Literature DB >> 32308851

Interpretation of machine learning predictions for patient outcomes in electronic health records.

William La Cava1, Christopher Bauer2, Jason H Moore1, Sarah A Pendergrass2.   

Abstract

Electronic health records are an increasingly important resource for understanding the interactions between patient health, environment, and clinical decisions. In this paper we report an empirical study of predictive modeling of seven patient outcomes using three state-of-the-art machine learning methods. Our primary goal is to validate the models by interpreting the importance of predictors in the final models. Central to interpretation is the use of feature importance scores, which vary depending on the underlying methodology. In order to assess feature importance, we compared univariate statistical tests, information-theoretic measures, permutation testing, and normalized coefficients from multivariate logistic regression models. In general we found poor correlation between methods in their assessment of feature importance, even when their performance is comparable and relatively good. However, permutation tests applied to random forest and gradient boosting models showed the most agreement, and the importance scores matched the clinical interpretation most frequently. ©2019 AMIA - All rights reserved.

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Year:  2020        PMID: 32308851      PMCID: PMC7153071     

Source DB:  PubMed          Journal:  AMIA Annu Symp Proc        ISSN: 1559-4076


  17 in total

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4.  Semi-supervised learning of the electronic health record for phenotype stratification.

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Review 5.  Deep EHR: A Survey of Recent Advances in Deep Learning Techniques for Electronic Health Record (EHR) Analysis.

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6.  Spectral Regularization Algorithms for Learning Large Incomplete Matrices.

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Review 8.  Relief-based feature selection: Introduction and review.

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Authors:  Riccardo Miotto; Li Li; Brian A Kidd; Joel T Dudley
Journal:  Sci Rep       Date:  2016-05-17       Impact factor: 4.379

10.  Scalable and accurate deep learning with electronic health records.

Authors:  Alvin Rajkomar; Eyal Oren; Kai Chen; Andrew M Dai; Nissan Hajaj; Michaela Hardt; Peter J Liu; Xiaobing Liu; Jake Marcus; Mimi Sun; Patrik Sundberg; Hector Yee; Kun Zhang; Yi Zhang; Gerardo Flores; Gavin E Duggan; Jamie Irvine; Quoc Le; Kurt Litsch; Alexander Mossin; Justin Tansuwan; James Wexler; Jimbo Wilson; Dana Ludwig; Samuel L Volchenboum; Katherine Chou; Michael Pearson; Srinivasan Madabushi; Nigam H Shah; Atul J Butte; Michael D Howell; Claire Cui; Greg S Corrado; Jeffrey Dean
Journal:  NPJ Digit Med       Date:  2018-05-08
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Review 5.  Contribution of Synthetic Data Generation towards an Improved Patient Stratification in Palliative Care.

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7.  Post-Analysis of Predictive Modeling with an Epidemiological Example.

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Journal:  Healthcare (Basel)       Date:  2021-06-24

8.  Extracting New Temporal Features to Improve the Interpretability of Undiagnosed Type 2 Diabetes Mellitus Prediction Models.

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  8 in total

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