Food Technology
Kimia Goharpour; Fakhreddin Salehi; Amir Daraei Garmakhany
Abstract
Falafel is considered as an inexpensive and nutritious product that contains various plant substances, vitamins, dietary fibers, and phenolic compounds. The aim of this research was to investigate the impact of sprouting time on the physicochemical characteristics of sprouted chickpea flour. Also, the ...
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Falafel is considered as an inexpensive and nutritious product that contains various plant substances, vitamins, dietary fibers, and phenolic compounds. The aim of this research was to investigate the impact of sprouting time on the physicochemical characteristics of sprouted chickpea flour. Also, the effects of sprouting time on the physicochemical characteristics and sensory properties of falafel prepared from sprouted chickpea flour were examined. The finding of this research indicated that the sprouting process significantly increased the total phenolic content (from 284.17 to 720.98 μg gallic acid/g dry), antioxidant capacity (from 77.55% to 93.35%), and redness (from 7.65 to 11.39) of chickpea flour (p<0.05). While, it significantly decreased the lightness (from 70.81 to 57.07) and yellowness (from 43.71 to 25.62) of chickpea flour (p<0.05). The total phenolic content and antioxidant capacity of falafel prepared from flour of sprouted chickpea for two-days (48 hours) were significantly higher than those prepared from unsprouted chickpeas flour (p<0.05). The volume of falafel samples produced from unsprouted, one-day sprouted, and two-day sprouted chickpea flours was 18.75, 16.60, and 15.40 cm3, respectively. The minimum oil uptake was observed in the sample prepared from chickpeas sprouted for two-days (p<0.05). The sprouting process did not have a significant impact on the firmness, cohesiveness, and chewiness of the falafel (p>0.05). In general, utilizing of one-day (24 hours) sprouted chickpea flour for the production of falafel is recommended due to the best flavor, the highest overall acceptance score, high content of phenolic compounds, high antioxidant capacity, and low oil absorption.
Food Chemistry
Zahra Khodakaramifard; Hannan Lashkari
Abstract
Introduction
The date palm (Phoenix dactylifera L.) plays an important social, environmental, and economical role for many people living in arid and semiarid regions of the world. Date fruit is one of the major agricultural crops in the East Asia region, where about 90% of the world's dates are cultivated. ...
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Introduction
The date palm (Phoenix dactylifera L.) plays an important social, environmental, and economical role for many people living in arid and semiarid regions of the world. Date fruit is one of the major agricultural crops in the East Asia region, where about 90% of the world's dates are cultivated. Dates are rich in certain nutrients and provide a good source of rapid energy, due to their high carbohydrate content (70–80%). Moreover, date fruits contain fat (0.20–0.50%), protein (2.30–5.60%), dietary fibre (6.40–11.50%), minerals (0.10–916 mg/100 g dry weight), and vitamins (C, B1, B2, B3, and A) with very little or no starch. In addition to the direct consumption of the fruit, various industrial products are also extracted derived from this product, including date juice, date honey, liquid sugar, vinegar, alcohol, caramel, date paste and date chocolate. The annual production of one million and 400 thousand tons of dates in Iran has made Iran the second pole of date production in the world after Egypt. Zarin Dasht region is located in Fars province, and the annual production of dates in this region reaches more than 1000 tons. The aim of the present work was to investigate the chemical composition, carbohydrate, and antioxidant capacity of two cultivars of Zarin Dasht dates.
Materials and Methods
After collection, all date fruits were washed with tap water, and the seeds were then removed, and the flesh were shade dried at room temperature. The dimensions and area of the imaged surfaces were measured by the physical properties measurement device in 100 repetitions. The working principle of this device is based on image processing technique. By placing the product in three different positions and perpendicular to each other, pictures of the date samples were taken individually. Date mass was obtained using a sensitive digital scale with an accuracy of 0.01 g. The displaced water method was used to determine the volume and density of each date seed. Bulk density, date porosity, geometric mean diameter, sphericity coefficient and surface area of the samples were determined. The amount of moisture was determined by weight method, ash by burning in an electric furnace, titratable acidity based on malic acid and pH of the samples were measured by a digital pH meter. To measure the amount of total phenol in the fruit, Folin–Ciocalteu reagent was used and the absorbance of the reaction mixture was read at 750 nm by a spectrophotometer. The amount of total phenol was reported in terms of gallic acid. The antioxidant capacity was determined through the neutralization of free radical 2 and 2 diphenyl 1-picrylhydrazyl (DPPH). To measure the sugar of all samples, first a standard curve was drawn from the glucose solution in different concentrations, then the sugar content of the samples was measured in milligrams per gram of fresh weight at 490 nm using the sulfuric phenol method. The amount of crude fibre was calculated according to the standard method of AOAC-991/43. The amount of fat was obtained with the Universal Extractor E-800 device for 3 hours at a suitable temperature and in 250 cc of n-hexane solvent. Finally, the statistical analysis of the data was done factorially and in the form of a completely random design in 3 replications using SAS 4, 9 software and the comparison of the means was done using the LSD test at a probability level of 1%.
