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. 2021 Jun;16(6):2765-2787.
doi: 10.1038/s41596-021-00513-5. Epub 2021 May 5.

Use of deep learning to develop continuous-risk models for adverse event prediction from electronic health records

Nenad Tomašev  1 Natalie Harris  2 Sebastien Baur  2 Anne Mottram  3 Xavier Glorot  3 Jack W Rae  3   4 Michal Zielinski  3 Harry Askham  3 Andre Saraiva  3 Valerio Magliulo  2 Clemens Meyer  3 Suman Ravuri  3 Ivan Protsyuk  2 Alistair Connell  2 Cían O Hughes  2 Alan Karthikesalingam  2 Julien Cornebise  3   5 Hugh Montgomery  6 Geraint Rees  7 Chris Laing  8 Clifton R Baker  9 Thomas F Osborne  10   11 Ruth Reeves  9 Demis Hassabis  3 Dominic King  2 Mustafa Suleyman  3 Trevor Back  3 Christopher Nielson #  9   12 Martin G Seneviratne #  13 Joseph R Ledsam #  14   15   16 Shakir Mohamed #  3
Affiliations

Use of deep learning to develop continuous-risk models for adverse event prediction from electronic health records

Nenad Tomašev et al. Nat Protoc. 2021 Jun.

Abstract

Early prediction of patient outcomes is important for targeting preventive care. This protocol describes a practical workflow for developing deep-learning risk models that can predict various clinical and operational outcomes from structured electronic health record (EHR) data. The protocol comprises five main stages: formal problem definition, data pre-processing, architecture selection, calibration and uncertainty, and generalizability evaluation. We have applied the workflow to four endpoints (acute kidney injury, mortality, length of stay and 30-day hospital readmission). The workflow can enable continuous (e.g., triggered every 6 h) and static (e.g., triggered at 24 h after admission) predictions. We also provide an open-source codebase that illustrates some key principles in EHR modeling. This protocol can be used by interdisciplinary teams with programming and clinical expertise to build deep-learning prediction models with alternate data sources and prediction tasks.

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