Abstract
A novel voltammetric sensor based on CeO2·Fe2O3 nanoparticles (NPs) has been developed for the determination of lipoic acid, playing an essential role in aerobic metabolism in the living organism. Sensor surface modification provides a 5.6-fold increase of the lipoic acid oxidation currents and a 20 mV anodic shift of the oxidation potential. The best voltammetric parameters have been obtained for the 0.5 mg mL−1 dispersion of CeO2·Fe2O3 NPs. Scanning electron microscopy (SEM) confirms the presence of spherical NPs of 25–60 nm, and their aggregates evenly distributed on the electrode surface and formed porous coverage. This leads to the 4.4-fold increase of the effective surface area vs. bare glassy carbon electrode (GCE). The sensor shows a significantly higher electron transfer rate. Electrooxidation of lipoic acid on CeO2·Fe2O3 NPs modified GCE is an irreversible diffusion-controlled pH-independent process occurring with the participation of two electrons. The sensor gives a linear response to lipoic acid in the ranges of 0.075–7.5 and 7.5–100 μM with the detection limit of 0.053 μM. The sensor is selective towards lipoic acid in the presence of inorganic ions, ascorbic acid, saccharides, and other S-containing compounds. The sensor developed has been tested on the pharmaceutical dosage forms of lipoic acid.
Highlights
Lipoic acid is an essential compound in living systems showing a wide spectrum of biological activity
It acts as a mitochondrial bioenergetic cofactor stimulating glucose and lipid metabolism as well as an insulin-mimetic agent via regulation of the IR/PI3K/Akt pathway [1,2,3]
Electrochemical sensors can be applied for these purposes as far as lipoic acid is the oxidizable substance as data for platinum [5], glassy carbon (GCE) [6,7], carbon fiber [8], or boron-doped diamond [9,10] electrodes confirm
Summary
Lipoic acid is an essential compound in living systems showing a wide spectrum of biological activity. It acts as a mitochondrial bioenergetic cofactor stimulating glucose and lipid metabolism as well as an insulin-mimetic agent via regulation of the IR/PI3K/Akt pathway [1,2,3]. Lipoic acid provides stress response regulation and an anti-inflammatory effect as well as neuronal protection and hyperalgesia attenuation [1,2,3,4]. These positive health effects are based on the antioxidant properties of lipoic acid in particular: . To provide high sensitivity and selectivity of quantification, sensor surface modification is a promising tool
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