Development of a Prognostic Model for the Outcome of Viral Lung Disease Using Machine Learning Algorithms
https://doi.org/10.35401/2541-9897-2026-11-1-7-15
Abstract
Background: During periods of increasing respiratory infections, stratifying patient care for virus-associated lung injury is crucial.
Objective: To develop a prognostic model for the outcome of viral lung injury using machine learning algorithms.
Materials and methods: The study included 295 patients with COVID-associated pneumonia, divided into two groups: 1) deceased (n=78) and 2) survivors (n=217). Data processing was performed using IDE R Studio (Version 4.3.1). The prognostic model was created using potential predictors and machine learning algorithms: multivariate logistic regression, random forest, and stochastic gradient boosting. A 5-fold cross-validation method (KFold) was used. Prediction models for mortality were implemented in Google Colaboratory with Python. Model quality was assessed by metrics such as ROC-AUC and confusion matrix, which provided measures like precision, recall, sensitivity, specificity, and F1-score.
Results: The prognostic outcome model was based on mortality predictors, demonstrating a high level of statistical significance between the predicted groups, with significant predictors including the presence of two or more comorbidities, respiratory failure above grade 2, pronounced myalgia and dyspnea, neutrophil-to-lymphocyte ratio >5.1, a critical decrease in eosinophil count accompanied by elevated ESR, glucose, AST, CRP, urea levels, and decreased hemoglobin (p<0.05).
Conclusion: The mortality risk prediction model developed using machine learning methods, particularly the random forest algorithm (AUC=0.99), demonstrates high accuracy and enables the assessment of mortality risk at hospital admission, guiding management decisions and optimizing treatment strategies.
About the Authors
E. A. BorodulinaRussian Federation
Elena A. Borodulina - Dr. Sci. (Med.), Professor, Head of the Department of Phthisiology and Pulmonology, Samara State Medical University.
89 Chapaevskaya St., Samara, 443099
E. S. Vdoushkina
Russian Federation
Elizaveta S. Vdoushkina - Cand. Sci. (Med.), Associate Professor, Department of Phthisiology and Pulmonology, Samara State Medical University.
Samara
K. I. Shakhgeldyan
Russian Federation
Karina I. Shakhgeldyan - Dr. Sci (Tech.), Head of Scientific Laboratory, School of Medicine and Life Sciences, Far Eastern Federal University; Professor, Artificial Intelligence Research Center, Vladivostok State University.
Vladivostok
E. A. Kurdyukova
Russian Federation
Elena A. Kurdyukova - Cand. Sci. (Biol.), Chief Specialist of Artificial Intelligence Laboratory, Institute of Automation and Control Processes, Far Eastern Branch of the Russian Academy of Sciences; 2nd year Master’s Student оf Artificial Intelligence Research Center, Vladivostok State University.
Vladivostok
B. E. Borodulin
Russian Federation
Boris E. Borodulin - Dr. Sci. (Med.), Professor, Department of Phthisiology and Pulmonology, Samara State Medical University.
Samara
S. Y. Pushkin
Russian Federation
Sergey Y. Pushkin - Dr. Sci. (Med.), Head of the Department of Surgical Diseases of Children and Adults, Samara State Medical University; Chief Physician, Samara Regional Clinical Hospital named after V.D. Seredavin; Chief Freelance Thoracic Surgeon of the Samara Region and the Volga Federal District.
Samara
K. V. Zhilinskaya
Russian Federation
Kristina V. Zhilinskaya - Resident, Department of Phthisiology and Pulmonology, Samara State Medical University.
Samara
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Review
For citations:
Borodulina E.A., Vdoushkina E.S., Shakhgeldyan K.I., Kurdyukova E.A., Borodulin B.E., Pushkin S.Y., Zhilinskaya K.V. Development of a Prognostic Model for the Outcome of Viral Lung Disease Using Machine Learning Algorithms. Innovative Medicine of Kuban. 2026;11(1):7-15. (In Russ.) https://doi.org/10.35401/2541-9897-2026-11-1-7-15
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