Longitudinal evaluation of morphological, functional and vascular alterations in a rat model of experimental glaucoma

[Display omitted] •Transient reduction in arteriolar and venular caliber as early changes due to OHT.•Permanent retinal capillary dystrophy in response to OHT without fluorescein leakage.•OHT induced long-term increase in optic nerve cupping and aberrant choroidal vessels.•Late venular thinning and lack of vitreal infiltrating immune cells following LPC.•Progressive degeneration of RGCs despite the return to normal IOP values. Glaucoma, the leading cause of irreversible blindness worldwide, is a neurodegenerative disease characterized by chronic axonal damages and progressive loss of retinal ganglion cells, with increased intraocular pressure (IOP) as the primary risk factor. While current treatments focus solely on reducing IOP, understanding glaucoma through experimental models is essential for developing new therapeutic strategies and biomarkers for early diagnosis. Our research group developed an ocular hypertension rat model based on limbal plexus cautery, which provides significant glaucomatous neurodegeneration up to four weeks after injury. We evaluated long-term morphological, functional, and vascular alterations in this model. Our results showed that transient ocular hypertension, lasting approximately one week, can lead to progressive increase in optic nerve cupping and retinal ganglion cells loss. Remarkably, the pressure insult caused several vascular changes, such as arteriolar and venular thinning, and permanent choroidal vascular swelling. This study provides evidence of the longitudinal effects of a pressure insult on retinal structure and function using clinical modalities and techniques. The multifactorial changes reported in this model resemble the complex retinal ganglion cell degeneration found in glaucoma patients, and therefore may also provide a unique tool for the development of novel interventions to either halt or slow down disease progression.