Enhancing Optogenetics‐Based Cancer Therapy Via Nanotechnology

ABSTRACT

Optogenetics represents a promising frontier in precision cancer therapy by enabling spatiotemporal control over cellular behavior. However, its clinical application is limited by inefficient delivery of optogenetic components and poor tissue penetration of visible light. Recent advances in nanotechnology offer solutions to these challenges. Nanoscale drug delivery systems enhance the targeted delivery of optogenetic tools, while light‐conversion nanomaterials enable deep‐tissue activation. Besides, the integration of nanotechnology with optogenetics further facilitates the development of engineered living therapeutics, including immune cells and bacteria, allowing programmable and localized antitumor responses. Despite promising preclinical progress, key challenges remain in long‐term biosafety, immunogenicity, and precise light dosing. Future progress will depend on interdisciplinary efforts combining biocompatible nanomaterials, protein engineering, and artificial intelligence to advance clinically viable optogenetic therapies and pave the way toward personalized cancer treatment. Collectively, the synergistic integration of optogenetics and nanotechnology holds potential for overcoming longstanding barriers in cancer treatment, paving the way for precision cancer therapeutics.