Macrowine 2021
IVES 9 IVES Conference Series 9 Extraction of polyphenols from grape marc by supercritical fluid extraction (SFE) and evaluation of their ‘bioavailability’ as dietary supplements

Extraction of polyphenols from grape marc by supercritical fluid extraction (SFE) and evaluation of their ‘bioavailability’ as dietary supplements

Abstract

In the winemaking process, several compounds that remain in the grape skins and seeds after the fermentation stage are bioactive-compounds (substances with potential beneficial effects on health) that can be extracted in order to recovery valuable substances with a high commercial value for the cosmetic, food (nutraceuticals) and pharmaceutical industries. The skins contain significant amounts of bioactive substances such as tannins (16-27%) and other polyphenolic compounds (2-6.5%) in particular, catechins, anthocyanins, proanthocyanins, quercetin , ellagic acid and resveratrol. The seeds, in addition to oil, contain approximately 60% of the polyphenols present in grape, in particular an high concentration of flavan-3-ols, catechin and epicatechin. Grape seed extracts are very potent antioxidants and exhibit numerous interesting pharmacologic activities The traditional extraction methods used for polyphenols from solid or semi-solid materials have been focused on methods, which use organic solvents. These methods are laborious and time consuming, promote degradation reactions, have low selectivity and/or low extraction yields. Moreover, these conventional techniques employ large amounts of toxic solvents. Some of these critical points could be over boost with Supercritical Fluid Extraction (SFE). The most used solvent in extraction with supercritical fluids is the CO2, which is economical, safe, non-toxic (it does not leave residues in extract) and reaches supercritical conditions easily (32°C and 74 bar). It is suitable for thermo-labile substances being the temperature of its critical point 32°C. In the supercritical phase it is selective towards apolar compounds or weakly polar, so it is necessary to add co-solvents (ethanol and water are the co-solvents used in food processing) in order to extract the polar compounds. Applying this technology the thermal and chemical degradation of the products, which are completely free from processing residues, is prevented, while the solvent power and selectivity can be easily adjusted from gas-like to liquid-like by changing the pressure and temperature of the extraction, making thus possible the fractionation of the extract. SFE is a Green Technology and this guarantees competitive advantage in conjunction with sustainable development. The extraction of phenolic compounds from grape marc using supercritical CO2 containing 15% ethanol–water mixture (57%, v/v) (EtW) as co-solvent, at 8, 10, 20 and 30 MPa/313.15 K suggested 8 MPa as the most suitable pressure. The evaluation of the ‘bioavailability’ of the grape-CO2 extracts so obtained was carried out . The ‘bioavailability’ is a key step in ensuring ‘bioefficacy’ of bioactive compounds when used as supplements because they need to be bioavailable in order to exert any beneficial effects on human health.

Publication date: April 4, 2024

Issue: Macrowine 2016

Type: Poster

Authors

Carla Da Porto*, Andrea Natolino, Dario Vojnovic, Deborha Decorti

*University of Udine

Contact the author

Tags

IVES Conference Series | Macrowine | Macrowine 2016

Citation

Related articles…

The moment of preharvest elicitor application influence its final effect on winegrapes quality

Phenolic compounds are secondary metabolites of grapes. Plants produce a wide variety of this type of metabolites through diverse biosynthesis pathways and their production is sometimes a response to external stimuli, either environmental or biotic stresses. Some of them may act as chemical defenses against pathogens or herbivores and their synthesis is increased when the attack exists. However, it is remarkable that the synthesis of these interesting compounds can be activated even when the stimulus is not present, with the use of elicitors. These are substances that when applied exogenously trigger the biosynthetic pathways conducting to the synthesis of these defense compounds.

Effect of supplementation with inactive yeast during alcoholic fermentation in base wine for sparkling

INTRODUCTION: Foam stability of sparkling wines is significantly favored by the presence of surface active agents such as proteins and polysaccharides [1]. For that reason, the renowned sparkling wines are aged after the second fermentation in contact with the lees for several months (even years). Thereby wines are enriched in these macromolecules due to yeast autolysis. Since this practice is slow and costly, winemakers are seeking for alternative procedures to increase their concentration in base wines. In that sense, the supplementation with inactive yeast during alcoholic fermentation has been proposed [2]. The aim of this study was to determine whether this new strategy is really useful for enriching base wines in macromolecules and for improving foam properties of the base wines.

Sensory definition of green aroma concept in red French wines. Evidence for the contribution of novel volatile markers

The aromatic complexity of a wine results from the perception of the association of volatile molecules and each aroma can be categorized into different families. The “green” aromas family in red wines has retained our attention by its close link with the fruity perception. In that study, the “green” olfactory concept of red wines was considered through a strategy combining both sensory analysis and hyphenated chromatographic techniques including HPLC and MDGC (Multidimensional Gas Chromatography). The aromatic space of this concept was specified by lexical generation through a free association task on 22 selected wines by a panel of wine experts. Then, 70 French red wines were scored on the basis of the intensity of their “green” and “fruity” attributes.

Comparative proteomic analysis of wines made from Botrytis cinerea infected and healthy grapes reveal interesting parallels to the gushing phenomenon in sparkling wine

In addition to aroma compounds also protein composition strongly influences the quality of wines. Proteins of wine derive mainly from the plant Vitis vinifera and may be influenced by abiotic stress as well as fermentation conditions or fining. Additionally, fungal infections can affect the protein content as well by introducing fungal proteins or affecting grape protein composition. An infection of the vine with the plant pathogenic fungus Botrytis (B.) cinerea was shown to cause a degradation of proteins in the resulting wine. Moreover, it influences the foaming properties in sparkling wine.

Comparison of aroma-related compounds of carbonic maceration and traditional young red winemaking in case of Merlot by means of targeted metabolomic approach

Winemaking decisions and techniques are known to affect the final aromatic composition of red wines. Winemakers put a constant effort into the improved controlling of vinification procedures to achieve better quality. Anyway an increased customer’s demand for uniqueness is often forcing them to adjust and offer new and new interesting products. To support the producers, an improved knowledge on aromatic potential as affected by classical and alternative strategies is needed.