With the surged prevalence of myopia, the pathogenic mechanism underlying myopia has attracted attention. At present, it is generally believed in the flied that the reduced blood perfusion in the choroid is crucial for myopigenesis. Then, in the process of myopigenesis, how are the blurred visual signals transmitted to the choroidal blood vessels through the retina and retinal pigment epithelium, leading to the reduced choroidal blood perfusion. The cellular and molecular mechanisms underpinning this process remain elusive. In recent years, the theory of scleral hypoxia has attracted much attention. Popular signaling molecules in current research include dopamine, epidermal growth factor, retinoic acid, cholinergic molecules and adenosine, etc. These factors are likely to participate in signal transduction in retina and RPE, thus causing changes in choroidal blood flow and affecting the occurrence and development of myopia. Therefore, these signaling factors and their downstream pathways may provide new ideas for the prevention and control of myopia targets.
Retinopathy of Prematurity (ROP) is a blinding eye disease characterized by abnormal retinal vascular proliferation and is a major cause of visual impairment in children. Its pathogenesis is complex, involving multiple factors such as hyperoxia exposure, hypoxic compensation, oxidative stress, inflammatory responses, and abnormal angiogenesis, with oxidative stress playing a central role. It is characterized by excessive production of reactive oxygen species and impaired antioxidant function, leading to retinal vascular endothelial cell damage, formation of avascular areas, and abnormal vascular proliferation. Studies have shown that oxidative stress can promote the development and progression of ROP through vascular damage, nitrooxidative stress synergy, and interference with cellular metabolism. Current treatment strategies mainly include antioxidant agents (such as vitamin C, vitamin E, and lutein), signal pathway regulatory agents (such as nuclear factor erythroid 2-related factor 2 activators, signal transducer and activator of transcription 3 inhibitors), corticosteroids (such as Triamcinolone and Dexamethasone), and adrenergic receptor antagonists (such as Propranolol), but their efficacy and safety still require further validation. In the future, multidisciplinary collaboration should be strengthened to further explore the interactions between oxidative stress and other pathological mechanisms, and long-term follow-up studies should be conducted to develop safer and more effective strategies for the prevention and treatment of ROP, thereby improving the visual outcomes of preterm infants.