Abstract Medication resistance in psychotic disorders represents a critical challenge in forensic psychiatry, where up to 50% of patients show poor treatment response, leading to increased risk of relapse, violence, and rehospitalization. Feature Transfer, a novel machine learning framework based on rank aggregated feature selection, transfers predictive features identified for one outcome to related outcomes while maintaining clinical interpretability, a critical advantage over conventional transfer learning approaches that obscure feature level insights by transferring complex model parameters. Applied to psychotic disorders, this methodology identified key predictors for medication resistance and assessed their transferability to related clinical outcomes. Analyzing data from 893 patients across 11 forensic psychiatric institutions, we compared Feature Transfer models (using the top 25 features discriminating medication resistance from responders) with full feature models (95 features) for predicting clinical relapse, treatment non adherence, and escape behaviors. In the broader psychotic disorders sample, Feature Transfer achieved statistically equivalent performance to full feature models for clinical relapse and treatment non adherence (F1 score differences with confidence intervals overlapping zero), though performed less effectively for escape behaviors (AUC: 0.736 vs 0.838). In schizophrenia patients (n=634), Feature Transfer showed statistically significant improvement in F1 score for clinical relapse prediction compared to full feature models (difference: 0.119, 95% CI: 0.025 to 0.213), with notably higher sensitivity (0.912 vs 0.802) while maintaining comparable discriminative ability (AUC: 0.912 vs 0.925, difference not statistically significant). Treatment history features, particularly previous medication unresponsiveness and duration of clinical care, maintained high predictive importance across multiple clinical outcomes (relapse, non adherence, and escape behaviors), suggesting they represent fundamental risk indicators regardless of the specific outcome being predicted. While our retrospective design limits causal inference and relies on historical indicators as proxies for secondary outcomes (relapse and escape behaviors), the demonstrated utility of medication resistance features across different clinical outcomes reveals potential shared risk dimensions in psychotic disorders, particularly for relapse prediction in schizophrenia. Feature Transfer offers a transparent approach for identifying common predictive factors that could advance personalized intervention strategies in complex psychiatric populations.