Improved prediction of antimicrobial resistance in Klebsiella pneumoniae using machine learning

Klebsiella pneumoniae is an important cause of healthcare-associated infections, with high levels of antimicrobial resistance (AMR) to critical antibiotics such as carbapenems and third-generation cephalosporins (3GCs). Accurate antimicrobial susceptibility detection is essential for guiding appropriate treatment. In this study, we evaluated the efficacy of machine learning (ML) models for predicting AMR phenotypes in K. pneumoniae particularly for antibiotics for which rule-based approaches fail. We analyzed a dataset of 5,907 K. pneumoniae genomes from public databases and a genomic surveillance project in Spanish hospitals. ML models were trained to predict AMR phenotypes using genomic features, and their performance was compared to ResFinder, which implements a conventional rule-based approach. Models were evaluated based on predictive accuracy across antibiotics. Additionally, we conducted a detailed analysis of the genomic features associated with AMR identified by ML to identify new putative AMR determinants. ResFinder exhibited low prediction accuracy for amikacin, fosfomycin, and piperacillin/tazobactam, whereas ML models significantly improved the prediction accuracy for these antibiotics. Moreover, we provide insights into why rule-based methods failed in these cases, specifically related to the genes acc(6)-Ib-cr , fosA , and bla _OXA-1 , respectively. Finally, we found possible genetic factors related to resistance for each antibiotic. Our findings underscore the value of ML models in AMR prediction based on genome information for K. pneumoniae , especially in challenging cases where traditional methods have low success rates. Continued evaluation and refinement of ML approaches are essential for applying these methods to enhance AMR detection in clinical and public health contexts.