Results and Discussion
According to the results of this research, there was a significant difference in all qualitative traits except pH (P<0.01). In comparing the characteristics of the palms of two cultivars, it was observed that the highest amount of fibre (1.78 %), titratable acid (0.59 %), ash (1.64 %) and fat (0.85 %) is related to Shahani cultivar,and the highest amount of total phenol (8.1 mg/gFW), DPPH inhibitory property (13 %), moisture (18.7%), sugar (63.8 %), protein (0.29 %) and pH (5.74) belonged to Khassui cultivar. Also, comparing the kernel characteristics of two cultivars, it was observed that the highest amount of ash (3.17 %), total phenol (10.8 mg/gFW), antioxidant property (72 % DPPH inhibition), protein (2.55 %), pH (6.11) and fat (9.20 %) related to the kernel of Shahani variety and the highest amount of fibre (26.2 %), moisture (5.26 %), sugar (15.8 %) and titratable acid (0.38 %) belonged to the kernel of Khassui cultivar. Overall, the kernel of Shahani variety had more DPPH inhibitory power among all the samples.
Hadis Cheraghi; Fardin Ghanbari; Mehdi Saidi
Abstract
Introduction: Button mushroom (Agaricus bisporus L.) is one of the most popular and widely consumed edible mushrooms that is grown all over the world. However, button mushrooms have a short shelf life of about 3 to 4 days after harvest and lose their commercial value within a few days due to browning ...
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Introduction: Button mushroom (Agaricus bisporus L.) is one of the most popular and widely consumed edible mushrooms that is grown all over the world. However, button mushrooms have a short shelf life of about 3 to 4 days after harvest and lose their commercial value within a few days due to browning of the tissue, water loss, aging and microbial attack. Tissue browning is caused by the activity of polyphenol oxidase (PPO) in plastids on phenolic compounds in the vacuoles as a substrate. Therefore, enzymatic browning is intensified by the loss of membrane integrity due to aging and tissue deterioration and as a result of physical connection between the enzyme and the substrate. The use of some techniques such as the chemicals and physical treatments gives promising results in delaying Browning and increasing the shelf life of edible mushrooms. Cinnamic acid (CA) is an organic acid that occurs naturally in plants and has low toxicity and a wide range of biological activities. Cinnamic acid and its derivatives are widely used in food industry. This compound acts as an inhibitor of polyphenol oxidase activity. On the other hand, cinnamic acid in low concentration has been proposed as an activator of the antioxidant system and its positive effects on reducing the effects of environmental stresses in various plants have been proven in several experiments. Therefore, in the present study, the effect of cinnamic acid treatment on reducing the browning of the tissue and maintaining the quality of white button mushrooms in the post-harvest period has been investigated. Materials and Methods: Treatments included exogenous application of cinnamic acid at four levels (control, 100, 200 and 400 μM trans cinnamic acid) and storage time at five times (0, 4, 8, 12 and 16 days after storage). Cinnamic acid treatment at the mentioned concentrations was applied by top application 24 hours before mushroom harvest. Distilled water was used for control treatment. At the time of picking, infected, very large and small mushrooms were removed and the same mushrooms with a cap diameter of 40 to 45 mm were collected for each experimental treatment. After harvesting, the mushrooms were placed in a polyethylene box covered with cellophane and after weighing, they were transferred to an incubator at 4°C. In the post-harvest period, different traits were measured with a four day interva. Results and Discussion: The results showed that by increasing storage time, the activity of polyphenol oxidase and peroxidase increased and consequently the browning of the tissue also had an increasing trend. Also, with increasing storage time, weight loss percentage, hydrogen peroxide and malondialdehyde increased and total phenol and total antioxidant capacity were decreased. The use of cinnamic acid treatment in all three concentrations (100, 200 and 400 μM) reduced the activity of peroxidase and polyphenol oxidase activities and reduced tissue browning. The application of cinnamic acid also improved the quality traits of edible mushrooms such as total phenol, total antioxidant capacity and visual quality index. These findings suggest that application of cinnamic acid, especially at a concentration of 400 μM, could have the potential of inhibiting tissue browning and thus maintaining the mushrooms quality at the postharvest period
