期刊
EPMA JOURNAL
卷 12, 期 3, 页码 365-381出版社
SPRINGER INT PUBL AG
DOI: 10.1007/s13167-021-00252-3
关键词
Predictive; Preventive and personalised medicine (PPPM; 3PM); Machine learning; Modelling; Bacteraemia diagnosis; Bacteraemia prediction; Blood culture's outcome prediction; Individualised electronic patient record analysis; Personalised antibiotic treatment; Support vector machine; Random forest; K-Nearest neighbours; Healthcare economy; Health policy; COVID-19
资金
- Fundacion Eugenio Rodriguez Pascual 2019 grant - Development of adaptive and bioinspired systems for glycaemic control with continuous subcutaneous insulin infusions and continuous glucose monitors
- Spanish Ministerio de Innovacion, Ciencia y Universidad [RTI2018-095180-B-I00]
- Madrid Regional Government FEDER grants [B2017/BMD3773, Y2018/NMT4668]
- CRUE-CSIC agreement
- Springer Nature
Predicting bacteraemia using machine learning techniques can aid in rapid diagnosis and personalized treatment, reducing medical errors and improving patient outcomes. The results of this study demonstrate high accuracy and sensitivity in predicting blood culture outcomes, showing promise in enhancing predictive and personalized medicine practices.
Background The bacteraemia prediction is relevant because sepsis is one of the most important causes of morbidity and mortality. Bacteraemia prognosis primarily depends on a rapid diagnosis. The bacteraemia prediction would shorten up to 6 days the diagnosis, and, in conjunction with individual patient variables, should be considered to start the early administration of personalised antibiotic treatment and medical services, the election of specific diagnostic techniques and the determination of additional treatments, such as surgery, that would prevent subsequent complications. Machine learning techniques could help physicians make these informed decisions by predicting bacteraemia using the data already available in electronic hospital records. Objective This study presents the application of machine learning techniques to these records to predict the blood culture's outcome, which would reduce the lag in starting a personalised antibiotic treatment and the medical costs associated with erroneous treatments due to conservative assumptions about blood culture outcomes. Methods Six supervised classifiers were created using three machine learning techniques, Support Vector Machine, Random Forest and K-Nearest Neighbours, on the electronic health records of hospital patients. The best approach to handle missing data was chosen and, for each machine learning technique, two classification models were created: the first uses the features known at the time of blood extraction, whereas the second uses four extra features revealed during the blood culture. Results The six classifiers were trained and tested using a dataset of 4357 patients with 117 features per patient. The models obtain predictions that, for the best case, are up to a state-of-the-art accuracy of 85.9%, a sensitivity of 87.4% and an AUC of 0.93. Conclusions Our results provide cutting-edge metrics of interest in predictive medical models with values that exceed the medical practice threshold and previous results in the literature using classical modelling techniques in specific types of bacteraemia. Additionally, the consistency of results is reasserted because the three classifiers' importance ranking shows similar features that coincide with those that physicians use in their manual heuristics. Therefore, the efficacy of these machine learning techniques confirms their viability to assist in the aims of predictive and personalised medicine once the disease presents bacteraemia-compatible symptoms and to assist in improving the healthcare economy.
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