Advances in Artemisinin Resistance: Mechanisms, Detection, and Novel Therapeutic Approaches

Abstract

Artemisinin-based combination therapies (ACTs) have been instrumental in reducing global malaria mortality over the past two decades. However, the rise of artemisinin resistance, particularly in Southeast Asia and parts of Africa, threatened these gains. Artemisinin resistance was characterized by delayed parasite clearance and is primarily driven by mutations in the kelch13 (K13) gene, which reduce the drug’s efficacy. This review explored the mechanisms behind artemisinin resistance, including genetic mutations, parasite stress responses, and reduced ring-stage sensitivity. Detection strategies, such as the use of molecular markers like K13 mutations and in vitro phenotypic assays, were discussed in detail. To combat resistance, novel therapeutic approaches were emerging, including the optimization of ACTs, the use of triple-drug regimens, host-directed therapies, and gene-editing technologies. The article highlighted the need for new antimalarial drugs, improved diagnostic tools, and global collaboration to address this growing challenge. We conducted the review by analyzing recent literature and summarizing advances in both resistance mechanisms and therapeutic strategies. Finally, future directions were outlined, emphasizing the importance of research, regulatory frameworks, and investment to mitigate the spread of resistance and ensure effective malaria control. Keywords: Artemisinin resistance, K13 mutations, malaria treatment, combination therapies, gene editing, host-directed therapies.