Steerable Pyramid Transform Enables Robust Left Ventricle Quantification

TL;DR

This paper introduces a steerable pyramid transform-based method for robust left ventricle quantification in cardiac imaging, improving resistance to input perturbations while maintaining accuracy.

Contribution

The study presents a novel use of the biologically inspired steerable pyramid transform for enhancing robustness in cardiac index prediction models.

Findings

Achieves comparable accuracy to state-of-the-art methods.

Significantly improves robustness against input perturbations.

Demonstrates effectiveness on the Cardiac-Dig benchmark.

Abstract

Predicting cardiac indices has long been a focal point in the medical imaging community. While various deep learning models have demonstrated success in quantifying cardiac indices, they remain susceptible to mild input perturbations, e.g., spatial transformations, image distortions, and adversarial attacks. This vulnerability undermines confidence in using learning-based automated systems for diagnosing cardiovascular diseases. In this work, we describe a simple yet effective method to learn robust models for left ventricle (LV) quantification, encompassing cavity and myocardium areas, directional dimensions, and regional wall thicknesses. Our success hinges on employing the biologically inspired steerable pyramid transform (SPT) for fixed front-end processing, which offers three main benefits. First, the basis functions of SPT align with the anatomical structure of LV and the geometric features of the measured indices. Second, SPT facilitates weight sharing across different orientations as a form of parameter regularization and naturally captures the scale variations of LV. Third, the residual highpass subband can be conveniently discarded, promoting robust feature learning. Extensive experiments on the Cardiac-Dig benchmark show that our SPT-augmented model not only achieves reasonable prediction accuracy compared to state-of-the-art methods, but also exhibits significantly improved robustness against input perturbations.