Food Technology
Ali Kashani; Maryam Hasani; Leila Nateghi; Mohammad javad Asadolahzadeh; Parvin Kashani
Abstract
Introduction: Nowaday, the demand for low calorie food based and keeping primary features including texture and taste is increasing. Jelly is one of low calorie products produced from fruits and other components, and its consumption is increasing for human health. Jelly is semi-solid and transparent ...
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Introduction: Nowaday, the demand for low calorie food based and keeping primary features including texture and taste is increasing. Jelly is one of low calorie products produced from fruits and other components, and its consumption is increasing for human health. Jelly is semi-solid and transparent product that prepared with the use of sugar or juice and pectin or gelatin and flavor and color may also be added. Potato peels contain valuable substances such as pectin. Using potato peels to produce pectin with appropriate properties can solve the environmental issue resulting from these wastes in addition to make value added product. Pectin is a complex polysaccharide that is found in the wall of early plant texture and in the intercellular layer. Pectin contains a group of rich polysaccharides of galacturonic acid units with lower amounts of different sugars (Baiano, 2014). Two commercial forms of pectin are available: high-methoxyl and low-methoxyl pectin (high ester and low ester pectin). High-ester pectin forms a gel in a solutions containing high soluble solids and acidic systems, whereas low-ester pectins form more gel at wider pH and range of solids content but they do require divalent cations to form the gel (Kratchanova et al., 2012). In the food industry, pectin is used as a jelly-making agent, especially in the production of jellies and jams. Pectin is also used in fillers, medicine, pastries, bakery products and also as a stabilizer in juices and beverages, as well as in dietary fiber (Sharma, 2006). Pectin also has therapeutic benefits such as lowering blood cholesterol levels, removing heavy metal ions from the body, stabilizing blood pressure and facilitating intestinal activity (Ptichkina et al., 2008). Temperature, pH, and acid extraction time are the most important factors affecting the extraction yield and quality of produced pectin (Yapo et al., 2007). Currently, almost all commercial pectins are produced from citrus or apple peels, both of which are juices by-products (Thirugnanasambandham et al., 2014). Therefore, the main objective of this study was to optimize the conditions of extraction of pectin from potato peel by response surface methodology and to compare the physicochemical properties of Jelly produced from potato peel under optimum conditions with Jelly produced from apple and citrus Material and methods: Potato of Granola variety was purchased from the local market in Ardebil. The chemicals used for the tests include: citric acid, sodium hydroxide, phenolphthalein, and Calcium chloride were purchased from Merck Company (Germany). The method of Hoseeni et al (2017) was used for jelly production with slight modification as follows. In the First step,0.5 and 1% pectin extracted from potato peelings, 30 % Sugar, 0.014 % Cherry edible color and 0.75 % Cherry essential oil were mixed then 100 CC Boiling water was added to the mixture and mixed again. After the sugar was completely dissolved, 15, 30, and 45 mg of calcium chloride was added per gram of pectin. The pH of the samples was regulated by citric acid solution on 2.5 and 4. The heating of the samples was continued until the brix of the treated treatments was set to 42. The prepared samples were kept at room temperature for half an hour. The treatments were then refrigerated for 2 to 3 hours to complete the jelly closing process. For this purpose some jelly characteristics such as texture properties, physico-chemical (pH, acidity, brix, moisture and Drainage) and sensory properties of samples were investigated using five point hedonic scale. A one-way analysis of variance and Duncan test (P≤ 0.05) in three replications were used to establish the significance of differences in the experimental data. The results were analyzed using the Minitab version 16. Results & Discussion: Results showed that by increasing calcium chloride, pH and Pectin concentration had a significant effect on increasing the hardness of the gel and the strength needed to make the gel brittle (P≤0.05).The highest hardness of the gel in pectin emulsion extracted from potato peel was 30.0959 N and highest force required to break the gel was 27.3431 N in the most severe extraction conditions at Calcium chloride 35.2286 mg/g, Pectin concentration 1% and pH 4. Results of physico-chemical properties showed that there was no significant difference between pH, acidity, brix and moisture of jelly made from apple pectin and citrus and apple commercial pectin. The results of the syneresis showed that the syneresis by the jelly of potato pectin is not similar with jelly from apple pectin and citrus and apple commercial pectin significantly different. Also Results of sensory properties showed that it was no significant difference between jelly from apple pectin and citrus and apple commercial pectin. The results of this study showed that by optimizing the production conditions, potato pectin can be used in jelly formulation and jelly can be produced with desirable and comparable quality compared to the commercial pectins
Samaneh Hizomi Shirejini; Hadi Koohsari; Seyedeh Zahra Seyed Alangi
Abstract
Introduction: Study in order to introduce new antimicrobial agents with natural origin to prevent the antibiotic resistance and eliminating its effects, employing chemical agents is an indispensable necessity. Honey, as an important food with natural origin has high antimicrobial potential. Several factors ...
