RED WINE EXTRACT OBTAINED BY MEMBRANE-BASED SUPERCRITICAL FLUID EXTRACTION: PRELIMINARY CHARACTERIZATION OF CHEMICAL PROPERTIES.

Silva, W.; Romero, J.; Morales, E.; Melo, R.; Mendoza, L.; Cotoras, M.

doi:10.1590/0104-6632.20170342s20150631

ABSTRACT

This study aims to obtain an extract from red wine by using membrane-based supercritical fluid extraction. This technique involves the use of porous membranes as contactors during the dense gas extraction process from liquid matrices. In this work, a Cabernet Sauvignon wine extract was obtained from supercritical fluid extraction using pressurized carbon dioxide as solvent and a hollow fiber contactor as extraction setup. The process was continuously conducted at pressures between 12 and 18 MPa and temperatures ranged from 30 to 50ºC. Meanwhile, flow rates of feed wine and supercritical CO₂ varied from 0.1 to 0.5 mL min^-1 and from 60 to 80 mL min^-1 (NCPT), respectively. From extraction assays, the highest extraction percentage value obtained from the total amount of phenolic compounds was 14% in only one extraction step at 18MPa and 35ºC. A summarized chemical characterization of the obtained extract is reported in this work; one of the main compounds in this extract could be a low molecular weight organic acid with aromatic structure and methyl and carboxyl groups. Finally, this preliminary characterization of this extract shows a remarkable ORAC value equal to 101737 ± 5324 µmol Trolox equivalents (TE) per 100 g of extract.

Keywords
Supercritical fluid extraction; wine; membrane contactor; extract; chemical characterization

INTRODUCTION

In terms of food classification, some foods and beverages are not classified as functional, but these contain active substances of natural origin and may provide the same benefits offered by functional foods like green tea, chocolate and red wine (Sarmento et al., 2008Sarmento L.A., Machado R.A., Petrus J.C., Tamanini T.R., Bolzan A., Extraction of polyphenols from cocoa seeds and concentration through polymeric membranes. Journal of Supercritical Fluids. 45, 64 - 69, (2008).).

Wines, specifically the red wines, are a rich source of different phenolic compounds, which contribute to its sensorial and antioxidant properties. Phenolic compounds have been identified as antioxidant, anti-inflammatory, neuro-sedative, anti-viral, anti-cancer and antimicrobial agents (Atanackovic et al., 2012Atanackovic M., Petrovic A., Jovic S., Gojkovic-Bukarica L., Bursac M., Cvejic T., Influence of winemaking techniques on the resveratrol content, total phenolic content and antioxidant potential of red wines. Food Chemistry. 131, 513 - 518, (2012).; Colon and Nerin, 2012Colon M., Nerin C., Role of catechins in the antioxidant capacity of an active film containing green tea, green coffee and grapefruit extracts. Journal of Agriculture Food Chemistry. 60, 9842 - 9849, (2012).) and these are synthesized during plant growth in response to stress, representing the basic components of pigments, essences and flavors. These compounds are directly related to a huge variety of applications in food technology because of their contribution to oxidative stability and organoleptic characteristics (Sánchez et al., 2012Sánchez A., Martinez - Fernández M., Chicharro M., The role of electroanalytical techniques in analysis of polyphenols in wine. Trends in Analytical Chemistry. 34, 78 - 94, (2012).). In humans, the consumption of these compounds has frequently demonstrated positive effects on health, due to their ability to modulate many homeostatic mechanisms, like lipid metabolism by controlling hepatic cholesterol absorption, triglyceride equilibrium and plasma lipoprotein processing. Furthermore, phenolic compounds may induce cardiovascular protective effects. Thanks to their antioxidant, vasodilator, anti-inflammatory, anti-fibrotic, antiapoptotic and metabolic properties, these biological properties are attributed mainly to their antioxidant and antiradical activity, which is related generally to the redox properties (Sánchez et al., 2012Sánchez A., Martinez - Fernández M., Chicharro M., The role of electroanalytical techniques in analysis of polyphenols in wine. Trends in Analytical Chemistry. 34, 78 - 94, (2012).; Quintieri et al., 2012Quintieri A.M., Baldino N., Filice E., Seta L., Vivetti A., Tota B., de Cindio B., Cerra M.C., Angelone T., Malvidin, a red wine polyphenol, modulates mammalian myocardial and coronary performance and protects the heart against ischemia/reperfusion injury. Journal of Nutritional Biochemistry, 24(7), 1221 - 1231, (2013).; Porgali and Büyüktuncel, 2011Porgali E., Büyüktuncel E., Determination of Phenolic Composition and Antioxidant Capacity of Native Red Wines by High Performance Liquid Chromatography and Spectrophotometric Methods.Food Research International. 45, 145 - 154, (2012).). At the same time, it is possible that all the properties described for red wines are due the effect of a mixture of compounds, rather than the effect of just one type of compound (Mendoza et al., 2011Mendoza L., Matsuhiro B., Aguirre M.J., Isaacs M., Sotés G., Cotoras M., Melo R., Characterization of phenolic acids profile from Chilean red wines by high - performance liquid chromatography. Journal Chemical Soc. 56, 688 - 691, (2011). ).

MEMBRANE -BASEDSUPERCRITICAL FLUID EXTRACTION TO OBTAIN WINE EXTRACTS

Chemical composition of wines

The phenolic compounds present in wines mainly derive from simple benzoic and cinnamic acids, stilbenes and flavonoids, which lead to more complex compounds formed by condensation, glycosylation and polymerization, where relevant contributions are made by tannic acids, anthocyanins, stilbene dimers, tartaric esters of cinnamic acids and proanthocyanidins and most generally could be divided into two major classes, based on their carbon structure: flavonoids and non-flavonoids. Flavonoids include anthocyanidins, flavanols, flavones and flavanones. The main non-flavonoid phenolic compounds include cinnamic acids, benzoic acids and stilbenes (Sánchez et al., 2012Sánchez A., Martinez - Fernández M., Chicharro M., The role of electroanalytical techniques in analysis of polyphenols in wine. Trends in Analytical Chemistry. 34, 78 - 94, (2012).; Granato et al., 2011Granato D., Katayama F.C.U., de Castro I.A., Phenolic composition of South American red wines classified according to their antioxidant activity, retail price and sensory quality. Food Chemistry. 129,366 - 373, (2011).). Moreover, the phenolic acids are one of the most important quality parameters of wine, and they contribute to characteristics such as astringency and bitterness (Mendoza et al., 2011Mendoza L., Matsuhiro B., Aguirre M.J., Isaacs M., Sotés G., Cotoras M., Melo R., Characterization of phenolic acids profile from Chilean red wines by high - performance liquid chromatography. Journal Chemical Soc. 56, 688 - 691, (2011). ). Furthermore, some authors report direct and rapid chromatographic protocols for identification of specific active species in red wine, grape, and winemaking byproducts (Careri et al., 2003Careri M., Corradini C., Elviri L., Nicoletti I., Zagnoni I., Direct HPLC analysis of quercetin and trans-resveratrol in red wine, grape, and winemaking byproducts. Journal of Agricultural and Food Chemistry.51, 5226-5231, (2003).; Kolouchová-Hanzlíková et al., 2004Kolouchová-Hanzlíková I., Melzoch K., Filip V., Smidrkal J., Rapid method for resveratrol determination by HPLC with electrochemical and UV detections in wines. Food Chemistry. 87, 151-158, (2004).).

On the other hand, through the supply chain of a product like red wine, we might find final products that do not meet the quality criteria, which may be a potential source for production of phenolic extracts, functional food components, healthy ingredients and additives (Boussetta et al., 2011Boussetta N., Vorobiev E., Reess T., de Ferron A., Pecastaing L., Ruscassié R., Lanoisellé J.L., Scale-up of high voltage electrical discharges for polyphenols extraction from grape pomace: Effect of the dynamic shock waves. Innovative Food Science and Emerging Technologies. 16, 129 - 136, (2011).). This extracts can be obtained by conventional and non-conventional processes.

