Clinical Text Data in Machine Learning: Systematic Review

Spasić, Irena; Nenadić, Goran

doi:10.2196/17984

Cited by 220 publications

(144 citation statements)

References 128 publications

(271 reference statements)

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“…One of the most problematic issues is their dependence on huge amounts of training data: SOTA embedding models are currently trained on hundreds of billions of tokens [89]. This magnitude of data volume is out of reach for any training effort in the medical/clinical domain [90]. Also, embeddings are very vulnerable to malicious attacks or adversarial examples-small changes at the input level may result in severe misclassification [5].…”

Section: Discussionmentioning

confidence: 99%

Medical Information Extraction in the Age of Deep Learning

Hahn

Oleynik

2020

Yearb Med Inform

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Objectives: We survey recent developments in medical Information Extraction (IE) as reported in the literature from the past three years. Our focus is on the fundamental methodological paradigm shift from standard Machine Learning (ML) techniques to Deep Neural Networks (DNNs). We describe applications of this new paradigm concentrating on two basic IE tasks, named entity recognition and relation extraction, for two selected semantic classes—diseases and drugs (or medications)—and relations between them. Methods: For the time period from 2017 to early 2020, we searched for relevant publications from three major scientific communities: medicine and medical informatics, natural language processing, as well as neural networks and artificial intelligence. Results: In the past decade, the field of Natural Language Processing (NLP) has undergone a profound methodological shift from symbolic to distributed representations based on the paradigm of Deep Learning (DL). Meanwhile, this trend is, although with some delay, also reflected in the medical NLP community. In the reporting period, overwhelming experimental evidence has been gathered, as illustrated in this survey for medical IE, that DL-based approaches outperform non-DL ones by often large margins. Still, small-sized and access-limited corpora create intrinsic problems for data-greedy DL as do special linguistic phenomena of medical sublanguages that have to be overcome by adaptive learning strategies. Conclusions: The paradigm shift from (feature-engineered) ML to DNNs changes the fundamental methodological rules of the game for medical NLP. This change is by no means restricted to medical IE but should also deeply influence other areas of medical informatics, either NLP- or non-NLP-based.

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Section: Discussionmentioning

confidence: 99%

Medical Information Extraction in the Age of Deep Learning

Hahn

Oleynik

2020

Yearb Med Inform

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“…12 Several studies have utilized artificial intelligent algorithms to automatically extract structured information from clinical notes in EMRs. 13,14 In Japan, the Next Stage ER system (NSER; TXP Medical Co. Ltd, Tokyo, Japan) has been increasingly implemented in EDs of university and tertiary care hospitals. 15 The NSER system supports not only physician decision making, clinician workflow, and communication but also EMR standardization.…”

Section: Introductionmentioning

confidence: 99%

Validation of chief complaints, medical history, medications, and physician diagnoses structured with an integrated emergency department information system in Japan: the Next Stage ER system

Goto

Hara

Hashimoto

et al. 2020

Acute Medicine & Surgery

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Aim Emergency department information systems (EDIS) facilitate free‐text data use for clinical research; however, no study has validated whether the Next Stage ER system (NSER), an EDIS used in Japan, accurately translates electronic medical records (EMRs) into structured data. Methods This is a retrospective cohort study using data from the emergency department (ED) of a tertiary care hospital from 2018 to 2019. We used EMRs of 500 random samples from 27,000 ED visits during the study period. Through the NSER system, chief complaints were translated into 231 chief complaint categories based on the Japan Triage and Acuity Scale. Medical history and physician’s diagnoses were encoded using the International Classification of Diseases, 10th Revision; medications were encoded as Anatomical Therapeutic Chemical Classification System codes. Two reviewers independently reviewed 20 items (e.g., presence of fever) for each study component (e.g., chief complaints). We calculated association measures of the structured data by the NSER system, using the chart review results as the gold standard. Results Sensitivities were very high (>90%) in 17 chief complaints. Positive predictive values were high for 14 chief complaints (≥80%). Negative predictive values were ≥96% for all chief complaints. For medical history and medications, most of the association measures were very high (>90%). For physicians’ ED diagnoses, sensitivities were very high (>93%) in 16 diagnoses; specificities and negative predictive values were very high (>97%). Conclusions Chief complaints, medical history, medications, and physician’s ED diagnoses in EMRs were well‐translated into existing categories or coding by the NSER system.

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“…7 NLP is still limited by different levels of development according to different languages and countries, but in the near future, it will provide fundamental understanding in the richest resource of medical knowledge such as the medical narrative included in clinical charts. 8 In intensive care medicine, the most used AI algorithms are those based on machine learning, as critical care is a good source for large dataset of numeric data derived by complex continuous monitoring and by continuous therapies.…”

Section: Clinical Applications Of Artificial Intelligencementioning

confidence: 99%

Artificial Intelligence in the Intensive Care Unit

Greco

Caruso

Cecconi

2020

Semin Respir Crit Care Med

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The diffusion of electronic health records collecting large amount of clinical, monitoring, and laboratory data produced by intensive care units (ICUs) is the natural terrain for the application of artificial intelligence (AI). AI has a broad definition, encompassing computer vision, natural language processing, and machine learning, with the latter being more commonly employed in the ICUs. Machine learning may be divided in supervised learning models (i.e., support vector machine [SVM] and random forest), unsupervised models (i.e., neural networks [NN]), and reinforcement learning. Supervised models require labeled data that is data mapped by human judgment against predefined categories. Unsupervised models, on the contrary, can be used to obtain reliable predictions even without labeled data. Machine learning models have been used in ICU to predict pathologies such as acute kidney injury, detect symptoms, including delirium, and propose therapeutic actions (vasopressors and fluids in sepsis). In the future, AI will be increasingly used in ICU, due to the increasing quality and quantity of available data. Accordingly, the ICU team will benefit from models with high accuracy that will be used for both research purposes and clinical practice. These models will be also the foundation of future decision support system (DSS), which will help the ICU team to visualize and analyze huge amounts of information. We plea for the creation of a standardization of a core group of data between different electronic health record systems, using a common dictionary for data labeling, which could greatly simplify sharing and merging of data from different centers.

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Clinical Text Data in Machine Learning: Systematic Review

Cited by 220 publications

References 128 publications

Medical Information Extraction in the Age of Deep Learning

Medical Information Extraction in the Age of Deep Learning

Validation of chief complaints, medical history, medications, and physician diagnoses structured with an integrated emergency department information system in Japan: the Next Stage ER system

Artificial Intelligence in the Intensive Care Unit

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