Explainable artificial intelligence model to predict acute critical illness from electronic health records

Lauritsen, Simon Meyer; Kristensen, Mads Ruben Burgdorff; Olsen, Mathias Vassard; Larsen, Morten Skaarup; Lauritsen, K. B.; Jørgensen, Marianne Johansson; Lange, Jeppe; Thiesson, Bo

doi:10.1038/s41467-020-17431-x

Cited by 257 publications

(149 citation statements)

References 45 publications

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“…For example, the AI systems trained on EHRs exhibit substantial predictive performance in relation to real‐time early clinical prediction; however, their clinical translation is difficult because they provide less insight into systems' complex decisions. Recently, an xAI system provided an early prediction model to facilitate clinical translations, which can simultaneously use EHR data to explain model decisions 71 . On the other hand, in multicenter clinical trials, xAI could also support safe communication on different levels, including the study of basic mechanisms, clinical translation, privacy and the data sharing system, and the decisions made by collaborators and managers.…”

Section: Methods and Resultsmentioning

confidence: 99%

Applying artificial intelligence in the microbiome for gastrointestinal diseases: A review

Zeng

Chen

2021

J of Gastro and Hepatol

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For a long time, gut bacteria have been recognized for their important roles in the occurrence and progression of gastrointestinal diseases like colorectal cancer, and the ever‐increasing amounts of microbiome data combined with other high‐quality clinical and imaging datasets are leading the study of gastrointestinal diseases into an era of biomedical big data. The “omics” technologies used for microbiome analysis continuously evolve, and the machine learning or artificial intelligence technologies are key to extract the relevant information from microbiome data. This review intends to provide a focused summary of recent research and applications of microbiome big data and to discuss the use of artificial intelligence to combat gastrointestinal diseases.

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Section: Methods and Resultsmentioning

confidence: 99%

Applying artificial intelligence in the microbiome for gastrointestinal diseases: A review

Zeng

Chen

2021

J of Gastro and Hepatol

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“…Other explainability algorithms are model-agnostic, meaning they can be applied to any type of model, regardless of its mathematical basis [ 51 ]. In the study by Lauritsen et al [ 52 ], an explainable EWS was developed based on a temporal convolutional network, using a separate module for explanations. These methodologies are promising, but their application to health care, including to EWS, has been limited.…”

Section: Discussionmentioning

confidence: 99%

Machine Learning–Based Early Warning Systems for Clinical Deterioration: Systematic Scoping Review

Muralitharan

Nelson

et al. 2021

J Med Internet Res

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Background Timely identification of patients at a high risk of clinical deterioration is key to prioritizing care, allocating resources effectively, and preventing adverse outcomes. Vital signs–based, aggregate-weighted early warning systems are commonly used to predict the risk of outcomes related to cardiorespiratory instability and sepsis, which are strong predictors of poor outcomes and mortality. Machine learning models, which can incorporate trends and capture relationships among parameters that aggregate-weighted models cannot, have recently been showing promising results. Objective This study aimed to identify, summarize, and evaluate the available research, current state of utility, and challenges with machine learning–based early warning systems using vital signs to predict the risk of physiological deterioration in acutely ill patients, across acute and ambulatory care settings. Methods PubMed, CINAHL, Cochrane Library, Web of Science, Embase, and Google Scholar were searched for peer-reviewed, original studies with keywords related to “vital signs,” “clinical deterioration,” and “machine learning.” Included studies used patient vital signs along with demographics and described a machine learning model for predicting an outcome in acute and ambulatory care settings. Data were extracted following PRISMA, TRIPOD, and Cochrane Collaboration guidelines. Results We identified 24 peer-reviewed studies from 417 articles for inclusion; 23 studies were retrospective, while 1 was prospective in nature. Care settings included general wards, intensive care units, emergency departments, step-down units, medical assessment units, postanesthetic wards, and home care. Machine learning models including logistic regression, tree-based methods, kernel-based methods, and neural networks were most commonly used to predict the risk of deterioration. The area under the curve for models ranged from 0.57 to 0.97. Conclusions In studies that compared performance, reported results suggest that machine learning–based early warning systems can achieve greater accuracy than aggregate-weighted early warning systems but several areas for further research were identified. While these models have the potential to provide clinical decision support, there is a need for standardized outcome measures to allow for rigorous evaluation of performance across models. Further research needs to address the interpretability of model outputs by clinicians, clinical efficacy of these systems through prospective study design, and their potential impact in different clinical settings.

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“…20(f) for one such explanation). In another work [106], the input time series is formed by EHRs sampled at a much lower rate, from which a DNN model can decide among a set of medical conditions. The medical condition can then be attributed to the different medical measurements.…”

Section: B From Explanations To Novel Scientific Insightsmentioning

confidence: 99%

Explaining Deep Neural Networks and Beyond: A Review of Methods and Applications

Montavon²,

et al. 2021

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Explainable artificial intelligence model to predict acute critical illness from electronic health records

Cited by 257 publications

References 45 publications

Applying artificial intelligence in the microbiome for gastrointestinal diseases: A review

Applying artificial intelligence in the microbiome for gastrointestinal diseases: A review

Machine Learning–Based Early Warning Systems for Clinical Deterioration: Systematic Scoping Review

Explaining Deep Neural Networks and Beyond: A Review of Methods and Applications

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