helper T cells, these vaccines enable highly selective tumor cell elimination while establishing durable immunological memory. Despite their promise, the rational development and clinical translation of neoantigen-based vaccines remain constrained by substantial challenges that limit their broad therapeutic impact. This review provides a comprehensive synthesis of the field, tracing the entire pipeline from the molecular origin and computational prediction of neoantigens to the design principles guiding vaccine formulation. It examines mechanisms of action across diverse platforms-including mRNA, peptide, and dendritic cell vaccines-and explores synergistic strategies that combine adjuvants or immune checkpoint blockade to enhance efficacy. In addition, we critically evaluate key barriers to success, such as immunosuppressive tumor microenvironments, T-cell dysfunction, and antigenic escape. Finally, we highlight recent clinical advances aimed at overcoming these barriers, thereby outlining a framework for optimizing neoantigen vaccine design to maximize their therapeutic potential in cancer treatment. Notably, encouraging progress has been reported in malignancies such as non-small cell lung cancer and melanoma, underscoring the translational promise of this strategy.
Shi et al. (Fri,) studied this question.