The extraction process is a critical step in the isolation and recovery of high-added value compounds, in particular phenolic compounds (Aliakbarian et al., 2010Aliakbarian B., Casazza A.A., Montoya E.J.O., A. Convert A., Valorization of olive oil solid wastes: Valuable compounds recovery using high pressure - high temperature. Journal of Biotechnology.150, 332, (2010).). At the industrial scale, hydrodistillation or solvent extraction using methanol, ethanol, acetone or ethyl acetate, represent the traditional extraction methods for recovery of phenolic compounds from vegetable byproducts. These techniques require high volumes of organic solvents, which involve a high environmental impact (Li and Chase, 2010Li J., Chase H.A., Applications of membrane techniques for purification of natural products. Biotechnology Letters. 32, 601 - 608, (2010).; García-Abarrio et al., 2012García - Abarrio S.M., Marqués J.L., Scognamiglio M., Della Porta G., Reverchon E., Mainar A.M., Urieta J.S., Supercritical extraction and separation of antioxidants from residues of the wine industry. Procedia Engineering. 42, 1762 - 1766, (2012).).

Membrane-based supercritical fluid extraction

At present, membrane processes have been extensively applied to the recovery of valuable products (Li and Chase, 2010Li J., Chase H.A., Applications of membrane techniques for purification of natural products. Biotechnology Letters. 32, 601 - 608, (2010).), which preserve the biological activity of the compounds contained in the raw materials, since these techniques reduce the consumption of chemicals, operating generally at low temperature.

On the other hand, supercritical fluids (SCFs) are good extracting solvents, with density and viscosity close to liquids and diffusivities of species like in gases (Bocquet et al., 2007Bocquet S., Romero J., Sanchez J., Rios G.M., Membrane contactors for the extraction process with subcritical carbon dioxide or propane: Simulation of the influence of operating parameters. Journal of Supercritical Fluids .41, 246 - 256, (2007).; Oliveira et al., 2012Oliveira D.A., Salvador A.A., Smânia J.A., Smânia E.F.A., Maraschin M., Ferreira S.R.S., Antimicrobial activity and composition profile of grape (Vitisvinífera) pomace extracts obtained by supercritical fluids. Journal of Biotechnology . 164, 423 - 432, (2013). ). Carbon dioxide is a fluid widely used as supercritical solvent because of its relatively low critical point (T_c= 304.15 K and P_c = 7.28 MPa) and non-toxic character. Furthermore, after extraction it is easy to separate it from the solute of interest by means of a depressurization step.

Membrane-based supercritical fluid extraction or Porocritical extraction is a commercial supercritical fluid extraction (SFC), which uses a hollow fiber membrane contactor (HFMC). In this process a macroporous membrane allows contact between two phases, where an aqueous liquid solution is circulated on one side and on the other side the extraction solvent in a SCF (Estay et al., 2007Estay H., Bocquet S., Romero J., Sánchez J., Ríos G.M., Valenzuela F., Modeling and simulation of mass transfer in near - critical extraction using a hollow fiber membrane contactor. 62, 5794 - 5808, (2007)). However, supercritical CO₂ (scCO₂) shows affinity with lipophilic compounds and this characteristic becomes an inconvenience when polar compounds must be extracted, therefore, organic solvent (ethanol, methanol, ethyl acetate) mixtures - CO₂ under pressure have also been used to improve the extraction. Results reported by Santos and coworkers (Santos et al., 2012Santos S.A.O., Villaverde J.J., Silva C.M., Neto C.P., Silvestre A.J.D, Supercritical fluid extraction of phenolic compounds from Eucalyptus globulusLabill bark. Journal of Supercritical Fluids. 71, 71 - 79, (2012).) showed a significant performance increase of phenolic extraction when ethanol was added as cosolvent. Meanwhile, the number of species detected by HPLC-MS increased from two to sixteen with this change. In the same way, Murga et al. (2000Murga R.R., Beltran R., Cabezas J.L., Extraction of natural complex phenols and tannins from grape sedes by using supercritical mixtures of carbon dioxide and alcohol. Journal of Agricultural and Food Chemistry. 48, 3408 - 3412, (2000).) reported that low molecular weight polyphenols were better extracted with scCO₂ and 15 % of methanol.

Previous studies by Yilmaz et al. (2011Yilmaz EE, Özvural EB, Vural H, Extraction and identification of proanthocyanidins from grape seed (VitisVinifera) using supercritical carbon dioxide. Journal of Supercritical Fluids. 55, 924 - 928, (2011).) on supercritical fluid extraction (SFE) show that the most important effect on the extraction of proanthocyanidins from dry grape seed in batch mode was the amount of ethanol added as cosolvent. Moreover, a large body of literature reports different experimental procedures for extraction of phenolic compounds using supercritical fluids and cosolvents (Satyajit and Lutfun, 2012Satyajit D.S., Lutfun N. Natural Products isolation, Methods in Molecular Biology, vol. 864, DOI 10.1007/978-1-61779-624-1_3, © Springer Science + Business Media, LLC 2012.
https://doi.org/10.1007/978-1-61779-624-... ).

Ruiz-Rodriguez et al. (2010Ruiz-Rodriguez A., Fornari T., Hernández E., Señorans F., Reglero G., Thermodynamic modeling of dealcoholization of beverages using supercritical CO2: Application to wine samples. Journal of Supercritical Fluids. 52, 183 - 188, (2010).) reported the production of a functional beverage prepared from wine, which was dealcoholized, obtaining a concentration of ethanol equal to 1% (v/v), by means of supercritical fluid extraction using a packed column of 2.8 m height with a pressure of 9.5 MPa and a temperature of 313K.

To our knowledge, there is no previous research on the continuous supercritical fluid extraction of specific compounds from wine using a membrane contactor device. In this work, an extract of red wine was obtained from supercritical fluid extraction in continuous mode where the non-dispersive contact between the wine and dense carbon dioxide streams was achieved by a specially implemented hollow fiber contactor device.

This work aims to identify the main operating variables on the overall extraction performance, as well as to show a preliminary chemical characterization of the extract in terms of its potential applications.

METHODOLOGY

Materials and reagents

Chilean red wine Cabernet Sauvignon (Gran 120, Viña Santa Rita, L1309.2S) was obtained from a local market (Santiago, Chile). Meanwhile, liquid CO₂ (purity ≥ 99.0 %) was obtained from Praxair Chile. Furthermore, gallic acid C₇H₆O₅ (purity ≥ 99.0 %), sodium carbonate Na₂CO₃ (purity ≥ 99.9 %), Folin-Ciocalteu phenol reagent, deuterated chloroform (purity ≥ 99.8 %), glacial acetic acid (purity ≥ 99 %) and methanol (HPLC grade) were supplied by Merck. Acetonitrile (HPLC grade) and RMN tubes were obtained from Sigma Aldrich Chile.

Membrane-based supercritical extraction assays

The supercritical fluid extraction setup was designed and built in the Laboratory of Membrane Separation Processes, LabProSeM, at the University of Santiago de Chile. This system contains a membrane contactor, which is formed by a single PTFE fiber (GoreTeX©; porosity=60 %; ID = 1.0 mm; OD = 1.8 mm), which is housed in a stainless steel module. This hollow fiber membrane contactor separates two independent circuits, one for the wine circulated into the lumen of the fiber by means of an isocratic pump (Jasco®PU-2080) and another one for the scCO₂ stream, which was circulated through the shell side by using a ISCO® 500D syringe pump. Red wine Cabernet Sauvignon was filtered before circulation through the extraction system.

