Porous medium 3D flow simulation of contrast media washout in cardiac MRI reflects myocardial injury

Item Type:	Article
Title:	Porous medium 3D flow simulation of contrast media washout in cardiac MRI reflects myocardial injury
Creators Name:	Riazy, L. and Schaeffter, T. and Olbrich, M. and Schueler, J. and von Knobelsdorff-Brenkenhoff, F. and Niendorf, T. and Schulz-Menger, J.
Abstract:	PURPOSE: Myocardial blood-flow simulation based on laws of fluid mechanics is a valuable tool for understanding tissue behavior. Our aim is to evaluate the ability of a porous-media flow model approach to reflect disturbed washout of contrast media (CM) from the myocardium as observed by cardiovascular MR. METHODS: A coupled advection-diffusion model is used to describe the CM flow in the vascular and extravascular space as separate compartments. Their exchange of CM is controlled by the exchange rate ExR , which in turn determines the washout behavior. We fitted simulations to CM concentration measurements, derived from T(1) maps of the midventricular slice. The CM concentration was extracted from 18 patients with myocarditis in the acute phase and during follow-up after 6 months. The results were compared with 18 sex- and age-matched controls. For each subject, the measurements were acquired before and during the first 10 minutes at 5 time points after CM administration, representing CM washout. Image registration was applied to compensate for motion between different time points. RESULTS: Eight matched data sets had to be excluded due to low registration quality. Processing was successful in n = 10 matched data sets of acute and healed myocarditis as well as controls. Significant differences in ExR were observed when comparing patients with acute myocarditis to controls (P < .001), to their follow-up (P < .05), and the follow-up to controls (P < .05). CONCLUSION: Our study suggests the feasibility of using the proposed porous-medium flow framework for the simulation of pathologic myocardial tissue.
Keywords:	Contrast Medium Kinetics, Fibrosis, Flow Simulation, Late Gadolinium Enhancement, Magnetic Resonance Imaging
Source:	Magnetic Resonance in Medicine
ISSN:	0740-3194
Publisher:	Wiley
Volume:	82
Number:	2
Page Range:	775-785
Date:	August 2019
Official Publication:	https://doi.org/10.1002/mrm.27756
PubMed:	View item in PubMed

Repository Staff Only: item control page