Quercetin glycosides and chlorogenic acid in highbush blueberry leaf decoction prevent cataractogenesis in vivo and in vitro: Investigation of the effect on calpains, antioxidant and metal chelating properties.

The present study investigates whether highbush blueberry leaf polyphenols prevent cataractogenesis and the underlying mechanisms. Chlorogenic acid, quercetin, rutin, isoquercetin and hyperoside were quantified in Vaccinium corymbosum leaf decoction (BBL) using HPLC-DAD. Wistar rats were injected subcutaneously with 20 µmol selenite (Na2SeO3)/kg body weight on postnatal (PN) day 10 (Se, n = 8-10/group) only or also intraperitoneally with 100 mg dry BBL/kg body weight on PN days 11 and 12 (SeBBL group, n = 10). Control group received only normal saline (C). Cataract evaluation revealed that BBL significantly prevented lens opacification. It, also, protected lens from selenite oxidative attack and prevented calpain activation, as well as protein loss and aggregation. In vitro studies showed that quercetin attenuated porcine lens turbidity caused by [Formula: see text] or Ca(2+) and interacted efficiently with those ions according to UV-Vis titration experiments. Finally, rutin, isoquercetin and hyperoside moderately inhibited pure human µ-calpain. Conclusively, blueberry leaf extract, a rich source of bioactive polyphenols, prevents cataractogenesis by their strong antioxidant, chelating properties and through direct/indirect inhibition of lens calpains.

Cerebral Area Differential Redox Response of Neonatal Rats to Selenite-Induced Oxidative Stress and to Concurrent Administration of Highbush Blueberry Leaf Polyphenols.

Our goal was to delineate the mechanisms of selenite-induced oxidative stress in neonatal rats and investigate the potential of blueberry leaf polyphenols to counteract the induced stress. Vaccinium corymbosum leaf decoction (BLD) was analyzed by UPLC-MS and LC-DAD, along with its in vitro antioxidant activity (DPPH radical scavenging, FRAP, ferrous chelation). Newborn suckling Wistar rats were randomly divided into three groups: 'Se' and 'SeBLD' received 20 µmol Na2SeO3/kg BW subcutaneously (PN day 10); 'SeBLD' received 100 mg dry BLD/kg BW intraperitoneally (PN11 and 12) and Group 'C' received normal saline. Βiochemical analysis revealed tissue-specific effects of selenite. Brain as a whole was more resistant to selenite toxicity in comparison to liver; midbrain and cerebellum were in general not affected, but cortex was moderately disturbed. Liver lipid peroxidation, GSH, SOD, CAT, GPx were significantly affected, whereas proteolytic activity was not. BLD, which is rich in chlorogenic acid and flavonols (especially quercetin derivatives), exerted significant antioxidant protective effects in all regions. In conclusion, we provide for the first time an insight to the neonatal rat cerebral and liver redox response against a toxic selenite dose and blueberry leaf polyphenols.