Figure 1
Setup of the continuous system for supercritical fluid extraction (Adapted from Bocquet et al., 2007)

This extraction system was operated in steady-state conditions and wine and scCO₂ streams were contacted countercurrently in the membrane contactor. Extract and raffinate samples were collected 15 min after the beginning of the operation in order to reach the steady state. Figure 1 shows the outline of the membrane-based extraction apparatus.

Preliminary experiments were carried out in order to evaluate the feasibility of phenolic extraction from Chilean red wine Cabernet Sauvignon. The operational conditions tested involved temperatures ranging from 303 to 323 K, pressure varying from 120 to 180 bar and CO₂ flow rate between 60 and 80 mL min^-1 (NCPT); meanwhile, wine flow rates ranged from 0.1 to 0.5 mL min^-1.

In order to assess the influence of the operational conditions on the extraction performance of this process, a full 3⁴ factorial design, which was distributed in 9 blocks, was previously defined.This experimental design considers the assessment of the effect of temperature, pressure, CO₂ flow rate and wine flow rate on the extraction percentage (%) and overall transmembrane phenolic flux (mol GAE h^-1 m^-2).

The coded and not-coded values of operating variables are reported in Table 1. The statistical analyses were carried out using the software Statgraphics® Centurion XV Version 15.2.05.

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Table 1
Range of select levels for the variables in continuous supercritical extraction method.

The experimental extraction percentage was estimated from the difference between the total concentration of phenolic compounds in the raw wine (in) and in the processed wine (out). This value is represented by equation 1:

E x t r a c t i o n y i e l d (%) = \frac{{[P o l y p h e n o l s]}_{i n}^{w i n e} - {[P o l y p h e n o l s]}_{o u t}^{w i n e}}{{[P o l y p h e n o l s]}_{i n}^{w i n e}} ∙ 100

(1)

Simultaneously, overall phenolic transmembrane flux transferred through the contactor was calculated from the extraction percentage value according to equation 2.

T r a n s m . f l u x (m o l G A E h^{- 1} m^{- 2}) = \frac{{[P o l y p h e n o l s]}_{i n}^{w i n e} - {[P o l y p h e n o l s]}_{o u t}^{w i n e}}{A_{i n n e r}^{m a n t l e}} ∙ \frac{Q_{f e e d}^{w i n e}}{{M . W}_{G . A c}}

(2)

where Q_feed ^wine represents the wine flow rate, MW_G.Ac is the molecular weight of gallic acid and A_inner ^mantle is the contact surface available for mass transfer into the lumen side.

Probably, the extract is not composed exclusively of phenolic compounds, but these compounds represent a good basis to quantify the efficiency to obtain a dry extract from red wine.

Chemical characterization of wine and extracts: analytical methods

Total phenolic content

The total polyphenols extraction was quantified using the Folin-Ciocalteu method (Sarmento et al., 2008Sarmento L.A., Machado R.A., Petrus J.C., Tamanini T.R., Bolzan A., Extraction of polyphenols from cocoa seeds and concentration through polymeric membranes. Journal of Supercritical Fluids. 45, 64 - 69, (2008).) at 760 nm. The concentration of phenolic compounds in was calculated using Gallic acid standard solutions between 5 and 55 µg mL^-1 and the measurement were carried out in duplicate. The result was expressed as equivalent of gallic acid (mg GAE mL^-1 red wine).

Determination of ethanol content in raw wine and raffinate

The concentration of ethanol for raw wine and raffinate obtained after extraction were quantified by HPLC. This analysis was done with an Aminex HPX-87 H column, stainless steel 300 mm x 7.8 mm. The isocratic separation was done at 323K, using 0.004 M sulfuric acid solution as mobile phase with a volumetric flow rate of 0.5 mL min^-1 and running time of 30 min.

FTIR spectrum measurement

FTIR spectroscopy (Bruker, model ALPHA) was carried out on the dry extract obtained from the expansion valve of the membrane-based supercritical extractor device described in Figure 1. After expansion through the valve, freeze-drying at pressures between 0.01 and 0.10 mbar and - 40 ºC during 24 hours was applied to dry the collected extract sample.

On the other hand, the extract samples were analyzed by Attenuated Total Reflectance (ATR) spectroscopy, scanned from 4000 to 400 cm^-1 at 4 cm^-1 and 24 scans were generated per sample. Meanwhile, the processing of the obtained spectra was done with the Software Opus V.7.

Analytical and semipreparative HPLC of extracts

Both analytical and semipreparative HPLC of extracts were carried out with a Waters 600 Chromatograph (Waters, Mildford, MA, USA), which was equipped with detector array diode Waters 2990. Analytical HPLC was achieved using a Symmetry C18 column (5 µm) 4.6 x 250 mm with 0.8 mL min^-1of mobile phase at room temperature by means of reverse phase with gradient (Table 2) at a wavelength of 300 nm. Moreover, semipreparative HPLC was implemented using a semipreparative column Waters Spherisorb S10 ODS2 10 x 250 mm isocratically operated (1400 psi) with mobile phase flow rates of 1.5 mL min^-1 and acetic acid (1%)/acetonitrile ratio equal to 40:60 at 300 nm.

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Table 2
Mobile phase gradient utilized at analytic HPLC procedure.

¹ H NMR and ¹³C analysis of extracts

The ¹H NMR spectra (400.13 Hz) and ¹³C (100.62 Hz) were recorded in CDCL₃ solvent using a Bruker Advance DRX400 spectrometer with TMS as internal standard at 30 ºC.

Antioxidant capacity ORAC assay

The procedure for ORAC assays was defined according to the method reported by Zhang et al. (2010Zhang Y., Chen J., Lei Y., Zhou Q., Sun S., Evaluation of different grades of ginseng using Fourier-transform infrared and two-dimensional infrared correlation spectroscopy Journal of Molecular Structure. 974, 144 - 150, (2010).). AAPH was used as a peroxyl radical generator, Trolox as a standard, and fluorescein as a fluorescent probe. The assays were carried out on a Victor Multilabel (Perkin Elmer, Germany) plate reader. All samples were analyzed in triplicate. The final ORAC value was calculated from the net area under the fluorescence decay curve and expressed in µmol Trolox equivalent (TE) per 100 g of sample.

RESULTS AND DISCUSSION

Extraction performance

Extraction assays were done according to the procedure described above. The extraction performance was assessed through the experimental estimation of extraction percentage and transmembrane flux of total phenolic compounds, which were estimated from equations 1 and 2, respectively. Figure 2 shows the normal probability plot for extraction yield where it can be observed that extraction experiments were correctly done according to the random distribution of these tests.

Table 3 shows the summary of the extraction efficiency and transmembrane flow (expressed in GAE, Gallic Acid Equivalent) obtained from experiments as a function of pressure, temperature, wine and scCO₂ flow rates. This table shows that the most significant effect on the extraction percentage of total phenolic compounds is the wine flow rate, followed by pressure.

Figure 2
Normal probability effects plot for extraction yield evaluated according to the proposed experimental design.

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Table 3
Values of significant effects on extraction percentage and transmembrane flux obtained under 95 % of confidence with Statgraphics Centurion XV.

Figures 3 and 4 show that the phenolic extraction yield and the transmembrane flux of phenolic compounds increase for higher operating pressures and for higher wine flow rates in the membrane contactor. The combined effect of these operational variables allows obtaining transmembrane fluxes of phenolic extract ranging from 0.007 to 0.034 (mol GAE h^-1 m^-2) and extraction yields ranging between 8.3 to 14.0 %.

Figure 4
Estimatedresponse surface of supercritical CO₂ extraction transmembrane flux from red wine Cabernet Sauvignon. T =30 ºC and Q_CO2 = 80 mL min^-1 NCPT.

