep-BOOST) for aortic imaging at...
Purpose To evaluate the feasibility of a novel, non‐contrast enhanced, 3D, simultaneous bright‐blood, and black‐blood sequence (iT2prep‐BOOST) for aortic...
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pubmed
wiley
SourceType Aggregation Database
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Publisher
StartPage 1982
SubjectTerms Adiabatic
Adiabatic flow
Adult
Algorithms
Aorta
Aorta - diagnostic imaging
aortic MRI
Blood
Blood vessels
bright and black blood
Cardiovascular diseases
Diameters
Diastole
Feasibility Studies
Female
free‐breathing
Humans
Image acquisition
Image Interpretation, Computer-Assisted - methods
Image Processing, Computer-Assisted - methods
Image quality
Imaging, Three-Dimensional - methods
low‐field
lumen
Magnetic Resonance Angiography - methods
Male
Medical imaging
Middle Aged
Myocardium
Phantoms, Imaging
Systole
systole and diastole
vessel wall
Title Simultaneous 3D aortic lumen and vessel wall imaging at 0.55 T at either systole or diastole
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fmrm.30611
https://www.ncbi.nlm.nih.gov/pubmed/40548843
https://www.proquest.com/docview/3244515377
https://www.proquest.com/docview/3223633427
Volume 94
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