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Introduction: Study in order to introduce new antimicrobial agents with natural origin to prevent the antibiotic resistance and eliminating its effects, employing chemical agents is an indispensable necessity. Honey, as an important food with natural origin has high antimicrobial potential. Several factors have contributed to the antibacterial activity of honey. For example, acidity, osmolarity, hydrogen peroxide, phenolic and flavonoid compounds, including these factors. Also, small amounts of glucose oxidase, protease, amylase, catalase and phosphatase enzymes and chemical compounds such as methylglyoxal are also effective. Floral origin of honey is effective on its biological properties including antimicrobial, anti-tumor, anti-inflammatory, antioxidant and antiviral activity. So this study was done to evaluate the antibacterial activity and physico-chemical analysis of four types of honey with different floral origin including: Thyme, Eryngium, Pennyroyal and Dill collected from the bee hives in Golestan province.
Materials and methods: Four honey samples with different floral origin including, Thyme, Eryngium, Pennyroyal and Dill were collected from the bee hive in the Golestan province in north of Iran. The bacterial strains used in this study, including two species of gram-negative of Escherichia coli and Shigella dysenteriae and the two species of gram-positive of Staphylococcus aureus and Bacillus cereus were provided in lyophilized. Bacterial strains in BHI broth were activated and from each of them were prepared bacterial suspensions equivalent to the McFarland 0.5 turbidity standard (1.5×108 CFU/ml). Evaluation of antibacterial activity using agar well diffusion method was performed. For this purpose serial dilutions of honey samples were prepared aseptically in sterilized distilled water. Surface of Mueller Hinton agar were uniformly inoculated with bacterial suspension containing of 1.5×108 CFU/ml. Then wells of 8 mm in diameter were prepared and these wells were filled with different dilutions of honey samples. After incubation at 37°C for 24 h, antibacterial activity was analyzed by measuring the zones of inhibition. Minimum inhibitory concentration (MIC) and minimum bactericidal concentration (MBC) of honey samples were determined by using broth macro-dilution method. For this purpose, each of the tubes from different dilutions of honey samples were added by 5×105 CFU/ml from each of the tested bacteria and incubated for 24 h at 37°C. The results for microbial turbidity of visible were recorded. The last dilution (lowest concentration) in which microbial turbidity was not observed, as the MIC was considered. For the determination of MBC, from the tube that contained honey concentrations higher than the MIC were cultured onto the agar medium. The MBC was defined as the lowest concentration that allowed no visible growth on the agar. Also the studied physico-chemical properties were moisture content, pH, acidity, ash content and reducing sugars that was performed according to the Iranian National Standard No. 92.
