Abstract
Cell-based regenerative therapy holds promise for a broad spectrum of retinal diseases characterized by irreversible photoreceptor cell (PRC) loss, including retinitis pigmentosa (RP) and age-related macular degeneration. While gene therapy has delivered landmark successes for selected indications, it does not directly replace lost PRCs and is not well suited for advanced-stages of diseases. In this context, cell-based regenerative approaches-either PRC suspensions or retinal sheets-aim to rebuild the outer retinal circuitry and restore light responses across different retinal diseases. In addition to its relatively high prevalence (1 in 3000-5000 individuals), the PRC-specific degeneration pattern in RP has motivated numerous preclinical studies aimed at clinical application. In this review, we first outline the two major graft modalities-cell suspensions and retinal sheet transplantation-from the perspective of their respective advantages and limitations. Here, we summarize preclinical and clinical evidence for both modalities, highlighting the first-in-human trial of transplantation of human iPSC-derived retinal organoid sheets in late-stage RP, which demonstrated a favorable safety profile and two-year graft survival. We then analyze the challenges that emerged from this first-in-human trial and discuss potential bioengineering and biological solutions. Finally, we consider the prospects of extending these transplantation strategies beyond RP to macular diseases, where PRC replacement may also provide therapeutic benefit. Collectively, the field is transitioning from proof-of-concept to diversified clinical exploration; converging advances in developmental biology, genome engineering, and high-throughput cell analytics are poised to accelerate functional vision restoration in retinal diseases.