Sequential Biorefining of Bioactive Compounds of High Functional Value from Calafate Pomace () Using Supercritical CO and Pressurized Liquids

Overview

Journal Antioxidants (Basel)

Date 2023 Feb 25

PMID 36829882

Authors

Jaime Ortiz-Viedma

Jose M Bastias-Montes

Cielo Char

Camila Vega

Alejandra Quintriqueo

Manuela Gallon-Bedoya

Marcos Flores

Jose M Aguilera

Jose M Miranda

Jorge Barros-Velazquez

Affiliations

Soon will be listed here.

Abstract

A biorefinery process was developed for a freeze-dried pomace of calafate berries (). The process consisted of extraction of lipophilic components with supercritical CO (scCO) and subsequent extraction of the residue with a pressurized mixture of ethanol/water (1:1 /). scCO extracted oil from the pomace, while pressurized liquid extraction generated a crude extract rich in phenols and a residue rich in fiber, proteins and minerals. Response surface analysis of scCO extraction suggested optimal conditions of 60 °C, 358.5 bar and 144.6 min to obtain a lipid extract yield of 11.15% (d.w.). The dark yellow oil extract contained a good ratio of ω6/ω3 fatty acids (1:1.2), provitamin E tocopherols (406.6 mg/kg), and a peroxide index of 8.6 meq O/kg. Pressurized liquid extraction generated a polar extract with good phenolic content (33 mg gallic acid equivalents /g d.w.), anthocyanins (8 mg/g) and antioxidant capacity (2,2-diphenyl-1-picrylhydrazyl test = 25 µg/mL and antioxidant activity = 63 µM Te/g). The extraction kinetics of oil by scCO and phenolic compounds were optimally adjusted to the spline model (R = 0.989 and R = 0.999, respectively). The solid extracted residue presented a fiber content close to cereals (56.4% d.w.) and acceptable values of proteins (29.6% d.w.) and minerals (14.1% d.w.). These eco-friendly processes valorize calafate pomace as a source of ingredients for formulation of healthy foods, nutraceuticals and nutritional supplements.

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