Interpretable machine learning identifies paediatric Systemic Lupus Erythematosus subtypes based on gene expression data

Abstract: Transcriptomic analyses are commonly used to identify differentially expressed genes between patients and controls, or within individuals across disease courses. These methods, whilst effective, cannot encompass the combinatorial effects of genes driving disease. We applied rule-based machine learning (RBML) models and rule networks (RN) to an existing paediatric Systemic Lupus Erythematosus (SLE) blood expression dataset, with the goal of developing gene networks to separate low and high disease activity (DA1… Show more

“…Ultimately, they were able to classify patients with high and low disease activity using the expression of only 34 genes (accuracy = 81%). Examination of the genes that discriminated each subset provided useful information about underlying subset biology/pathogenesis, including the finding that the interferon response term was limited to low disease activity in this cohort [22 ▪ ]. Hierarchical clustering of the initial machine learning model output resulted in even further granularity about the disease activity subtypes, which were correlated with clinical data.…”

“…Yones et al [22 ▪ ] applied machine learning to blood gene expression data from pediatric patients with lupus with the aim of classifying patients into those with high and low disease activity. The authors repeatedly reduced the number of model input genes, by various feature selection techniques.…”

Recent advances in the use of machine learning and artificial intelligence to improve diagnosis, predict flares, and enrich clinical trials in lupus

“…Ultimately, they were able to classify patients with high and low disease activity using the expression of only 34 genes (accuracy = 81%). Examination of the genes that discriminated each subset provided useful information about underlying subset biology/pathogenesis, including the finding that the interferon response term was limited to low disease activity in this cohort [22 ▪ ]. Hierarchical clustering of the initial machine learning model output resulted in even further granularity about the disease activity subtypes, which were correlated with clinical data.…”

“…Yones et al [22 ▪ ] applied machine learning to blood gene expression data from pediatric patients with lupus with the aim of classifying patients into those with high and low disease activity. The authors repeatedly reduced the number of model input genes, by various feature selection techniques.…”

Recent advances in the use of machine learning and artificial intelligence to improve diagnosis, predict flares, and enrich clinical trials in lupus