Leila Khajehvandi; Majid Javanmard; Mohammad Reza Eshaghi
Abstract
Introduction: Studies in recent years have led to the emergence of a new concept in the packaging industry namely “Active packaging”. Contrary to popular packaging that needs to be completely neutral and ineffective, in different kinds of active packaging, there is an interaction with food ...
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Introduction: Studies in recent years have led to the emergence of a new concept in the packaging industry namely “Active packaging”. Contrary to popular packaging that needs to be completely neutral and ineffective, in different kinds of active packaging, there is an interaction with food or environment, and has an active role in food materials maintenance (Brody et al, 2008). Nowadays, various kinds of polymeric materials and their different characteristics and forms has resulted in easy design and production of packaging based on special requirements of a food product (Lopez-rubio et al, 2004). Polyethylene and polypropylene along with cardboard boxes are used for packing butter (Milts, 1988). It has been proved that Alpha-Tocopherol maintains its stability in the processing conditions and low aw also maintain its stability, alpha – Tocopherol has desirable migration characteristics and excellent solubility in polyolephines. use of alpha- Tocopherol is more affordable compared to other antioxidants (Lee, 2005; Wessling et al, 1998).The aim of this study was to investigate the effect of alpha-tocopherol coating on the surface of polymer films in preventing the oxidation of lipid in butter.Materials and Methods:MaterialsDL-alpha-tocopherol acetate, low density polyethylene film(LDPE) , biaxial oriented polypropylene film (BOPP), traditional-lactic butter with salt made from cow's milk .MethodsPreparation of films: In this stage, first alpha-tocopherol was prepared with three concentrations of %0.1, %0.15and %0.2, and %70 ethanol was used as solvent. In the next step, low density polyethylene and polypropylene films were prepared in enough dimensions and numbers, and were washed and sterilized by %70 ethanol. Then, different concentrations of alpha-tocopherol (%0.1, %0.15,%0.2) were separately covered on a sufficient number of films via spraying (under identical conditions).to complete coverage of the films surface, spraying alpha-tocopherol was performed 3 times. after drying, films were kept in dark place (Pereira et al, 2011).Packaging and storage of butter: At this stage, butter pieces weighing 45 grams covered with LDPE and BOPP films with three different concentrations of alpha-tocopherol (%0.1,%0.15,%0.2) were packed. To prepare the control sample, butter was packed with alpha-tocopherol lacked films. The experiments of determining the amount of peroxide and acidity, and Sensory evaluation test was conducted on a sample of butter before packaging, and were repeated in tenth, twentieth ,and thirtieth days.Determining the amount of alpha-tocopherol remained on the films : At this stage, in order to determine the amount of alpha-tocopherol remaining on the films, weight difference of films before and after spraying alpha-tocopherol, and drying them on the films was measured. The amount was calculated by mg/cm2 stated (Contini et al, 2012).Measurement of alpha-tocopherol migration to ethanol: The total amount of alpha-tocopherol migrate from the films into the similar lipid matter(%95 ethanol)were calculated by the colorimetric method using a standard alpha-control solution and drawing the calibration curve(Corrales et al, 2009).The Sensory evaluation test: To evaluate the sensory properties including taste, color, smell and public acceptance, five-point hedonic test was used(Tafreshi et al, 2013).Methods and tools for data analysis: All tests were repeated three times. For data analysis, a factorial experiment in a completely randomized design was used. Alpha-tocopherol concentration, time and type of film were the main factors. Duncan multiple range test was used to assess the differences between means in the confidence level of %5.For all statistical analysis, MSTAT-C software version 14 was used.Results and Discussion: Findings from surveying the migration process into 95% ethanol solution, indicates that alpha-tocopherol were remained on the surface of polymeric films (LDPE &BOPP) after drying, and migrated from the surface of films into ethanol %95. With the increase of time and concentration of alpha-tocopherol, migration from the surface of films into ethanol increased (p
Malahat Safavi; Majid Javanmard
Abstract
In this study, the effects of coating with whey protein concentrate (7.5% w/v) alone and/or in combination with rice bran oil (0.2, 0.4, 0.6 g in 100 ml coating solution) and Zataria multiflora extract (1 and 2 μL in 100 ml coating solution) on the quality attributes and egg shelf life were carefully ...
