Author: Xiao, Yang; Yan, Li; Zhang, Mingyang; Pinkerton, Kent E.; Cao, Haosen; Xiao, Ying; Li, Wei; Li, Shuai; Wang, Yancheng; Li, Shusheng; Cao, Zhiguo; Wong, Gary Wingâ€Kin; Xu, Hui; Zhang, Haiâ€Tao
Title: Machine learning discovery of distinguishing laboratory features for severity classification of COVIDâ€19 patients Cord-id: aa2jhkk5 Document date: 2021_3_22
ID: aa2jhkk5
Snippet: The exponential spread of COVIDâ€19 worldwide is evident, with devastating outbreaks primarily in the United States, Spain, Italy, the United Kingdom, France, Germany, Turkey and Russia. As of 1 May 2020, a total of 3,308,386 confirmed cases have been reported worldwide, with an accumulative mortality of 233,093. Due to the complexity and uncertainty of the pathology of COVIDâ€19, it is not easy for frontâ€line doctors to categorise severity levels of clinical COVIDâ€19 that are general and
Document: The exponential spread of COVIDâ€19 worldwide is evident, with devastating outbreaks primarily in the United States, Spain, Italy, the United Kingdom, France, Germany, Turkey and Russia. As of 1 May 2020, a total of 3,308,386 confirmed cases have been reported worldwide, with an accumulative mortality of 233,093. Due to the complexity and uncertainty of the pathology of COVIDâ€19, it is not easy for frontâ€line doctors to categorise severity levels of clinical COVIDâ€19 that are general and severe/critical cases, with consistency. The more than 300 laboratory features, coupled with underlying disease, all combine to complicate proper and rapid patient diagnosis. However, such screening is necessary for early triage, diagnosis, assignment of appropriate level of care facility, and institution of timely intervention. A machine learning analysis was carried out with confirmed COVIDâ€19 patient data from 10 January to 18 February 2020, who were admitted to Tongji Hospital, in Wuhan, China. A softmax neural networkâ€based machine learning model was established to categorise patient severity levels. According to the analysis of 2662 cases using clinical and laboratory data, the present model can be used to reveal the top 30 of more than 300 laboratory features, yielding 86.30% blind test accuracy, 0.8195 F1â€score, and 100% consistency using a twoâ€way patient classification of severe/critical to general. For severe/critical cases, F1â€score is 0.9081 (i.e. recall is 0.9050, and precision is 0.9113). This model for classification can be accomplished at a miniâ€secondâ€level computational cost (in contrast to minuteâ€level manual). Based on available COVIDâ€19 patient diagnosis and therapy, an artificial intelligence model paradigm can help doctors quickly classify patients with a high degree of accuracy and 100% consistency to significantly improve diagnostic and classification efficiency. The discovered top 30 laboratory features can be used for greater differentiation to serve as an essential supplement to current guidelines, thus creating a more comprehensive assessment of COVIDâ€19 cases during the early stages of infection. Such early differentiation will help the assignment of the appropriate level of care for individual patients.
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