Machine learning as a supportive tool to recognize cardiac arrest in emergency calls

Blomberg, Stig Nikolaj; Folke, Fredrik; Ersbøll, Annette Kjær; Christensen, Helle Collatz; Torp‐Pedersen, Christian; Sayre, Michael R.; Counts, Catherine R.; Lippert, Freddy

doi:10.1016/j.resuscitation.2019.01.015

Cited by 143 publications

(130 citation statements)

References 31 publications

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“…An alternative approach could be to develop a clinical decision support system with machine learning capabilities for all these symptoms, in order to help EMS clinicians to distinguish patients with time-sensitive conditions from those without. For example, machine learning support tools have shown higher sensitivity and faster identification over the telephone in recognising cardiac arrest compared with professional dispatchers [16]. These instruments need to be tested in large patient cohorts in order to prove their eventual value.…”

Section: Main Textmentioning

confidence: 99%

Towards definitions of time-sensitive conditions in prehospital care

Wibring

Magnusson

Axelsson

et al. 2020

Scand J Trauma Resusc Emerg Med

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Background: Prehospital care has changed in recent decades. Advanced assessments and decisions are made early in the care chain. Patient assessments form the basis of a decision relating to prehospital treatment and the level of care. This development imposes heavy demands on the ability of emergency medical service (EMS) clinicians properly to assess the patient. EMS clinicians have a number of assessment instruments and triage systems available to support their decisions. Many of these instruments are based on vital signs and can sometimes miss timesensitive conditions. With this commentary, we would like to start a discussion to agree on definitions of temporal states in the prehospital setting and ways of recognising patients with time-sensitive conditions in the most optimal way. Main body: There are several articles discussing the identification and management of time-sensitive conditions. In these articles, neither definitions nor terminology have been uniform. There are a number of problems associated with the definition of time-sensitive conditions. For example, intoxication can be minor but also life threatening, depending on the type of poison and dose. Similarly, diseases like stroke and myocardial infarction can differ markedly in terms of severity and the risk of life-threatening complications. Another problem is how to support EMS clinicians in the early recognition of these conditions. It is well known that many of them can present without a deviation from normal in vital signs. It will most probably be impossible to introduce specific decision support tools for every individual time-sensitive condition. However, there may be information in the type and intensity of the symptoms patients present. In future, biochemical markers and machine learning support tools may help to identify patients with time-sensitive conditions and predict mortality at an earlier stage. Conclusion: It may be of great value for prehospital clinicians to be able to describe time-sensitive conditions. Today, neither definitions nor terminology are uniform. Our hope is that this commentary will initiate a discussion on the issue aiming at definitions of time-sensitive conditions in prehospital care and how they should be recognised in the most optimal fashion.

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Section: Main Textmentioning

confidence: 99%

Towards definitions of time-sensitive conditions in prehospital care

Wibring

Magnusson

Axelsson

et al. 2020

Scand J Trauma Resusc Emerg Med

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“…18 Deep learning has also been used to predict outcomes in heart failure 19 and to identify out-of-hospital cardiac arrest in emergency telephone calls in Denmark. 20 A network model using an AI-enabled electrocardiogram was successful in screening patients for asymptomatic left ventricle dysfunction. 21 The integration of AI technology and biosensors with the wireless capabilities through Bluetooth, Wi-Fi, and global positioning systems have led to the development of pointof-care (POC) diagnosis.…”

Section: Central Messagementioning

confidence: 99%

Wireless monitoring and artificial intelligence: A bright future in cardiothoracic surgery

Kalfa

Agrawal

Goldshtrom

et al. 2020

The Journal of Thoracic and Cardiovascular Surgery

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“…perpetuity. preprint (which was not certified by peer review) is the author/funder, who has granted medRxiv a license to display the preprint in The copyright holder for this this version posted August 28, 2020. ; https://doi.org/10.1101/2020.06.26.20123216 doi: medRxiv preprint volume, [31] automatic stress detection of the caller, [32] interpretable knowledge extraction, [33] performance monitoring, [34] cardiac arrest calls assistance [35] or triaging unconscious and fainting patients. [36] Therefore, we can argue that deep learning models are a feasible and promising technology to improve EMD through EMCI classification.…”

Section: Prediction Of Emergency Callsmentioning

confidence: 99%

Deep multitask ensemble classification of emergency medical call incidents combining multimodal data improves emergency medical dispatch

Ferri

Sáez

Castro

et al. 2020

Preprint

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Objective: To develop a predictive model to aid non-clinical dispatchers to classify emergency medical call incidents by their life-threatening level (yes/no), admissible response delay (undelayable, minutes, hours, days) and emergency system jurisdiction (emergency system/primary care) in real time. Materials: A total of 1 244 624 independent retrospective incidents from the Valencian emergency medical dispatch service in Spain from 2009 to 2012, comprising clinical features, demographics, circumstantial factors and free text dispatcher observations. Methods: A deep multitask ensemble model integrating four subnetworks, composed in turn by multi-layer perceptron modules, bidirectional long short-term memory units and a bidirectional encoding representations from transformers module. Results: The model showed a F1 score of 0.771 in life-threatening classification, 0.592 in response delay and 0.801 in jurisdiction, obtaining a performance increase of 13.2%, 16.4% and 4.5%, respectively, with regard to the current in-house triage protocol of the Valencian emergency medical dispatch service. Discussion: The model captures information present in emergency medical calls not considered by the existing in-house triage protocol, but relevant to carry out incident classification. Besides, the results suggest that most of this information is present in the free text dispatcher observations. Conclusion: To our knowledge, this study presents the development of the first deep learning model undertaking emergency medical call incidents classification. Its adoption in medical dispatch centers would potentially improve emergency dispatch processes, resulting in a positive impact in patient wellbeing and health services sustainability.

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Machine learning as a supportive tool to recognize cardiac arrest in emergency calls

Cited by 143 publications

References 31 publications

Towards definitions of time-sensitive conditions in prehospital care

Towards definitions of time-sensitive conditions in prehospital care

Wireless monitoring and artificial intelligence: A bright future in cardiothoracic surgery

Deep multitask ensemble classification of emergency medical call incidents combining multimodal data improves emergency medical dispatch

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