Results and Discussion: The results indicated that the antibacterial effects of the tested honeys, and the difference between floral origins honeys is effective in antibacterial properties. MIC and MBC values obtained for the tested honeys were in the range of %6.25-50% (vol/vol). Highest antibacterial activity was recorded for Eryngium honey by agar well diffusion method with zone of inhibition of 15.5, 14,11 and 11 mm against S. dysenteriae, S. aureus, B. cereus and E. coli at concentration of 50% v/v respectively and its MIC for this bacteria were, 6.25%, 10%, 10% and 25% respectively. also low antibacterial activity of Pennyroyal honey was confirmed so that MIC of the this honey for E. coli, S. aureus, B. cereus and S.dysenteriae was, 50%, 25%, 12.5% and 10%, respectively. The quality of honey depends on a number of physico-chemical properties such as moisture, ash content, pH, acidity, the amount of sugars. For this reason, standards for honey have been set by different countries. The physico-chemical analysis of honeys showed moisture contents in the range of 22.56-25.36%, acidity in the range of 12.58-13.59 meq/kg, pH in the range of 4.15-4.26, reducing sugars in the range of 63.7-63.8%. Also the ash content of Eryngium honey with 0.183% was higher than the other honey samples. This higher level might be due to the higher pollen count in this region. High ash contents may also depend upon the floral origin of honey and the material collected by bees during foraging. The low acidity of honey samples studied in the present study was due to the fact that there was no unwanted fermentation in these samples. Overall, the results implied that honey samples with different floral origin collected from the bee hive in the Golestan province in north of Iran have variable potential antibacterial activity. The variety of antibacterial effects of different types of honey can be due to differences in plants that honey is obtained from. In other words, different species of plants in different regions have different compounds and their obtained honey will not be the similar and thus its biological effects also will be different.
Mahdi Kashani-Nejad; Alireza Sadeghi Mahoonak; Seyed Mohammad Ali Razavi
Abstract
Introduction: Honey is a natural food product having a high nutritional and medicinal value. It is a sweet, viscous substance produced by the honeybees from the nectar of plants. Sensory and physical properties and chemical composition of honey depend on the botanical origin and the regional and climatic ...
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Introduction: Honey is a natural food product having a high nutritional and medicinal value. It is a sweet, viscous substance produced by the honeybees from the nectar of plants. Sensory and physical properties and chemical composition of honey depend on the botanical origin and the regional and climatic conditions of the area in which it is produced.The knowledge of honey rheology is very important for its processing, quality control, process control, and selection of proper process equipment, storage, handling, and transportation and plays an important role in fluid heat transfer. Rheological properties of honeys depend on many factors including composition, temperature, and amount and size of crystals. Different kinds of honeys with various floral origins (such as Rosa, Thyme, Astragalus, Trifolium, sunflower, Medicago, alfalfa and etc.) are produced in different regions of Iran. In this study, some physicochemical and rheological properties of four Iranian honeys from Golestanprovienceobtained from various floral sources, two poly floral (Mountain, Forest) and two mono floral (Sunflower, Ivy) were compared with adulteratedand sugar honeys.Materials and methods: Sixhoney samples were collected directly from beekeepers in Golestan Province,two monofloral (Sunflower, Ivy) and two polyfloral(Mountain, Forest), adulterated and sugar honeys. Some physico–chemical characteristics of samples including water content, Hydroxymethylfurfural content (HMF), diastase activity, pH, ash, free acidity, reducing sugars (fructose and glucose), sucrose contentand electrical conductivity were determined by the harmonized methods of the International Honey Commission. The rheological measurements were also carried out on the honey samples at eighteen rotations, ranging from 5-200 rpm and at five temperatures, ranging from 10-30ºC, using a viscosimeter Brookfield.Results and discussion: The samples were found to be different from each other in terms of physico-chemical properties. In the natural honey samples, this discrepancy can be due to diversity in original plant and harvesting season. All the values obtained in the natural honey samples were agreement with those reported by Codex Alimentarius and ISIRI. The values of sucrose and fructose/glucose ratio the sugar honey sample and sucrose, fructose/glucose ratio, pH, HMF, diastase activity of adulterated honey were not in the range suggested by Codex Alimentarius and ISIRI. Conclusion: Rheological characteristics of honeys were evaluated at different temperatures (10, 15, 20, 25 and 30ºC). All the honeys exhibited Newtonian behavior for shear rate in range of 1.045- 41.8 s-1.The temperature dependence of viscosity was described using the Arrhenius and the Vogel–Taumman–Fulcher (VTF) equations.Two models (Power Law and Exponential models) were also investigated to describe the concentration (ºBrix) dependence of viscosity
