| dc.description.abstract | Reactive oxygen species (ROS) are continuously generated as a by-product of normal aerobic metabolism. Elevated ROS formation
leads to potential damage of biological structures and is implicated in various diseases. Astaxanthin, a xanthophyll carotenoid, is a
secondary metabolite responsible for the red-orange color of a number of marine animals and microorganisms. There is mounting
evidence that astaxanthin has powerful antioxidant, anti-inflammatory, and antiapoptotic activities. Hence, its consumption can
result in various health benefits, with potential for therapeutic application. Astaxanthin contains both a hydroxyl and a keto
group, and this unique structure plays important roles in neutralizing ROS. The molecule quenches harmful singlet oxygen,
scavenges peroxyl and hydroxyl radicals and converts them into more stable compounds, prevents the formation of free radicals,
and inhibits the autoxidation chain reaction. It also acts as a metal chelator and converts metal prooxidants into harmless
molecules. However, like many other carotenoids, astaxanthin is affected by the environmental conditions, e.g., pH, heat, or
exposure to light. It is hence susceptible to structural modification, i.e., via isomerization, aggregation, or esterification, which
alters its physiochemical properties. Here, we provide a concise overview of the distribution of astaxanthin in tissues, and
astaxanthin structures, and their role in tackling singlet oxygen and free radicals. We highlight the effect of structural
modification of astaxanthin molecules on the bioavailability and biological activity. These studies suggested that astaxanthin
would be a promising dietary supplement for health applications. | en_US |