A large body of literature (Ruiz-Rodriguez et al., 2010Ruiz-Rodriguez A., Fornari T., Hernández E., Señorans F., Reglero G., Thermodynamic modeling of dealcoholization of beverages using supercritical CO2: Application to wine samples. Journal of Supercritical Fluids. 52, 183 - 188, (2010).; Moncada et al., 2013Moncada J., Cardona C.A., Pisarenko Y.A., Solubility of some phenolic acids contained in citrus seeds in supercritical carbon dioxide: comparison of mixing rules, influence of multicomponent mixture and model validation. Theoretical Foundations of Chemical Engineering. 47, 381 - 387, (2013).; Choi et al., 2010; Paviani et al., 2008Paviani L.C., Dariva C., Marcucci M.C., Cabral F.A., Supercritical carbon dioxide selectivity to fractionate phenolic compounds from the dry ethanolic extract of propolis. Journal of Food Process Engineering. 33, 15 - 27, (2008).) shows the effect of the pressure on extraction performance. However, this effect could be less important in our system because the mass transfer resistance in the feed solution boundary layer (red wine circulating in the lumen side) is significantly higher. The Reynolds number in the lumen side of capillary tubes or hollow fibers is extremely low (Re < 30). Thus, the feed solution flow rate represents a more important effect on the extraction performance for this system.

Table 4 summarizes the main results reported in the literature for extracts obtained from grape pomace, seeds, stem and skin using supercritical carbon dioxide and subcritical water. In these studies, the obtained extracts contain phenolic compounds, which could show degradation at high temperature or long times of processing. In the membrane extractor system of this study the residence time in the contactor varied between 5 and 32 seconds depending on the wine flow rates.

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Table 4
Extraction processes of phenolic compounds from grape products and byproducts.

Chafer et al. (2007Chafer A., Fornari T., Stateva R., Berna A. and García - Reverter J.,Solubility of the natural antioxidant Gallic acid in supercritical CO2 + ethanol as a cosolvent. Journal of Chemical Engineering Data.52, 116 - 121 (2007).) report the increase of the solubility of gallic acid in scCO₂ when the pressure increases. The solubility of different types of compounds increases with pressure since the density of the supercritical fluid increases (Drake and Smith, 1990Drake B.D., Smith JrR.L., Measurement of static dielectric constants of supercritical fluid solvents and cosolvents: Carbon dioxide and argon, carbon dioxide, and methanol at 323 K and pressures to 25 MPa. Journal of Supercritical Fluids.3, 162 - 168, (1990).). Moreover, the natural presence of ethanol in red wine could improve the extractability of phenolic compounds in this case. The concentration of ethanol was measured before and after the supercritical extraction assays in the raw wine and raffinate, respectively, observing a decrease from 13.2 ± 0.5 % v/v to 12.6 ± 0.12 % v/v because of this processing. This slight decrease could involve a modification in the extractability of different types of compounds present in wine at low concentrations.

Figure 5
Estimate response surface of scCO₂ extraction yield from red wine Cabernet Sauvignon. P = 180 bar and Q_wine = 0.5 mL min^-1.

On the other hand, the effect of the temperature on the extraction performance changes depending on the pressure or scCO₂ flow rate levels. Temperature can modify the density of pressurized CO₂ used as solvent as well as the transport properties through the membrane and boundary layers. This fact could explain the results reported in Figure 5 where the increase of temperature has a negative effect on the extraction yield at low scCO₂ flow rates and this effect is reversed at the highest level of scCO₂ flow rate.

The desirability function was calculated for optimization of the operating variables in the intervals studied in this work (Vera et al., 2014Vera Candioti L., de Zan M.M., Cámara M.S., Goicoechea H.C., Experimental design and multiple response optimization. Using the desirability function in analytical methods development. Talanta. 124, 123 - 138, (2014).). Thus, the experimental responses -extraction percentage and transmembrane flux of phenolic compounds - are maximized in terms of the operating variables as a one objective function. Figure 6 shows the result obtained from this optimization where the optimum desirability value is equal to 0.76 for the lowest and highest values of temperature and pressure, respectively. Furthermore, the values of the factor levels that allow obtaining the maximum of the desirability function are summarized in Table 5.

Previously, the results reported in Table 3 showed that the highest value of extraction percentage reached 14 % when the wine flow rate, CO₂ flow rate, pressure and temperature were 0.5 mL min^-1, 80 mL min^-1 NCPT, 17 MPa and 35 ºC, respectively. The statistical analysis reported in Table 5 and Figure 6 validates this result.

Figure 6
Estimated response surface of desirability for scCO₂ extraction of compounds from red wine Cabernet Sauvignon. Q_wine = 0.5 mL min^-1 and Q_CO2 = 70 mL min^-1 NCPT.

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Table 5
Values of factor levels to obtain the maximum of the desirability function.

Under the best operating condition tested in this work, 20.6 ± 1.13 mg of dry extract and 86.7 ± 2.1 mg GAE were collected per liter of processed red wine. This condition involves a residence time of wine in the extractor equal to 32 seconds with a consumption of 0.538 kg of CO₂, which can be considered low if compared with values reported by studies summarized in Table 4.

Figure 7
Dimensionless Sherwood number as a function of Reynolds number. T = 35 ºC; P = 180 bar. Correlation for shell and lumen sides (Bocquet et al., 2007)

On the other hand, the highest transmembrane flux of total phenolic compounds obtained from a single extraction step was 0.034(mol GAE h^-1 m^-2) under the optimized conditions. This behavior is in agreement with the increase of the Reynolds number (Hoff et al., 2014Hoff K.A., Svendsen H.F., Membrane contactors for CO2 absorption - Application, modeling and mass transfer effects. Chemical Engineering Science. 116, 331 - 341, (2014).) in the lumen side where the wine was circulated. Figure 7 shows the change of the dimensionless Sherwood number as a function of the Reynolds number (Re) in the lumen and in the shell side of the contactor. It is possible to observe a relatively significant change of the Sherwood number in function of the Re in both sides of the membrane contactor. Thus, the effect of the wine and scCO₂ flow rates on the extraction percentages can be understood.

Chemical characterization of wine extracts

Figure 8 shows the FTIR spectra, where it is possible to see the C-H stretching vibration for methyl and methylene groups, being the characteristic bands related to the main compounds in the dry extract with at least one aliphatic fragment (Coates, 2000Coates J., Interpretation of infrared spectra, a practical approach. Encyclopedia of Analytical Chemistry.Chichester, England: Meyers, (2000).) and potential presence of functional groups like alkanes, aromatics, ether, carboxylic acid, aldehydes or ketones.

Figure 8
FTIR spectrum of the dry extract obtained from red wine Cabernet Sauvignon by means of membrane-based supercritical extraction under the best process conditions.

