Explaining Clinical Decision Support Systems in Medical Imaging using Cycle-Consistent Activation Maximization

TL;DR

This paper introduces a novel CycleGAN activation maximization method to generate high-quality visual explanations for deep learning models in medical imaging, improving interpretability even with limited data.

Contribution

The paper presents a new decision explanation approach using CycleGAN activation maximization that enhances visualization quality in small datasets, aiding clinical understanding.

Findings

Outperformed existing explanation methods on medical imaging datasets

Ranked second in natural image recognition tasks

Improved interpretability of deep neural networks in clinical settings

Abstract

Clinical decision support using deep neural networks has become a topic of steadily growing interest. While recent work has repeatedly demonstrated that deep learning offers major advantages for medical image classification over traditional methods, clinicians are often hesitant to adopt the technology because its underlying decision-making process is considered to be intransparent and difficult to comprehend. In recent years, this has been addressed by a variety of approaches that have successfully contributed to providing deeper insight. Most notably, additive feature attribution methods are able to propagate decisions back into the input space by creating a saliency map which allows the practitioner to "see what the network sees." However, the quality of the generated maps can become poor and the images noisy if only limited data is available - a typical scenario in clinical contexts. We propose a novel decision explanation scheme based on CycleGAN activation maximization which generates high-quality visualizations of classifier decisions even in smaller data sets. We conducted a user study in which we evaluated our method on the LIDC dataset for lung lesion malignancy classification, the BreastMNIST dataset for ultrasound image breast cancer detection, as well as two subsets of the CIFAR-10 dataset for RBG image object recognition. Within this user study, our method clearly outperformed existing approaches on the medical imaging datasets and ranked second in the natural image setting. With our approach we make a significant contribution towards a better understanding of clinical decision support systems based on deep neural networks and thus aim to foster overall clinical acceptance.