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. 2023 Jun;57(6):1752-1763.
doi: 10.1002/jmri.28432. Epub 2022 Sep 23.

Hemodynamic Evaluation of Type B Aortic Dissection Using Compressed Sensing Accelerated 4D Flow MRI

Ozden Kilinc  1 Stanley Chu  1 Justin Baraboo  1   2 Elizabeth K Weiss  1   2 Joshua Engel  1 Anthony Maroun  1 Daniel Giese  3   4 Ning Jin  5 Kelvin Chow  1   6 Xiaoming Bi  6 Rachel Davids  6 Christopher Mehta  7 S Chris Malaisrie  7 Andrew Hoel  8 James Carr  1 Michael Markl  1   2 Bradley D Allen  1
Affiliations

Hemodynamic Evaluation of Type B Aortic Dissection Using Compressed Sensing Accelerated 4D Flow MRI

Ozden Kilinc et al. J Magn Reson Imaging. 2023 Jun.

Abstract

Background: 4D Flow MRI is a quantitative imaging technique to evaluate blood flow patterns; however, it is unclear how compressed sensing (CS) acceleration would impact aortic hemodynamic quantification in type B aortic dissection (TBAD).

Purpose: To investigate CS-accelerated 4D Flow MRI performance compared to GRAPP-accelerated 4D Flow MRI (GRAPPA) to evaluate aortic hemodynamics in TBAD.

Study type: Prospective.

Population: Twelve TBAD patients, two volunteers.

Field strength/sequence: 1.5T, 3D time-resolved cine phase-contrast gradient echo sequence.

Assessment: GRAPPA (acceleration factor [R] = 2) and two CS-accelerated (R = 7.7 [CS7.7] and 10.2 [CS10.2]) 4D Flow MRI scans were acquired twice for interscan reproducibility assessment. Voxelwise kinetic energy (KE), peak velocity (PV), forward flow (FF), reverse flow (RF), and stasis were calculated. Plane-based mid-lumen flows were quantified. Imaging times were recorded.

Tests: Repeated measures analysis of variance, Pearson correlation coefficients (r), intraclass correlation coefficients (ICC). P < 0.05 indicated statistical significance.

Results: The KE and FF in true lumen (TL) and PV in false lumen (FL) did not show difference among three acquisition types (P = 0.818, 0.065, 0.284 respectively). The PV and stasis in TL were higher, KE, FF, and RF in FL were lower, and stasis was higher in GRAPPA compared to CS7.7 and CS10.2. The RF was lower in GRAPPA compared to CS10.2. The correlation coefficients were strong in TL (r = [0.781-0.986]), and low to strong in FL (r = [0.347-0.948]). The ICC levels demonstrated moderate to excellent interscan reproducibility (0.732-0.989). The FF and net flow in mid-descending aorta TL were significantly different between CS7.7 and CS10.2.

Conclusion: CS-accelerated 4D Flow MRI has potential for clinical utilization with shorter scan times in TBAD. Our results suggest similar hemodynamic trends between acceleration types, but CS-acceleration impacts KE, FF, RF, and stasis more in FL.

Evidence level: 1 Technical Efficacy: Stage 2.

Keywords: 4D Flow; MRI; aorta; dissection; flow; hemodynamics.

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Figures

Figure 1:
Figure 1:
A) Represents postprocessing steps of the 4D Flow MRI data including processing of raw 4D Flow MR images on MATLAB and manual 3D segmentation of the true and false lumen B) True lumen peak velocity and kinetic energy and false lumen stasis and reverse flow maps in one subject with de novo type B aortic dissection and comparison of maps generated by MATLAB between conventional and compressed sensing accelerated 4D Flow MRI scans.
Figure 2:
Figure 2:
Boxplots represent the values for each parameter and the trend of their distribution among three acquisition types in true and false lumen. Statistically significant differences in pairwise comparisons are shown in the figure.
Figure 3:
Figure 3:
4D Flow MRI magnitude coronal and sagittal images for each acquisition type in one patient with de novo type B aortic dissection covering the lungs and thoracic descending aorta.
See this image and copyright information in PMC

Comment in

References

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