Supercritical Fluid CO2 Extraction and Microcapsule Preparation of Lycium barbarum Residue Oil Rich in Zeaxanthin Dipalmitate

The scope of this investigation aimed at obtaining and stabilizing bioactive products derived from Lycium barbarum seeds and peels, which were the byproducts in the processing of fruit juice. Zeaxanthin dipalmitate is a major carotenoid, comprising approximately 80% of the total carotenoid content in the seeds and peels. The method of obtainment was supercritical fluid CO2 extraction, studying different parameters that affect the oil yield and content of zeaxanthin dipalmitate. The optimized protocol to enact successful supercritical fluid CO2 extraction included optimum extraction pressure of 250 bar, temperature at 60 °C over a time span of 2.0 h, and a CO2 flow of 30 g/min, together with the use of a cosolvent (2% ethanol). The yields of oil and zeaxanthin dipalmitate under these optimal conditions were 17 g/100 g and 0.08 g/100 g, respectively. The unsaturated fatty acids were primarily linoleic acid (C18:2), oleic acid (C18:1), and γ-linolenic acid (C18:3), with their contents being as high as 91.85 ± 0.27% of the total fatty acids. The extract was a red-colored oil that was consequently microencapsulated through spray-drying with octenylsuccinate starch, gum arabic, and maltodextrin (13.5:7.5:3, w/w) as wall materials to circumvent lipid disintegration during storage and add to fruit juice in a dissolved form. The mass ratio of core material and wall material was 4:1. These materials exhibited the highest microencapsulation efficiency (92.83 ± 0.13%), with a moisture content of 1.98 ± 0.05% and solubility of 66.22 ± 0.24%. The peroxide content level within the microencapsulated zeaxanthin dipalmitate-rich oil remained at one part per eight in comparison to the unencapsulated oil, following fast-tracked oxidation at 60 °C for 6 weeks. This indicated the potential oxidation stability properties of microcapsule powders. Consequently, this microencapsulated powder has good prospects for development, and can be utilized for a vast spectrum of consumer health and beauty products.

Comparative Analysis of Perspective Extragation Methods for Receiving Extractions from Fenugreek Seeds

Introduction. Today, innovative technologies are widely used in pharmacology (in particular, in the production of herbal preparations), in cosmetology (obtaining various extracts and oils, complex preparations), as well as in the food industry (as natural dyes, etc.). Plant extracts with a high level of risk do not have a harmful effect on the human body, except that they provide environmental safety, which creates a special interest for the pharmaceutical industry . vibrocavitation and supercritical fluid CO2 extraction.Aim. The choice of the optimal level of extraction to obtain a high level of fenugreek seeds.Materials and methods. Obtaining a vibrocavitation extract with an experimental vibration-explosive installation made at the Department of Processes and Apparatus of the St. Petersburg State Technology Institute. Extracts at a temperature of 60±2 ºС. The frequency of revolutions of the homogenizer ranged from 1000 to 5000 rpm. Ultrasonic impact using ultrasound unit I100-6/4 Ultrasonic effect on solid plant material with an intensity of 22 kHz for 60 minutes. The time of extraction in a vibro-cavitation extractor-homogenizer was studied for optimal values.Supercritical fluid CO2-extraction is obtained in two versions with the use of extragent (96% ethanol in the presence of carbon dioxide: ethanol 9:1) and without it. Extraction of the sound of a supercritical fluid extraction system with a 1-liter vessel. SFE1000-2-BASE with a kit for upgrading the SFE1000-2-BASE system to an SFE1000M1-2-FMC50 system (Waters, USA). The flow rate of the extractant was 60 g/min. Emergency listening for one hour and pressure 200, 300 and 400 bar. Extraction is observed three times. The obtained extracts indicate the amount of extractive substances according to article of Russian state pharmacopoeia 1.5.3.0006.15 «Determination of the content of extractive substances in plant raw materials and medicinal plant preparations». Quantitative determination of the saponin complex of parasitic seed seeds on an Agilent QTOF-6530 chromatograph with two ESI and APCI ionization sources according to Gravel et al.Results and discussion. Studies have allowed to determine the amount of extractives in the seeds and choose the most promising method. Conclusion. As a result of our research, it was found that the most promising extraction method for extracting seeds is a parasitic with vibration extraction at frequent revolutions of the homogenizer of 5000 rpm and an extraction time of 60 minutes.