The main objective of this study was to use heating method (HM) to prepare liposome without employing any chemical solvent or detergent. Plackett-Burman design (PBD) was applied for the screening of significant process variables including the lecithin proportion, the cholesterol/ lecithin ratio, the pH of solution for liposome preparation, the enzyme/lecithin ratio, the stirring time, the process temperature, the speed of stirrer, the ratio of stirrer to the tank diameter, the application of homogenization, the method of adding enzyme and centrifugation conditions on the encapsulation efficiency (EE %) of liposome and the activity of liposomal Flavourzyme (LAPU −1 ) (P<0.05). Then, the response surface methodology based on the central composite design (CCD) was applied for the evaluation of the impacts of the significant mentioned variables on the EE (%) and the activity of the liposomal Flavourzyme. The results indicated that the lecithin proportion and the stirring time were the major influential variables for both responses. The most suitable formulation of the Flavourzyme-loaded liposome is 4.5 % lecithin, 45°C temperature, 5 % Flavourzyme/lecithin ratio, 30 min stirring time and medium pH of 6. Under suitable operating conditions, the EE of liposome and the activity of the liposomal Flavourzyme were achieved as 26.5 % and 9.96 LAPU ml −1 , respectively. AFM technique and size distribution clearly showed the diameter of 189 nm for the spherical shape of the Flavourzyme-loaded nanoliposome.
A major obstacle in the utilization of phenolic antioxidant compounds is their sensitivity and as a result stability issue. The current study aimed to encapsulate polyphenolic compounds, extracted from Rosemary, in liposomes prepared by the Mozafari method without the utilization of toxic solvents or detergents. The extract was prepared and converted into a powder by freeze-drying. The process conditions were optimized using response surface analysis, and the optimal parameters were as follows: phosphatidylcholine (PC), 2.5% (25 mg/mL); extract, 0.7% (7 mg/mL); process temperature, 70 C and process time, 60 min. The entrapment efficiency in optimal sample was 54.59%. Also, optimal glycerosomes formulation were finally physicochemical characterized (permeability, zeta potential, and size distribution). The mean size of empty and containing rosemary extract glycerosome were 265.4 nm and 583.5 nm, respectively, and the Z-potential of optimal glycerosome was -65.1 mV. Total phenolic content was obtained 151.38 mg gallic acid/g extract, in optimal liposomal formulation, which was measured by Folin-Ciocalteu's phenol reagent. Also, the antioxidant activity of rosemary extract by DPPH for the free and optimal liposomal formulation was determined to be 84.57% and 92.5% respectively. It can be concluded that the liposomal rosemary extract formulation prepared in this study, employing a safe, scalable, and green technology, has great promise in food and pharmaceutical applications.
Skimmed milk was inoculated with the commercial starter and Lactobacillus casei ssp. casei. pH changes, viable counts, and organoleptic properties of the produced control and probiotic yogurts were analysed. The pH decrease during the fermentation period was faster in the milk inoculated with L. casei plus starter. The growth of both starters in probiotic yogurt was significantly lower than their growth in control yogurt during the fermentation period. The viable count of the probiotic bacterium remained higher than the standard limit for probiotic products. There was no significant difference between the organoleptic properties of the control and the probiotic yogurts.
Color is one of the most important characteristics of foods. It includes visual signals for flavor identification and taste thresholds. Furthermore, color plays significant roles in consumer satisfaction of foods (Hutchings, 2021). Legally permitted pigments are divided into two major categories of natural and synthetic.Natural colors include beneficial and therapeutic characteristics.Use of natural colors is one of the current marketing trends because of consumer's concerns about the safety of artificial food dyes, facilitated by possible health benefits of the natural pigments (Rodriguez-Amaya, 2016). However, natural pigments show more sensitivity and instability when exposed to environmental factors such as high temperature, oxidation, and pH than artificial
This study tested the effects of the application of Laurus nobilis aqueous extract and edible coating of chitosan had on the chemical, microbial, and sensory attributes of cashew's shelf life. An aqueous extract of L. nobilis leaf (0, 0.5, and 1% w/w) was added to chitosan solution (0, 0.5, 1% w/w) in the cashew's coating. Cashews were dipped into the coating solution and were kept in polyethylene terephthalate containers. The result showed that chitosan and aqueous extract of L. nobilis coating had significant effects on peroxide and thiobarbituric acid value (p < .05). There was significant reduction in the growth of mold/yeast and mesophilic bacteria with higher concentration of chitosan and L. nobilis aqueous extract (p < .05). The results of this study show chitosan aqueous extract of L. nobilis coating could be an effective preservative method for extending shelf life and improving the stability of cashew.
Liposomes and nanoliposomes as small vesicles composed of phospholipid bilayer (entrapping one or more hydrophilic or lipophilic components) have recently found several potential applications in medicine and food industry. These vesicles may protect the core materials from moisture, heat and other extreme conditions. They may also provide controlled release of various bioactive agents, including food ingredients at the right place and time. Potential applications of enzyme-loaded liposomes are in the medical or biomedical field, particularly for the enzymereplacement therapy, as well as cheese industry for production of functional foods with improved health beneficial impacts on the consumer. Encapsulation process has a recondite impact on enzymes. In fact, liposome preparation techniques may alter the pH and temperature optima, affinity of the enzyme to substrate (Km), and maximum rate of reaction (Vmax). In addition, in this paper, the impact of process variables on the kinetic characteristics of enzymes encapsulated in liposomes was investigated. Also, the effects of enzyme entrapment in liposomes, prepared by different methods, on the catalytic efficiency of enzyme, as well as its kinetic properties and stability compared to native (free) enzymes has been reviewed.
In the present study, green tea extract was encapsulated in liposomes based on the Mozafari method (with no organic solvents) and characterized for its physicochemical properties (encapsulation efficiency, particle size, and Z‐potential). Encapsulation efficiency, particles size, and Z‐potential were determined to be 51.34, 419 nm, and ‐57 mV, respectively. Total polyphenol content of the green tea by Folin‐Ciocalteu's phenol reagent was measured as 164.2 mg gallic acid/g extract. Free radical scavenging activities of free and liposomal extracts were 90.6 and 93.4%, respectively, using the DPPH method. Antioxidant activity of the ethanolic extract of green tea in free and liposomal forms with concentrations of 200, 600, and 1000 mg L−1 were assessed on oxidative stability of the canola oil at 60 °C for 0, 4, 8, 12, 16, 20, 24, 28, and 32 days. Results were compared to results of synthetic antioxidant butylated hydroxytoluene at 200 mg L−1. To assess antioxidant activity on canola oil stability, peroxide, thiobarbitoric acid, and anisidine values were assessed as well as the total oxidation value and rancimat test. Results showed that the liposomal green tea extract was more effective than the free extract. Furthermore, a 600 mg L−1 concentration of the green tea extract showed a significant antioxidant activity, compared to other extract concentrations. Increasing storage time and various concentrations of the ethanolic green tea extracts included significant effects on canola oil stability (P ≤ 0.05). Results demonstrated that the green tea extract could be used as an effective antioxidant. Free and liposomal extract (at 600 mg L−1) resulted in stronger functionality than the synthetic antioxidant butylated hydroxytoluene.
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