Antioxidants are vital compounds that can delay or prevent oxidation, a chemical process triggered by atmospheric oxygen or reactive oxygen species (ROS). These compounds play a crucial role in protecting various materials and biological systems from oxidative damage. In industrial applications, antioxidants are used to stabilize polymers, petrochemicals, food products, cosmetics, and pharmaceuticals, extending their shelf life and maintaining quality. In living organisms, antioxidants form part of the body’s defense mechanism against the harmful effects of free radicals—unstable molecules that contribute to aging, inflammation, and diseases such as cancer and cardiovascular disorders.
The measurement of antioxidant activity (AA) provides insight into how effectively a substance can neutralize oxidative stress. Various chemical and physicochemical methods have been developed to assess AA, generally based on monitoring reaction rates or the completeness of oxidation or reduction processes. These methods are often categorized into three main types: those that measure oxygen consumption, those that track the formation of oxidation products, and those that quantify the uptake or neutralization of free radicals. In the first two approaches, antioxidant activity is determined by the degree of inhibition or the rate at which reagents are consumed or products are formed.
Several common laboratory methods are widely used to quantify antioxidant activity. The DPPH assay is one of the simplest and most popular techniques. It measures an antioxidant’s ability to donate a hydrogen atom to the purple-colored DPPH radical, which fades to yellow upon reduction—this color change is measured at 517 nm. The ABTS assay operates on a similar principle, using a blue-green ABTS radical cation that decolorizes upon interaction with antioxidants; the change is measured at 734 nm. The FRAP assay (Ferric Reducing Antioxidant Power) evaluates an antioxidant’s reducing capacity by its ability to convert Fe³⁺ to Fe²⁺ in a ferric-tripyridyltriazine complex, producing a blue color read at 593 nm. The ORAC assay (Oxygen Radical Absorbance Capacity) assesses the antioxidant’s ability to protect a fluorescent probe from degradation by peroxyl radicals, simulating biological oxidative stress. Lastly, the Hydrogen Peroxide Scavenging Assay measures an antioxidant’s direct ability to neutralize hydrogen peroxide, indicated by a reduction in color intensity.
Together, these methods provide comprehensive insight into the potency and mechanism of antioxidants, both in industrial applications and biological systems, highlighting their essential role in maintaining stability and health.Antioxidants and Their Measurement Methods