Generally, bands of phenolic compounds found in grapes can be observed in the region between 900 and 1680 cm^-1. The bands in the range 1520 - 1600 cm^-1 might be attributed to vibrations of C=C bonds, typical of aromatic systems (Coates, 2000Coates J., Interpretation of infrared spectra, a practical approach. Encyclopedia of Analytical Chemistry.Chichester, England: Meyers, (2000).). The C-O bonds show peaks in the range 1060 - 1150 cm^-1, indicating the presence in the extract of an organic acid component (Edelman et al., 2001Edelmann, A., Diewok, J., Schuster, K.C., Lendl, B., Rapid method for the discrimination of red wine cultivars based onmid-infrared spectroscopy of phenolic wine extracts. Journal of Agricultural Food Chemistry. 49, 1139 - 1145, (2001).). The absorption band at 1750 cm^-1 is attributable to the stretching vibration of a C=O group in esterified carboxyl to methyl or protonated carboxylic acid O=C-O-H (Manrique and Lajolo, 2002Manrique G.D., Lajolo F.M., FT-IR spectroscopy as a tool for measuring degree of methyl esterification in pectins isolated from ripening papaya fruit. Postharvest Biology and Technology. 25, 99 - 107, (2002).). The presence of absorption bands in the interval 1420 - 1620 cm^-1 is attributable to absorbance of deprotonated COO^- groups (Boulet et al., 2007Boulet J.C., Williams P., Doco T., A Fourier transform infrared spectroscopy study of wine polysaccharides. Carbohydrate Polymers. 69, 79 - 85, (2007).). Peaks in the region 1407-1618 cm^-1 correspond to symmetric and asymmetric stretching for carboxyl ion (COO^-), indicating the presence of a carboxylic acid, ester or carbonyl group according to the information reported by other studies (Zhang et al., 2010Zhang Y., Chen J., Lei Y., Zhou Q., Sun S., Evaluation of different grades of ginseng using Fourier-transform infrared and two-dimensional infrared correlation spectroscopy Journal of Molecular Structure. 974, 144 - 150, (2010).). Thus, the change from carboxylic acid to salt could be a confirmation of acid structure, and logically the O-H stretching band disappears.

From the gradient HPLC analysis done on dry extract, it is possible to see only two peaks (Figure 9).

Figure 9
High performance liquid chromatography for dry solid extract obtained from red wine Cabernet Sauvignon using as mobile phase a solution of acetic acid 1 % in methanol under isocratic configuration 1.5 mL min^-1 and 300 nm.

Visualizing the spectra obtained for the two separated compounds, it is seen that the component with the lowest retention time shows an absorption peak at 259 nm. However, the other compound showed two absorbance peaks at 228.4 and 311.1 nm. These values suggest the phenolic nature of one or both components according to the absorption range obtained (de Villiers et al., 2010De Villiers, A., Kalili, K.M., Malan, M., Roodman, J. ,Improving HPLC separation of polyphenols. LCGC Europe. 23, 466 - 478, (2010).).

The results of thermal analysis (DSC) show two endothermic peaks. Both peaks might represent one or two compounds present in the solid extract, showing that it does not represent a second order phase transition. Increasing the temperature, the first peak corresponds to the mean melting point temperature 124.42 ºC and it involves an absolute latent heat of 62.57 J g^-1, presenting a base width lower than the second peak. The width of the peak is associated with the change of size distribution of the structure from crystalline state to a disordered liquid state. The second peak presents a mean temperature of 248.4 ºC, which could denote a thermal resistance of the compound; this resistance might be attributed to the presence of aromatic rings. Masoud et al. (2012Masoud M.S., Hagagg S.S., Ali A.E., Nasr N.M., Synthesis and spectroscopic characterization of Gallic acid and some of its azo complexes. Journal of Molecular Structure. 1014, 17 - 25, (2012).) obtained an identical result for gallic acid, which presented two endothermic peaks, at 124.5 ºC and 267.6 ºC in DTA analysis. Furthermore, benzoic acid shows two endothermic peaks, around 122.4 ºC and 250 ºC for melting point and boiling point, respectively, according to calibration standard DSC LGC2606.

The ¹³C Nuclear Magnetic Resonance (NMR) spectrum of extract is reported in Figure 10 where it can be seen chemical shifts of δ = 172.63; 147.47; 140.91; 129.84; 118.23; 18.85 ppm, which could establish the presence of a carbonyl group with a displacement to lower field around δ = 172.63 ppm attributable to the presence of carbon in a O-COCH₃ group (Topcu and Ulubelen, 2007Topcu G., Ulubelen A., Structure elucidation of organic compounds from natural sources using 1D and 2D NMR techniques. Journal of Molecular Structure. 834, 57 - 73, (2007)).

At higher field values, the carbon nuclei belong to aliphatic chains. Nevertheless, the peak at δ = 18.85 ppm could be related to CH₂ or CH₃ groups. The distribution of those types of carbon in the structure involves the presence of an aromatic ring structure because of the presence of the other 4 peaks above chemical displacement δ = 110 ppm and at least 1 type of carbon associated with a CH₃ group. Furthermore, at low field (δ < 40 ppm) in the level of the noise, there are peaks that could be associated with linear aliphatic structures of other components extracted from the red wine with supercritical CO₂. The compounds would represent a minor fraction of the whole extract.

Figure 10
NMR spectrum ¹³C (0 - 180 ppm) and ¹H (0 - 8 ppm) of the dry solid extract obtained from red wine Cabernet Sauvignon by means of membrane-based supercritical extraction under the best condition of extraction at 30 ºC using CDCl₃ as deuterated solvent.

The ¹H NMR spectrum reported in Figure 10 shows nuclei in aromatic, olefinic and alkyl regions. Moreover, its complexity makes it difficult to identify individual organic species in the absence of authenticated standard and/or reference NMR spectra. The spectrum obtained from this analysis showsaromatic regions with intensity lower than observed in the aliphatic region, showing chemical displacement values δ = 7.32 - 7.37 ppm for a doublet of doublets integrating as 4 hydrogens, which might correspond to an aromatic substituted compound bonded to an electron withdrawing aliphatic chain. Those peaks appearing at chemical shifts 6.23 ppm as a singlet and 6.21 ppm as a triplet with coupling constant J = 3.1 Hz are associated with hydrogens present in aromatic rings and/or carbons linked to double bonds. Furthermore, peaks around 5.75 - 5.79 ppm allow establishing the coupling constant J = 15.4 Hz for a doublet with configuration trans between neighboring hydrogens or the presence of negative elements in its composition.

From the ensemble of these results, the most probable structure of the main molecules that constitutes the dry red wine extract obtained by membrane-based supercritical fluid extraction could be mainly two compounds of intermediate polarities and low molecular weight. The principal compound could correspond to an acid with aromatic structure and the presence of methyl and carboxyl functional groups in the structure.

Antioxidant Capacity ORAC

The antioxidant capacity quantification of the obtained red wine extract was by means of the ORAC method. The curve of ORAC assay reported in Figure 11 shows two curves of fluorescein decaying at dilution factors 100x and 60x for the solid extract in phosphate buffer, where the lag time decreased when the sample was diluted. It is possible to verify a significant antioxidant capacity and lag time of around 2000 seconds.

Figure 11
ORAC curves for antioxidant capacity of lyophilized extract obtained by means of membrane-based supercritical extraction from red wine Cabernet Sauvignon under the best operational conditions.

The antioxidant capacity of red wine extract is shown in Table 6 and equal to 101737 ± 5324 µmol TE per 100 g of lyophilized extract. This value is equivalent to the antioxidant activity of Açai fruit pulp/skin powder (ORAC value of 102700 µmol TE per 100 g) but is lower than spices such as cinnamon, rosemary, oregano and cloves among others reported in Table 7, which shows a value range varying from 131420 to 290283 µmol TE per 100 g of sample (USDA, 2010). Thus, the extract obtained from red wine Cabernet Sauvignon by membrane-based supercritical CO₂ extraction could be among the 12 food products with higher antioxidant capacities reported in the ORAC database of the USDA (2010). Furthermore, the ORAC value of this extract is around ten times lower than BHA, which represents a commercial artificial antioxidant.

Thumbnail

Table 6
Equivalences for ORAC values of extract obtained from red wine Cabernet Sauvignon by means of membrane-based supercritical extraction.

Thumbnail

Table 7
Antioxidant capacity of substances and food products evaluated by the ORAC method.

Furthermore, the red wine extract obtained in this work shows ORAC values between 24 - 40 times higher than wines and 1.3-7.0 times higher than the fruits mentioned above, respectively. Meanwhile, for pure substances such as Zeaxanthin, gallic acid and ascorbic acid, the ORAC values ranged from 9.8-272 times lower than the ORAC value obtained in this work.

