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Using machine learning models to predict falls in hospitalised adults

Samad Jahandideh, Anastasia Hutchinson, Anastasia Hutchinson, Tracey Bucknall, Julie Considine, Andrea Driscoll, Elizabeth Manias, Nicole M. Phillips, Bodil Rasmussen, N. J. de Vos, Ashley Hutchinson, Ashley Hutchinson

2024International Journal of Medical Informatics20 citationsDOIOpen Access PDF

Abstract

BACKGROUND: Identifying patients at high risk of falling is crucial in implementing effective fall prevention programs. While the integration of information systems is becoming more widespread in the healthcare industry, it poses a significant challenge in analysing vast amounts of data to identify factors that could enhance patient safety. OBJECTIVE: To determine fall-associated factors and develop high-performance prediction tools for at-risk patients in acute and sub-acute care services in Australia. METHODS: , electronic health records, and the health workforce dataset. Machine learning techniques, including Random Forest and Deep Neural Network models, were used to analyse the data, predict patient falls, and identify the most important risk factors for falls in this population. Model performance was evaluated using accuracy, F1-score, precision, recall, specificity, Matthew's correlation coefficient, and the area under the receiver operating characteristic curve (AUC). RESULTS: The deep neural network and random forest models were highly accurate in predicting hospital patient falls. The deep neural network model achieved an accuracy of 0.988 and a specificity of 0.999, while the RF achieved an accuracy of 0.989 and a specificity of 1.000. The top 20 variables impacting falls were compared across both models, and 12 common factors were identified. These factors can be broadly classified into three categories: patient-related factors, staffing-related factors, and admission-related factors. Although not all factors are modifiable, they must be considered when planning fall prevention interventions. CONCLUSION: The study demonstrated machine learning's potential to predict falls and identify key risk factors. Further validation across diverse populations and settings is essential for broader applicability.

Topics & Concepts

MedicineRandom forestMachine learningArtificial intelligenceArtificial neural networkReceiver operating characteristicPopulation healthWorkforceHealth careDeep learningAcute carePredictive modellingPopulationMedical emergencyComputer scienceEconomicsEconomic growthEnvironmental healthBalance, Gait, and Falls PreventionFrailty in Older AdultsProsthetics and Rehabilitation Robotics