A 4D continuous representation of myocardial velocity fields from tissue phase mapping magnetic resonance imaging.

Bård A Bendiksen,Lili Zhang,Ivar Sjaastad,Emil K S Espe,Gary Mcginley,Quan Jiang

doi:10.1371/journal.pone.0247826

Abstract

Myocardial velocities carry important diagnostic information in a range of cardiac diseases, and play an important role in diagnosing and grading left ventricular diastolic dysfunction. Tissue Phase Mapping (TPM) Magnetic Resonance Imaging (MRI) enables discrete sampling of the myocardium’s underlying smooth and continuous velocity field. This paper presents a post-processing framework for constructing a spatially and temporally smooth and continuous representation of the myocardium’s velocity field from TPM data. In the proposed scheme, the velocity field is represented through either linear or cubic B-spline basis functions. The framework facilitates both interpolation and noise reducing approximation. As a proof-of-concept, the framework was evaluated using artificially noisy (i.e., synthetic) velocity fields created by adding different levels of noise to an original TPM data. The framework’s ability to restore the original velocity field was investigated using Bland-Altman statistics. Moreover, we calculated myocardial material point trajectories through temporal integration of the original and synthetic fields. The effect of noise reduction on the calculated trajectories was investigated by assessing the distance between the start and end position of material points after one complete cardiac cycle (end point error). We found that the Bland-Altman limits of agreement between the original and the synthetic velocity fields were reduced after application of the framework. Furthermore, the integrated trajectories exhibited consistently lower end point error. These results suggest that the proposed method generates a realistic continuous representation of myocardial velocity fields from noisy and discrete TPM data. Linear B-splines resulted in narrower limits of agreement between the original and synthetic fields, compared to Cubic B-splines. The end point errors were also consistently lower for Linear B-splines than for cubic. Linear B-splines therefore appear to be more suitable for TPM data.

Highlights

Measures of regional myocardial function play a key role in pre-clinical studies that aim to identify and describe mechanisms driving heart failure development, and to discover efficient targets for therapy
limits of agreement (LoA) between original and synthetic field grew wider with increasing noise
The Bland-Altman analysis did not reveal any systematic bias between the original and the synthetic noisy fields. Both linear B-spline functions (LBS) and cubic B-spline functions (CBS) approximation resulted in narrower LoAs (Table 1)

Summary

Introduction

Measures of regional myocardial function play a key role in pre-clinical studies that aim to identify and describe mechanisms driving heart failure development, and to discover efficient targets for therapy. Myocardial velocities reflect myocardial function, and has been shown to carry important diagnostic information in a range of cardiac diseases [1,2,3] They play a important role in diagnosing and grading left ventricular diastolic dysfunction [4]. TPM data can serve as a basis for deriving several characteristics that describes cardiac mechanical function on a regional level; such as strain [6, 7], fiber shortening [8], strain rate [9, 10], and work [11] To derive these parameters, the velocity field must undergo either spatial differentiation (to get strain rate) or temporal integration (to get myocardial material point trajectories)

Methods

Results

Discussion

Conclusion