Chemical characterization of the extract described above involves the identification of a mixture with at least two main compounds. These compounds seem to show a synergic antioxidant action. Nevertheless, it is necessary to emphasize that the ORAC assay is a simplified technique that reduces the complex antioxidant mechanism to a reaction between the radicals produced by AAPH and the analyzed antioxidant. The combined effect of a mixture of antioxidants on different paths of the food oxidation processes effectively acts in a synergistic way, providing extra protection higher than the addition of the effects of the single antioxidant components (Bentayeb et al., 2014Bentayeb K., Vera P., Rubio C., Nerín C., The additive properties of Oxygen Radical Absorbance Capacity (ORAC) assay: the case of essential oils. Food Chemistry. 148, 204 - 208, (2014).). However, red wine polyphenols have different physiological properties, which depend on the composition of the extracts (Zoechling et al., 2011Zoechling A., Liebner F, Jungbauer A., Red wine: a source of potent ligands for peroxisome proliferator-activated receptor γ. Food & Function. 2(1), 28-38, (2011).). Thus, redox values become only a surrogate parameter and further investigation is necessary for the detailed characterization of the extract composition.

CONCLUSIONS

In this work, the membrane-based supercritical fluid extraction process was used to obtain an extract directly from Cabernet Sauvignon wine. During the extraction runs implemented in a single PTFE fiber contactor, a permanent stability of the extraction system it was observed, as well as reproducible measurements.

The continuous extraction system with supercritical CO₂ coupled to a membrane contactor allowed the extraction of organic compounds from red wine Cabernet Sauvignon, as well as evidenced the great mechanical stability presented by membrane fiber.

The process of this extraction gave a maximum dry extract yield of 20.6 mg per L of red wine processed in only one extraction step in steady-state conditions when the wine flow rate, CO₂ flow rate, pressure and temperature were 0.5 mL min^-1, 80 mL min^-1 NCPT, 17 MPa and 35 ºC, respectively. Furthermore, the extraction yield as a function of supercritical CO₂ consumption was 40.9 mg per kg of CO₂.

From the chemical characterization of the dry extract, the most probable structure of the main molecules extracted by membrane-based supercritical fluid extraction could be associated with an acid with aromatic structure and the presence of methyl and carboxyl functional groups.

The extract obtained under the best operational condition showed an antioxidant activity equivalent to 101737± 5324 µmol TE per 100 g of lyophilized extract. This value was obtained by the ORAC method and is higher than those obtained for other raw food materials like fruits, chocolate, green tea leaves and red wine Cabernet Sauvignon itself. This ORAC - FL value of extracts allows positioning among food compounds with a significant antioxidant capacity for its use in food formulations or in mixtures with other compounds with synergic action. Nevertheless, further investigation is required to know the detailed chemical composition of these extracts.

ACKNOWLEDGEMENTS

This study has been developed in the framework of the research projects FONDECYT 1140208 and FONDECYT 1130389, granted by CONICYT Chile, and RC-130006-CILIS granted by Fondo de Innovación para la Competitividad, del Ministerio de Economía, Fomento y Turismo, Chile. The Doctoral Scholarship Program of CONICYT Chile supported Wladimir Silva Vera.

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Bocquet S., Romero J., Sanchez J., Rios G.M., Membrane contactors for the extraction process with subcritical carbon dioxide or propane: Simulation of the influence of operating parameters. Journal of Supercritical Fluids .41, 246 - 256, (2007).
Boulet J.C., Williams P., Doco T., A Fourier transform infrared spectroscopy study of wine polysaccharides. Carbohydrate Polymers. 69, 79 - 85, (2007).
Boussetta N., Vorobiev E., Reess T., de Ferron A., Pecastaing L., Ruscassié R., Lanoisellé J.L., Scale-up of high voltage electrical discharges for polyphenols extraction from grape pomace: Effect of the dynamic shock waves. Innovative Food Science and Emerging Technologies. 16, 129 - 136, (2011).
Careri M., Corradini C., Elviri L., Nicoletti I., Zagnoni I., Direct HPLC analysis of quercetin and trans-resveratrol in red wine, grape, and winemaking byproducts. Journal of Agricultural and Food Chemistry.51, 5226-5231, (2003).
Chafer A., Fornari T., Stateva R., Berna A. and García - Reverter J.,Solubility of the natural antioxidant Gallic acid in supercritical CO₂ + ethanol as a cosolvent. Journal of Chemical Engineering Data.52, 116 - 121 (2007).
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Granato D., Katayama F.C.U., de Castro I.A., Phenolic composition of South American red wines classified according to their antioxidant activity, retail price and sensory quality. Food Chemistry. 129,366 - 373, (2011).
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Manrique G.D., Lajolo F.M., FT-IR spectroscopy as a tool for measuring degree of methyl esterification in pectins isolated from ripening papaya fruit. Postharvest Biology and Technology. 25, 99 - 107, (2002).
Masoud M.S., Hagagg S.S., Ali A.E., Nasr N.M., Synthesis and spectroscopic characterization of Gallic acid and some of its azo complexes. Journal of Molecular Structure. 1014, 17 - 25, (2012).
Mathkar S., Kumar S., Bystol A., Olawoore K., Min D., Markovich R., Rustum A., The use of differential scanning calorimetry for the purity verification of pharmaceutical reference standards. Journal of Pharmaceutical and Biochemical Analysis. 627 - 631, (2009).
Meireles M.A., Prado J.M., Dalmolin I., Carareto N., Basso R., Meirelles A., Oliveira J.V., Batista E., Supercritical fluid extraction of grape seed: Process scale-up, extract chemical composition and economic evaluation. Journal of Food Engineering. 109, 249 - 257, (2012).
Mendoza L., Matsuhiro B., Aguirre M.J., Isaacs M., Sotés G., Cotoras M., Melo R., Characterization of phenolic acids profile from Chilean red wines by high - performance liquid chromatography. Journal Chemical Soc. 56, 688 - 691, (2011).
Moncada J., Cardona C.A., Pisarenko Y.A., Solubility of some phenolic acids contained in citrus seeds in supercritical carbon dioxide: comparison of mixing rules, influence of multicomponent mixture and model validation. Theoretical Foundations of Chemical Engineering. 47, 381 - 387, (2013).
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Ruiz-Rodriguez A., Fornari T., Hernández E., Señorans F., Reglero G., Thermodynamic modeling of dealcoholization of beverages using supercritical CO₂: Application to wine samples. Journal of Supercritical Fluids. 52, 183 - 188, (2010).
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Publication Dates

Publication in this collection
Apr 2017

History

Received
07 Oct 2015
Reviewed
21 Dec 2015
Accepted
24 Jan 2016

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Aliakbarian B., Casazza A.A., Montoya E.J.O., A. Convert A., Valorization of olive oil solid wastes: Valuable compounds recovery using high pressure - high temperature. Journal of Biotechnology.150, 332, (2010).

[2] Aliakbarian B., Fathi A., Perego P., Dehghani F., Extraction of antioxidants from winery wastes using subcritical water. Journal of Supercritical Fluids. 65, 18 - 24, (2012).

[3] Atanackovic M., Petrovic A., Jovic S., Gojkovic-Bukarica L., Bursac M., Cvejic T., Influence of winemaking techniques on the resveratrol content, total phenolic content and antioxidant potential of red wines. Food Chemistry. 131, 513 - 518, (2012).

[4] Bentayeb K., Vera P., Rubio C., Nerín C., The additive properties of Oxygen Radical Absorbance Capacity (ORAC) assay: the case of essential oils. Food Chemistry. 148, 204 - 208, (2014).

