Robust and Efficient Medical Imaging with Self-Supervision
Abstract
Recent progress in Medical Artificial Intelligence (AI) has delivered systems that can reach clinical expert level performance. However, such systems tend to demonstrate sub-optimal "out-of-distribution" performance when evaluated in clinical settings different from the training environment. A common mitigation strategy is to develop separate systems for each clinical setting using site-specific data [1]. However, this quickly becomes impractical as medical data is time-consuming to acquire and expensive to annotate [2]. Thus, the problem of "data-efficient generalization" presents an ongoing difficulty for Medical AI development. Although progress in representation learning shows promise, their benefits have not been rigorously studied, specifically for out-of-distribution settings. To meet these challenges, we present REMEDIS, a unified representation learning strategy to improve robustness and data-efficiency of medical imaging AI. REMEDIS uses a generic combination of large-scale supervised transfer learning with self-supervised learning and requires little task-specific customization. We study a diverse range of medical imaging tasks and simulate three realistic application scenarios using retrospective data. REMEDIS exhibits significantly improved in-distribution performance with up to 11.5% relative improvement in diagnostic accuracy over a strong supervised baseline. More importantly, our strategy leads to strong data-efficient generalization of medical imaging AI, matching strong supervised baselines using between 1% to 33% of retraining data across tasks. These results suggest that REMEDIS can significantly accelerate the life-cycle of medical imaging AI development thereby presenting an important step forward for medical imaging AI to deliver broad impact.
Cite
@article{arxiv.2205.09723,
title = {Robust and Efficient Medical Imaging with Self-Supervision},
author = {Shekoofeh Azizi and Laura Culp and Jan Freyberg and Basil Mustafa and Sebastien Baur and Simon Kornblith and Ting Chen and Patricia MacWilliams and S. Sara Mahdavi and Ellery Wulczyn and Boris Babenko and Megan Wilson and Aaron Loh and Po-Hsuan Cameron Chen and Yuan Liu and Pinal Bavishi and Scott Mayer McKinney and Jim Winkens and Abhijit Guha Roy and Zach Beaver and Fiona Ryan and Justin Krogue and Mozziyar Etemadi and Umesh Telang and Yun Liu and Lily Peng and Greg S. Corrado and Dale R. Webster and David Fleet and Geoffrey Hinton and Neil Houlsby and Alan Karthikesalingam and Mohammad Norouzi and Vivek Natarajan},
journal= {arXiv preprint arXiv:2205.09723},
year = {2022}
}