Ascorbic acid-loaded gliadin nanoparticles as a novel nutraceutical formulation.

Ascorbic acid (AA) is one of the foremost antioxidants. Unfortunately, its sensitivity to different external stimuli such as light, heat and oxygen are concrete limitations for its use. Various approaches have been investigated in order to circumvent this problem and enhance the stability of the active compound, besides promoting its use for different applications. In this investigation, AA was encapsulated in a vegetal protein-based matrix made up of gliadin, the prolamin obtained from wheat kernels, with the aim of proposing a novel nutraceutical formulation. The nanosystems were characterized by an average diameter of < 200 nm and a negative surface charge of âˆ¼ -40 mV. The samples were not destabilized after incubation at different temperatures (up to 70 °C) or after the pasteurization procedure. Suitable stability was also observed in NaCl 100 mM, as well as after cryodesiccation when 10 % w/v of mannose was used. The gliadin nanoparticles showed the ability to retain high amounts of AA, promoting its prolonged release in PBS and under simulated gastrointestinal conditions. The nanosystems enhanced the antioxidant features of the compound as compared to its free form and preserved its chemical stability following UV exposition. The results demonstrate the potential application of the investigated nanoparticles as a novel nutraceutical formulation or as food fortificants.

Characterization and in vitro anticancer properties of chitosan-microencapsulated flavan-3-ols-rich grape seed extracts.

Studies have fully demonstrated that a diet rich in fruit and vegetables may reduce the incidence of tumors. In particular, Grape Seed Extract (GSE) has been shown to carry on chemopreventive and antitumor activity thanks to the numerous beneficial substances it contains. The purpose of this work was to create a biocompatible matrix containing GSE in order to obtain microparticles able to modulate its biopharmaceutical parameters. The spray-drying technique was chosen in order to realize chitosan microparticles characterized by a mean diameter of 4-10µm and a positive surface charge that decreased after GSE encapsulation. The evaluation of the pharmacological activity of the GSE and these GSE-loaded chitosan microparticles on different cancer cells together with CLSM investigation evidenced an increase in the antitumor effect promoted by the polysaccharide as a consequence of the enhanced cell interaction. Therefore GSE-loaded chitosan microparticles may be an innovative drug delivery system useful for the treatment of certain cancer-related diseases.