[5] Bocquet S., Romero J., Sanchez J., Rios G.M., Membrane contactors for the extraction process with subcritical carbon dioxide or propane: Simulation of the influence of operating parameters. Journal of Supercritical Fluids .41, 246 - 256, (2007).

[6] Boulet J.C., Williams P., Doco T., A Fourier transform infrared spectroscopy study of wine polysaccharides. Carbohydrate Polymers. 69, 79 - 85, (2007).

[7] Boussetta N., Vorobiev E., Reess T., de Ferron A., Pecastaing L., Ruscassié R., Lanoisellé J.L., Scale-up of high voltage electrical discharges for polyphenols extraction from grape pomace: Effect of the dynamic shock waves. Innovative Food Science and Emerging Technologies. 16, 129 - 136, (2011).

[8] Careri M., Corradini C., Elviri L., Nicoletti I., Zagnoni I., Direct HPLC analysis of quercetin and trans-resveratrol in red wine, grape, and winemaking byproducts. Journal of Agricultural and Food Chemistry.51, 5226-5231, (2003).

[9] Chafer A., Fornari T., Stateva R., Berna A. and García - Reverter J.,Solubility of the natural antioxidant Gallic acid in supercritical CO₂ + ethanol as a cosolvent. Journal of Chemical Engineering Data.52, 116 - 121 (2007).

[10] Coates J., Interpretation of infrared spectra, a practical approach. Encyclopedia of Analytical Chemistry.Chichester, England: Meyers, (2000).

[11] Colon M., Nerin C., Role of catechins in the antioxidant capacity of an active film containing green tea, green coffee and grapefruit extracts. Journal of Agriculture Food Chemistry. 60, 9842 - 9849, (2012).

[12] De Villiers, A., Kalili, K.M., Malan, M., Roodman, J. ,Improving HPLC separation of polyphenols. LCGC Europe. 23, 466 - 478, (2010).

[13] Drake B.D., Smith JrR.L., Measurement of static dielectric constants of supercritical fluid solvents and cosolvents: Carbon dioxide and argon, carbon dioxide, and methanol at 323 K and pressures to 25 MPa. Journal of Supercritical Fluids.3, 162 - 168, (1990).

[14] Edelmann, A., Diewok, J., Schuster, K.C., Lendl, B., Rapid method for the discrimination of red wine cultivars based onmid-infrared spectroscopy of phenolic wine extracts. Journal of Agricultural Food Chemistry. 49, 1139 - 1145, (2001).

[15] EFSA Panel on Food Additives and Nutrient Sources added to Food. EFSA Journal. 49, (2011).

[16] Estay H., Bocquet S., Romero J., Sánchez J., Ríos G.M., Valenzuela F., Modeling and simulation of mass transfer in near - critical extraction using a hollow fiber membrane contactor. 62, 5794 - 5808, (2007)

[17] Fragoso S., Aceña L., Guasch J., Busto O., Mestres M., Application of FT-MIR spectroscopy for fast control of red grape phenolic ripening. Journal of Agricultural Food Chemistry. 59, 2175 - 2183, (2011).

[18] García - Abarrio S.M., Marqués J.L., Scognamiglio M., Della Porta G., Reverchon E., Mainar A.M., Urieta J.S., Supercritical extraction and separation of antioxidants from residues of the wine industry. Procedia Engineering. 42, 1762 - 1766, (2012).

[19] García-Marino M., Rivas-Gonzalo J.C., Ibáñez E., García-Moreno C., Recovery of catechins and proanthocyanidins from winery by-products using subcritical wáter extraction. Analytica Chimica Acta. 563, 44 - 50, (2006).

[20] Ghaffor K., Park J., Choi Y.H., Optimization of supercritical fluid extraction of bioactive compounds from grape (Vitislabrusca B.) peel by using response surface methodology. Innovative Food Science and Emerging Technologies 11, 485 - 490, (2010).

[21] Granato D., Katayama F.C.U., de Castro I.A., Phenolic composition of South American red wines classified according to their antioxidant activity, retail price and sensory quality. Food Chemistry. 129,366 - 373, (2011).

[22] Haytowitz D.B, Bhagwat S., USDA database for the oxygen radical absorbance capacity ORAC of selected food, Release 2, U.S. Department of Agriculture, Agricultural Research Service. 12 - 41 (2010).

[23] Hoff K.A., Svendsen H.F., Membrane contactors for CO₂ absorption - Application, modeling and mass transfer effects. Chemical Engineering Science. 116, 331 - 341, (2014).

[24] Kolouchová-Hanzlíková I., Melzoch K., Filip V., Smidrkal J., Rapid method for resveratrol determination by HPLC with electrochemical and UV detections in wines. Food Chemistry. 87, 151-158, (2004).

[25] Li J., Chase H.A., Applications of membrane techniques for purification of natural products. Biotechnology Letters. 32, 601 - 608, (2010).

[26] Manrique G.D., Lajolo F.M., FT-IR spectroscopy as a tool for measuring degree of methyl esterification in pectins isolated from ripening papaya fruit. Postharvest Biology and Technology. 25, 99 - 107, (2002).

[27] Masoud M.S., Hagagg S.S., Ali A.E., Nasr N.M., Synthesis and spectroscopic characterization of Gallic acid and some of its azo complexes. Journal of Molecular Structure. 1014, 17 - 25, (2012).

[28] Mathkar S., Kumar S., Bystol A., Olawoore K., Min D., Markovich R., Rustum A., The use of differential scanning calorimetry for the purity verification of pharmaceutical reference standards. Journal of Pharmaceutical and Biochemical Analysis. 627 - 631, (2009).

[29] Meireles M.A., Prado J.M., Dalmolin I., Carareto N., Basso R., Meirelles A., Oliveira J.V., Batista E., Supercritical fluid extraction of grape seed: Process scale-up, extract chemical composition and economic evaluation. Journal of Food Engineering. 109, 249 - 257, (2012).

[30] Mendoza L., Matsuhiro B., Aguirre M.J., Isaacs M., Sotés G., Cotoras M., Melo R., Characterization of phenolic acids profile from Chilean red wines by high - performance liquid chromatography. Journal Chemical Soc. 56, 688 - 691, (2011).

[31] Moncada J., Cardona C.A., Pisarenko Y.A., Solubility of some phenolic acids contained in citrus seeds in supercritical carbon dioxide: comparison of mixing rules, influence of multicomponent mixture and model validation. Theoretical Foundations of Chemical Engineering. 47, 381 - 387, (2013).

[32] Murga R.R., Beltran R., Cabezas J.L., Extraction of natural complex phenols and tannins from grape sedes by using supercritical mixtures of carbon dioxide and alcohol. Journal of Agricultural and Food Chemistry. 48, 3408 - 3412, (2000).

[33] Oliveira D.A., Salvador A.A., Smânia J.A., Smânia E.F.A., Maraschin M., Ferreira S.R.S., Antimicrobial activity and composition profile of grape (Vitisvinífera) pomace extracts obtained by supercritical fluids. Journal of Biotechnology . 164, 423 - 432, (2013).

[34] Paviani L.C., Dariva C., Marcucci M.C., Cabral F.A., Supercritical carbon dioxide selectivity to fractionate phenolic compounds from the dry ethanolic extract of propolis. Journal of Food Process Engineering. 33, 15 - 27, (2008).

[35] Porgali E., Büyüktuncel E., Determination of Phenolic Composition and Antioxidant Capacity of Native Red Wines by High Performance Liquid Chromatography and Spectrophotometric Methods.Food Research International. 45, 145 - 154, (2012).

[36] Quintieri A.M., Baldino N., Filice E., Seta L., Vivetti A., Tota B., de Cindio B., Cerra M.C., Angelone T., Malvidin, a red wine polyphenol, modulates mammalian myocardial and coronary performance and protects the heart against ischemia/reperfusion injury. Journal of Nutritional Biochemistry, 24(7), 1221 - 1231, (2013).

