Consumption of a Mango Fruit Powder Protects Mice from High-Fat Induced Insulin Resistance and Hepatic Fat Accumulation.

BACKGROUND/AIMS: The aim of this study was to gain more insight into the beneficial effects of mango fruit powder on the early metabolic adverse effects of a high-fat diet. METHODS: The progressive dose-response effects of mango fruit powder on body composition, circulating parameters, and the expression of genes related to fatty acid oxidation and insulin sensitivity in key tissues were studied in mice fed a moderate (45%) high-fat diet. RESULTS: Findings suggest that mango fruit powder exerts physiological protective effects in the initial steps of insulin resistance and hepatic lipid accumulation induced by a high-fat diet in mice. Moreover, AMPK and SIRT1 appear as key regulators of the observed improvement in fatty acid oxidation capacity, as well as of the improved insulin sensitivity and the increased glucose uptake and metabolism through the glycolytic pathway capacity in liver and skeletal muscle. CONCLUSION: In summary, this study provides evidence that the functional food ingredient (CarelessTM) from mango fruit prevents early metabolic alterations caused by a high-fat diet in the initial stages of the metabolic syndrome.

Effects of Mangifera indica (Careless) on Microcirculation and Glucose Metabolism in Healthy Volunteers.

A commercial Mangifera indica fruit powder (Careless) showed beneficial acute effects on microcirculation in a randomized, double-blind, crossover pilot study. Here, long-term effects on microcirculation and glucose metabolism were investigated in a double-blind, randomized, placebo-controlled, 3-arm parallel-design study in healthy individuals. A daily dose of 100 mg or 300 mg of the fruit powder was compared to placebo after supplementation for 4 weeks. Microcirculation and endothelial function were assessed by the Oxygen-to-see System and pulse amplitude tonometry, respectively. Glucose metabolism was assessed under fasting and postprandial conditions by capillary glucose and HbA1c values.Microcirculatory reactive hyperemia flow increased, especially in the 100 mg group (p = 0.025). The 300 mg of the M. indica fruit preparation reduced postprandial glucose levels by trend if compared to placebo (p = 0.0535) accompanied by significantly lower HbA1c values compared to baseline. Furthermore, 300 mg intake significantly improved postprandial endothelial function in individuals with decreased endothelial function after high-dose glucose intake (p = 0.0408; n = 11).In conclusion, the study suggests moderate beneficial effects of M. indica fruit preparation on microcirculation, endothelial function, and glucose metabolism.

Non-targeted 1H-NMR-metabolomics suggest the induction of master regulators of energy metabolism in the liver of vitamin E-deficient rats.

The essential function of vitamin E in vivo is not fully understood. Several studies addressed changes in the pattern of gene expression induced by vitamin E, but often did not investigate if these changes altered biochemical pathways and are eventually translated into biological function. We therefore used (1)H-NMR metabolomics to investigate the biochemical effects in the liver of rats caused by long-term feeding with diets deficient (dVE; α-tocopherol (αT), <1; γ-tocopherol (γT), <1; all values in mg kg(-1) diet), marginal (mVE; αT, 6; γT, 11), sufficient (sVE; αT, 12; γT, 24), or fortified with vitamin E (fVE; αT, 140; γT, 24). The concentrations of four polar hepatic metabolites were affected by the vitamin E content of the diet; glucose was lower and creatine, phosphocholine, and betaine were higher in deficient compared with rats receiving vitamin E. To achieve further biochemical insight, we investigated transcriptional changes in genes involved in the regulation of metabolic pathways related to these metabolites. Transcription of PGC1α, PPARα, and PPARγ, transcription factors controlling energy metabolism, was lower and that of the fatty acid translocase CD36 higher in animals fed vitamin E-deficient compared to those fed vitamin E-replete diets. Our data thus indicate that consumption of a vitamin E-deficient diet may alter hepatic energy metabolism in rats.