Dis-AE: Multi-domain & Multi-task Generalisation on Real-World Clinical Data
Abstract
Clinical data is often affected by clinically irrelevant factors such as discrepancies between measurement devices or differing processing methods between sites. In the field of machine learning (ML), these factors are known as domains and the distribution differences they cause in the data are known as domain shifts. ML models trained using data from one domain often perform poorly when applied to data from another domain, potentially leading to wrong predictions. As such, developing machine learning models that can generalise well across multiple domains is a challenging yet essential task in the successful application of ML in clinical practice. In this paper, we propose a novel disentangled autoencoder (Dis-AE) neural network architecture that can learn domain-invariant data representations for multi-label classification of medical measurements even when the data is influenced by multiple interacting domain shifts at once. The model utilises adversarial training to produce data representations from which the domain can no longer be determined. We evaluate the model's domain generalisation capabilities on synthetic datasets and full blood count (FBC) data from blood donors as well as primary and secondary care patients, showing that Dis-AE improves model generalisation on multiple domains simultaneously while preserving clinically relevant information.
Cite
@article{arxiv.2306.09177,
title = {Dis-AE: Multi-domain & Multi-task Generalisation on Real-World Clinical Data},
author = {Daniel Kreuter and Samuel Tull and Julian Gilbey and Jacobus Preller and BloodCounts! Consortium and John A. D. Aston and James H. F. Rudd and Suthesh Sivapalaratnam and Carola-Bibiane Schönlieb and Nicholas Gleadall and Michael Roberts},
journal= {arXiv preprint arXiv:2306.09177},
year = {2023}
}
Comments
17 pages main body, 5 figures, 18 pages of appendix