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Review
. 2020 Sep 14:3:119.
doi: 10.1038/s41746-020-00323-1. eCollection 2020.

The future of digital health with federated learning

Nicola Rieke  1   2 Jonny Hancox  3 Wenqi Li  4 Fausto Milletarì  1 Holger R Roth  5 Shadi Albarqouni  2   6 Spyridon Bakas  7 Mathieu N Galtier  8 Bennett A Landman  9 Klaus Maier-Hein  10   11 Sébastien Ourselin  12 Micah Sheller  13 Ronald M Summers  14 Andrew Trask  15   16   17 Daguang Xu  5 Maximilian Baust  1 M Jorge Cardoso  12
Affiliations
Review

The future of digital health with federated learning

Nicola Rieke et al. NPJ Digit Med. .

Abstract

Data-driven machine learning (ML) has emerged as a promising approach for building accurate and robust statistical models from medical data, which is collected in huge volumes by modern healthcare systems. Existing medical data is not fully exploited by ML primarily because it sits in data silos and privacy concerns restrict access to this data. However, without access to sufficient data, ML will be prevented from reaching its full potential and, ultimately, from making the transition from research to clinical practice. This paper considers key factors contributing to this issue, explores how federated learning (FL) may provide a solution for the future of digital health and highlights the challenges and considerations that need to be addressed.

Keywords: Medical imaging; Medical research.

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Conflict of interest statement

Competing interestsR.M.S. receives royalties from iCAD, ScanMed, Philips, Translation Holdings and Ping An. His lab has received research support from Ping An and NVIDIA. S.B. is supported by the National Institutes of Health (NIH). M.N.G. is supported by the HealthChain (BPIFrance) and Melloddy (IMI2) projects. A.T. is an employee of Google’s DeepMind. S.O. and M.J.C. are founders and shareholders of Brainminer, llc. The other authors declare no competing interests.

Figures

Fig. 1
Fig. 1. Example federated learning (FL) workflows and difference to learning on a Centralised Data Lake.
a FL aggregation server—the typical FL workflow in which a federation of training nodes receive the global model, resubmit their partially trained models to a central server intermittently for aggregation and then continue training on the consensus model that the server returns. b FL peer to peer—alternative formulation of FL in which each training node exchanges its partially trained models with some or all of its peers and each does its own aggregation. c Centralised training—the general non-FL training workflow in which data acquiring sites donate their data to a central Data Lake from which they and others are able to extract data for local, independent training.
Fig. 2
Fig. 2. Overview of different FL design choices.
FL topologies—communication architecture of a federation. a Centralised: the aggregation server coordinates the training iterations and collects, aggregates and distributes the models to and from the Training Nodes (Hub & Spoke). b Decentralised: each training node is connected to one or more peers and aggregation occurs on each node in parallel. c Hierarchical: federated networks can be composed from several sub-federations, which can be built from a mix of Peer to Peer and Aggregation Server federations (d)). FL compute plans—trajectory of a model across several partners. e Sequential training/cyclic transfer learning. f Aggregation server, g Peer to Peer.
See this image and copyright information in PMC

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