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Red Grapes (red + grape)

Distribution by Scientific Domains
Chemistry75%

Selected Abstracts

Antioxidant activities of organic grape, pomace, juice, must, wine and their correlation with phenolic content

INTERNATIONAL JOURNAL OF FOOD SCIENCE & TECHNOLOGY, Issue 2 2005
Hatice K. Y
Summary The highest values of antioxidant activity (AOA), inhibition of low-density lipoproteins (LDL-diene, LDL-MDA) and total phenols were determined in pomace (82.30 and 82.60%), grapes (68.91%) and must [2750 mg L,1 gallic acid equivalents (GAE)], respectively. For all parameters (AOA, iLDL-diene, iLDL-MDA, total phenols) the highest values were obtained in Cabernet Sauvignon and Merlot grape varieties. Positive correlations were determined between AOA and iLDL-diene (r = 0.809); AOA and total phenols (r = 0.528); total phenols and iLDL-diene (r = 0.451) with significance of P < 0.005. The results of principal component analysis demonstrated that the location of iLDL-diene and AOA is the same for pomace, must and red wines. The total phenols are found in the same place in red wines, red grapes, pomace and must. The results emphasize the importance of must, pomace and red wine for inhibiting LDL-oxidation. [source]

EFFECTS OF DIFFERENT MACERATION TIMES AND PECTOLYTIC ENZYME ADDITION ON THE ANTHOCYANIN COMPOSITION OF VITIS VINIFERA CV. KALECIK KARASI WINES

JOURNAL OF FOOD PROCESSING AND PRESERVATION, Issue 3 2009
HASIM KELEBEK
ABSTRACT Kalecik karasi is an important red grape cultivar for winemaking in Turkey. The effect of three different maceration times (3, 6 and 12 days) and addition of pectolytic enzyme (2 and 4 g/hL) on the anthocyanin and chemical composition of Kalecik karasi wines were studied. High performance liquid chromatography-mass spectrometry coupled with diode array detection was used for analysis. Fourteen anthocyanin compounds were detected in wines. Major anthocyanins in all wines are malvidin-3-glucoside and its acylated esters. The results showed that increasing maceration time, especially with addition of enzymes, gives significant increases in anthocyanin contents. Moreover, the wines treated with enzymes had higher values in total phenolics, tannins, and color intensity than the control wines. PRACTICAL APPLICATIONS Anthocyanins are the most important polyphenols in red grapes and red wines with potential health benefits. Therefore, the first analysis of the anthocyanins contents of wine obtained from important turkish cv. Kalecik karasi using liquid-chromatography-mass spectrometry and the influence of different maceration times and addition of pectolytic enzyme on these important phenolic compounds are of interest for scientific literature, the wine industry as well as for the wine consumer. [source]

Protective effect of resveratrol on markers of oxidative stress in human erythrocytes subjected to in vitro oxidative insult

PHYTOTHERAPY RESEARCH, Issue S1 2010
Kanti Bhooshan Pandey
Abstract Resveratrol is a natural polyphenolic compound found largely in the skin of red grapes. Growing evidence suggests that resveratrol may play an important role in the prevention of many human diseases. Many of the biological actions of this polyphenol have been attributed to its antioxidant properties. The present study was undertaken to evaluate the effect of resveratrol on intracellular reduced glutathione (GSH) and membrane sulphydryl groups in erythrocytes subjected to oxidative stress in vitro by incubating with t-BHP (10 µm). The study was aimed to test the efficacy of the antioxidant effect of resveratrol on human erythrocytes. Subjecting erythrocytes to oxidative stress (in vitro) by incubating them with t-BHP (10 µm) caused a significant decrease in the intracellular GSH level and membrane ,SH content compared with basal values. Incubation of erythrocytes/membranes with resveratrol (1,100 µm final conc) resulted in significant protection against the t-BHP-induced oxidative stress as evidenced by the increase in GSH level and membrane ,SH content. It was observed that the effect of resveratrol is dose/concentration and time-dependent. Since resveratrol is naturally present in many fruits and vegetables, a diet rich in resveratrol may provide protection against degenerative diseases. Copyright © 2009 John Wiley & Sons, Ltd. [source]

Molecular biology of grape berry ripening

AUSTRALIAN JOURNAL OF GRAPE AND WINE RESEARCH, Issue 2 2000
SIMON P. ROBINSON
Abstract Grapevines produce non-climacteric fruit that exhibit a double sigmoidal pattern of growth. Ripening occurs during the second growth phase when grapes change colour, start to soften, accumulate reducing sugars, metabolise organic acids and synthesise flavour compounds. Unlike many other fruit, grapes ripen while the berries are still expanding, and as with most non-climacteric fruit, ripening does not appear to be controlled by ethylene. Sugars and amino acids that accumulate in grapes during ripening are imported via the phloem, while many secondary metabolites are synthesised within the berry itself. Grapes import sucrose but accumulate hexoses. Conversion of sucrose to hexoses is most likely catalysed by invertase. cDNAs encoding vacuolar invertases have been isolated from grape berries. Expression of these genes and an increase in invertase activity occur before veraison, so it seems unlikely that synthesis of this enzyme is a controlling factor for sugar accumulation during ripening. Proteins that transport sugars into the berry vacuole may regulate sugar accumulation, and cDNAs encoding both sucrose and hexose transporters have been isolated from ripening grape berries. Determination of the role of these transporters may reveal the pathway of sugar accumulation in grapes. Anthocyanins are only synthesised in the skin of red grapes after veraison. Analysis of the patterns of expression of genes in the flavonoid pathway has shown that there is a dramatic increase in expression of many of these genes in skin cells at veraison. Expression of the gene encoding a glycosyl transferase involved in the lasts steps of anthocyanin synthesis was absolutely correlated with anthocyanin synthesis and may explain the lack of anthocyanin synthesis in white grapes and in the flesh of most red grapes. We infer that the synthesis of anthocyanins is regulated at the transcription level and is likely to be controlled by regulatory genes. Softening of fruit generally results from changes in the properties of cell walls. Analysis of the cell walls of grapes during ripening suggests that there are no dramatic changes in polysaccharide composition but modification of specific components may contribute to softening. A number of proteins are newly synthesised in grapes during ripening and several of these proteins have now been identified. The most abundant are pathogenesis-related (PR) proteins, including chitinases and thaumatin-like proteins. Expression of genes encoding a number of PR proteins increased dramatically in grapes during ripening. It is not clear what role the PR proteins play during ripening but they may provide resistance to pathogens. Differential screening of a post-veraison grape berry cDNA library has also identified ripening-related genes, some of which encode proline-rich cell wall proteins. Other grape ripening-related genes have homologues that are induced by stress in other plants. These studies indicate that a dramatic change in gene expression occurs in grape berries at veraison and suggest that ripening involves a coordinated increase in transcription of a number of different genes. [source]