[37] Ruiz-Rodriguez A., Fornari T., Hernández E., Señorans F., Reglero G., Thermodynamic modeling of dealcoholization of beverages using supercritical CO₂: Application to wine samples. Journal of Supercritical Fluids. 52, 183 - 188, (2010).

[38] Sánchez A., Martinez - Fernández M., Chicharro M., The role of electroanalytical techniques in analysis of polyphenols in wine. Trends in Analytical Chemistry. 34, 78 - 94, (2012).

[39] Santos S.A.O., Villaverde J.J., Silva C.M., Neto C.P., Silvestre A.J.D, Supercritical fluid extraction of phenolic compounds from Eucalyptus globulusLabill bark. Journal of Supercritical Fluids. 71, 71 - 79, (2012).

[40] Sarmento L.A., Machado R.A., Petrus J.C., Tamanini T.R., Bolzan A., Extraction of polyphenols from cocoa seeds and concentration through polymeric membranes. Journal of Supercritical Fluids. 45, 64 - 69, (2008).

[41] Satyajit D.S., Lutfun N. Natural Products isolation, Methods in Molecular Biology, vol. 864, DOI 10.1007/978-1-61779-624-1_3, © Springer Science + Business Media, LLC 2012.
» https://doi.org/10.1007/978-1-61779-624-1_3

[42] Topcu G., Ulubelen A., Structure elucidation of organic compounds from natural sources using 1D and 2D NMR techniques. Journal of Molecular Structure. 834, 57 - 73, (2007)

[43] Vera Candioti L., de Zan M.M., Cámara M.S., Goicoechea H.C., Experimental design and multiple response optimization. Using the desirability function in analytical methods development. Talanta. 124, 123 - 138, (2014).

[44] Yilmaz EE, Özvural EB, Vural H, Extraction and identification of proanthocyanidins from grape seed (VitisVinifera) using supercritical carbon dioxide. Journal of Supercritical Fluids. 55, 924 - 928, (2011).

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Effects	Extraction percentage (%)				Transmembrane flux (molGAE h^-1 m^-2 )
	Estimated (± 3.0596)	Optimum level	Magnitude	Value (%)	Estimated (± 0.0035518)	Optimum level	Magnitude	Value (mol h^-1 m^-2 )
13.99	0.034
		Temperature (ºC)	-0.4053	-0.5	35	-0.0004220	34.4	34.4
		Pressure (bar)	1.7059	0.7	170	0.0030090	178	178
		Red wine flow (mLmin^-1)	3.4962	1	0.5	0.0242481	0.5	0.5
CO₂ SC flow (mL min^-1)	3.1773	80	80	0.0055239	75	75

Matrix	Solvent	Operational conditions	Extraction Yield	Ref.
Grape pomace	Subcritical water	Batch system; 11.6 MPa - 140 °C.	Phenolic compounds/31.69 mg GAE g^-1 db.	Aliakbarian B. et al. 2012
Grape seed	Subcritical water	Batch system; 1500 psig- 150 °C.	Catechins and Proanthocyanidins/ 70% db.	García-Marino et al. 2006
Grape seed	Supercritical CO₂	Batch system; 250-300 bar; 2 - 5% ethanol	Complex phenols and tannins/ less [EtOH] and pressure ( less [Polyphenols]	Murga et al. 2000
Grape seed		Batch system; 35 MPa - 313 K.	13.42 % of extraction yield db at 430 min.	Meireles et al. 2012
Grape seed		Batch system; 250-300 bar; 30-50 °C; 15-20 % ethanol	Gallic acid 2.6 - 32.9 mg kg^-1 db. Catechins 5.8 - 78.83 mg kg^-1 db. Epicatechins 4.8 - 35.15 mg kg^-1 db.	Yilmaz et al. 2011
Seed, stem, skin and grape pomace		Batch system, 400 bar; 308 K; 5 % v/v ethanol	Resveratrol with extraction yield between 15 and 21 times greater than conventional methods.	Goli, Barzegar and Sahari 2005

Substance/Food	ORAC value	Unit	Source
Ascorbic Acid	40.4 ± 2.1	µM TE	Zulueta et al. (2009)
Gallic Acid	161 ± 4.8	µM TE
β - carotene	582 ± 30.3	µM TE
Zeaxanthin	1108 ± 5.9	µM TE
BHA (Butylated Hydroxy anisole)	13500 ± 332	µmol TE g^-1	Dávalos et al. (2004)
Squalene	304.3	µmol TE g^-1	Kraujalis and Venskutonis (2013)
Cinnamon, ground	131420 ± 13867	µmol TE/100g^-1	Haytowitz and Bhagwat (2010)
Rosemary, dried	165280 ± 1319	µmol TE/100g^-1
Oregano, dried	175295 ± 7683	µmol TE/100g^-1
Cloves, ground	290283 ± 3292	µmol TE/100g^-1
Red wine Cabernet Sauvignon
Santa Tierra (Chile)	28.064 ± 2.073	µmol TE mL^-1	Van Leew et al. (2014)
Casillero del Diablo (Chile)	42.669 ± 1,14	µmol TE mL^-1
Sunrise (Chile)	25.773 ± 1.493	µmol TE mL^-1
Chocolate, Dark
Black & Green´s Organic	118.9	µM TEg^-1	Stockham et al. (2011)
Lindt, 70 %	171.8	µM TE g^-1
Lindt, 90 %	290.0	µM TE g^-1
Fruits
Strawberry	154	µmol TEg^-1	Yilmaz et al. (2006)
Plum	80	µmol TE g^-1
Red Grape	36	µmol TE g^-1
Orange	52	µmol TE g^-1
Blueberries	63 - 282	µmol TE g^-1
Blackberries	8650 ± 200	µM TE	Atala et al. (2009)
Raspberry	2870 ± 700	µM TE	Atala et al. (2009)
Tomato dry	222.3 ± 285.61	µmol TE g^-1	Li et al. (2012)

Brasil

Brasil

RED WINE EXTRACT OBTAINED BY MEMBRANE-BASED SUPERCRITICAL FLUID EXTRACTION: PRELIMINARY CHARACTERIZATION OF CHEMICAL PROPERTIES.

ABSTRACT

INTRODUCTION

MEMBRANE -BASEDSUPERCRITICAL FLUID EXTRACTION TO OBTAIN WINE EXTRACTS

Chemical composition of wines

Membrane-based supercritical fluid extraction

METHODOLOGY

Materials and reagents

Membrane-based supercritical extraction assays

Chemical characterization of wine and extracts: analytical methods

Analytical and semipreparative HPLC of extracts

¹ H NMR and ¹³C analysis of extracts

Antioxidant capacity ORAC assay

RESULTS AND DISCUSSION

Extraction performance

Chemical characterization of wine extracts

Antioxidant Capacity ORAC

CONCLUSIONS

ACKNOWLEDGEMENTS

REFERENCES

Publication Dates

History

Variables	Low level (-1)	Medium level (0)	High level (+1)
Liquid solution flow rate (mL min ^-1 )	0.1	0.3	0.5
CO ₂ flow rate, NCPT (mL min ^-1 )	60	70	80
Temperature (°C)	30	40	50
Pressure (bar)	120	150	180

Factor	Value	Optimum level
Temperature	32 ºC	-0.9
Pressure	180 bar	1
Red wine flow rate	0.5 mL min^-1	1
scCO₂ flow rate	70 mL min^-1 NCPT	0

Time (min)	Volumetricflow (mLmin^-1 )	A (Acetic acid 1%)	B (Acetonitrile)
0	0.8	90	10
20	0.8	80	20
41	0.8	80	20
45	0.8	50	50
65	0.8	50	50