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Acute myocardial infarction (MI), a serious manifestation of ischemic heart disease, remains the culprit for mortality among coronary heart disease patients. Astaxanthin has demonstrated the ability to alleviate inflammation-induced myocardial damage while maintaining a balance between oxidants and antioxidants. This study investigates the cardioprotective potential of astaxanthin (ASX), particularly when encapsulated in nanostructured lipid carriers (NLCs), in isoprenaline (ISO)-induced myocardial infarction in rats. The study involved 48 rats separated into 6 groups. ASX and Nano-ASX (5 mg/kg) were administrated orally for 21 days before MI induction (isoprenaline, 85 mg/kg, subcutaneously). Blood and cardiac tissue samples were taken 24 h following the last isoprenaline injection for biochemical and histopathological investigation. The findings reveal that nano-formulated ASX significantly reduces oxidative stress and cardiac injury markers, including CK-MB, Troponin-I, and LDH. Additionally, it enhances antioxidant enzyme activities (GSH, GPx, and GSH-RD) and decreases inflammatory markers (COX-2 and VEGF). The study further demonstrates that nano-ASX stimulates autophagy by upregulating critical genes such as Beclin-1, ULK1, and LC3B, which are vital for cardiac protection and repair. Histological analysis confirms these biochemical outcomes, showing reduced myocardial damage and inflammation in the nano-ASX-treated groups. This study concludes the potential of ASX nano-formulations as an advanced therapeutic approach for myocardial infarction, leveraging improved bioavailability and targeting oxidative stress, inflammation, and autophagic mechanisms.

Astaxanthin (AST) is a naturally occurring carotenoid with potent anti-oxidative and anti-inflammatory potency against chronic diseases. In this study, we suspended AST in different nonionic emulsifiers to produce nanodispersions. The basic physicochemical properties of the produced AST nanodispersions were verified to select the optimized nonionic emulsifier. Among the tested emulsifiers, Polysorbate 20 produced the AST nanoemulsions with smaller particle diameters, narrower size distributions, and higher AST contents among these emulsifiers. The N-methyl-N-nitrosourea (MNU) administered mouse is a chemically induced retinal degeneration (RD) model with rapid progress rate. AST suspended in Polysorbate 20 was demonstrated to ameliorate the dramatic consequences of MNU on retina architectures and function in several different tests encompassing from electrophysiology to histology and molecular tests. Furthermore, the multi-electrodes array (MEA) was used to detect the firing activities of retinal ganglion cells within the inner retinal circuits. We found that AST nanodispersions could restrain the spontaneous firing response, enhance the light induced firing response, and preserve the basic configurations of visual signal pathway in degenerative retinas. The MEA assay provided an appropriate example to evaluate the potency of pharmacological compounds on retinal plasticity. In summary, emulsifier type affects the basic physicochemical characteristic of AST nanodispersions. Polysorbate 20 acts as an optimized nonionic emulsifier for the efficient delivery of AST nanodispersions to retina. AST nanodispersions can alleviate the photoreceptor loss and rectify the abnormities in visual signal transmission.