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. 2020 Oct;84(4):2231-2245.
doi: 10.1002/mrm.28269. Epub 2020 Apr 8.

Blood flow imaging by optimal matching of computational fluid dynamics to 4D-flow data

Johannes Töger  1   2 Matthew J Zahr  3   4 Nicolas Aristokleous  2 Karin Markenroth Bloch  5 Marcus Carlsson  2 Per-Olof Persson  3   6
Affiliations
Free article

Blood flow imaging by optimal matching of computational fluid dynamics to 4D-flow data

Johannes Töger et al. Magn Reson Med. 2020 Oct.
Free article

Abstract

Purpose: Three-dimensional, time-resolved blood flow measurement (4D-flow) is a powerful research and clinical tool, but improved resolution and scan times are needed. Therefore, this study aims to (1) present a postprocessing framework for optimization-driven simulation-based flow imaging, called 4D-flow High-resolution Imaging with a priori Knowledge Incorporating the Navier-Stokes equations and the discontinuous Galerkin method (4D-flow HIKING), (2) investigate the framework in synthetic tests, (3) perform phantom validation using laser particle imaging velocimetry, and (4) demonstrate the use of the framework in vivo.

Methods: An optimizing computational fluid dynamics solver including adjoint-based optimization was developed to fit computational fluid dynamics solutions to 4D-flow data. Synthetic tests were performed in 2D, and phantom validation was performed with pulsatile flow. Reference velocity data were acquired using particle imaging velocimetry, and 4D-flow data were acquired at 1.5 T. In vivo testing was performed on intracranial arteries in a healthy volunteer at 7 T, with 2D flow as the reference.

Results: Synthetic tests showed low error (0.4%-0.7%). Phantom validation showed improved agreement with laser particle imaging velocimetry compared with input 4D-flow in the horizontal (mean -0.05 vs -1.11 cm/s, P < .001; SD 1.86 vs 4.26 cm/s, P < .001) and vertical directions (mean 0.05 vs -0.04 cm/s, P = .29; SD 1.36 vs 3.95 cm/s, P < .001). In vivo data show a reduction in flow rate error from 14% to 3.5%.

Conclusions: Phantom and in vivo results from 4D-flow HIKING show promise for future applications with higher resolution, shorter scan times, and accurate quantification of physiological parameters.

Keywords: 4D-flow MRI; blood flow; computational fluid dynamics; simulation-based imaging.

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References

REFERENCES

    1. Bolger AF, Heiberg E, Karlsson M, et al. Transit of blood flow through the human left ventricle mapped by cardiovascular magnetic resonance. J Cardiovasc Magn Reson. 2007;9:741-747.
    1. Arvidsson PM, Kovács SJ, Töger J, et al. Vortex ring behavior provides the epigenetic blueprint for the human heart. Sci Rep. 2016;6:22021.
    1. Fredriksson AG, Svalbring E, Eriksson J, et al. 4D flow MRI can detect subtle right ventricular dysfunction in primary left ventricular disease. J Magn Reson Imaging. 2016;43:558-565.
    1. Sjöberg P, Heiberg E, Wingren P, et al. Decreased diastolic ventricular kinetic energy in young patients with Fontan circulation demonstrated by four-dimensional cardiac magnetic resonance imaging. Pediatr Cardiol. 2017;38:669-680.
    1. Calkoen EE, Westenberg JJ, Kroft LJ, et al. Characterization and quantification of dynamic eccentric regurgitation of the left atrioventricular valve after atrioventricular septal defect correction with 4D flow cardiovascular magnetic resonance and retrospective valve tracking. J Cardiovasc Magn Reson. 2012;17:1-9.

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