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In this study, the effects of coating with whey protein concentrate (7.5% w/v) alone and/or in combination with rice bran oil (0.2, 0.4, 0.6 g in 100 ml coating solution) and Zataria multiflora extract (1 and 2 μL in 100 ml coating solution) on the quality attributes and egg shelf life were carefully observed and analyzed. Weight loss, Haugh index, yolk index, pH, air cell depth, shell strength and the impact of this coating on the microbial load of the eggs surface were studied at the end of each week (during the 4 weeks of storage in a room environment temperature and humidity). After 4 weeks of storage, it was observed that the weight loss in all of the treated eggs with whey protein concentrate and 0.2 gr of rice bran oil (experimental group) was significantly lower than that of the control group(P<0/05). With regard to Haugh index and yolk index, egg shelf life increased about 4 weeks compared with the control samples. Haugh Index changes revealed that the coated samples remained at grade A after 3 weeks of storage, while the control samples were relegated from grade AA to B after one week. Haugh and yolk Indices in all coated eggs were more than those of the control group. In the coated groups, Haugh and yolk indices of the coated samples with whey protein concentrate and 0.2 g rice bran oil and with whey protein concentrate and 0.2g of rice bran oil and 1 micro liter of Zataria multiflora extract were more than those of the other coated eggs and the control group eggs. PH values of the control group were higher than those of the coated groups during the storage of the eggs. The shell strength of the coated group was more than that of the control group (uncoated) and in coated samples, whey protein concentrate and 0.2 gr of rice bran oil coated samples had high shell strength. In the other treatments no significant differences were observed. The depth of the air cell of the coated groups was determined to be less than that of the control group during the storage period. The minimum inhibitory concentration was 1 μL of Zataria multiflora extract. The results showed that 1 μL concentration of Zataria multiflora extract reduces the microbial load of the egg shell surface to 87% and 2 μL reduced total bacterial load to zero. In sensory evaluation, from evaluator point of view, the coated eggs had more overall acceptance than the uncoated group (control), and in the treatment group coated eggs, those containing a low percentage of rice bran oil had higher overall acceptability. In conclusion, coating as a practical and cost effective method can maintain the quality parameters of eggs and lead to durability of supply conditions in addition to the product marketability.
Faezeh Tafreshi; Majid Javanmard; Maryam Fahim danesh
Abstract
Antioxidant active packaging is one of the active packaging that prevents of lipid oxidation by releasing antioxidant during storage of food. In recent years the use of natural antioxidant instead of the synthetic variety in these packaging has been considered. The aim of this study was evaluating the ...
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Antioxidant active packaging is one of the active packaging that prevents of lipid oxidation by releasing antioxidant during storage of food. In recent years the use of natural antioxidant instead of the synthetic variety in these packaging has been considered. The aim of this study was evaluating the performance of polymeric film coated with natural antioxidant (Rosemary Extract) to prevent lipid oxidation in butter. With three different concentrations (0.1%, 0.15%, 0.2%), the ethanolic extract of Rosemary was sprayed on the surface of low density polyethylene films (LDPE). Films without extract was used as control. Phenolic compounds migration from the surface of film to 95% ethanol (fatty food stimulant) was measured at 4ºc during 10 hours. With increasing time and extract concentration, migration to ethanol increased (P
Sahar Lashgari; Majid Javanmard
Abstract
Nowadays, the use of natural antioxidants as alternative antioxidants is more acceptable than synthetic antioxidants mainly for negative effects such as carcinogenicity and toxicity. This has led to an increasing interest in the search for natural antioxidants. The objectives of this study were to measure ...
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Nowadays, the use of natural antioxidants as alternative antioxidants is more acceptable than synthetic antioxidants mainly for negative effects such as carcinogenicity and toxicity. This has led to an increasing interest in the search for natural antioxidants. The objectives of this study were to measure total crude phenolic compounds and in sorghum grain as natural antioxidant sources, to determine antioxidant effect of extracted compounds in various concentrations on sheep tail fat and to compare antioxidant effect of crude extract with synthetic antioxidant (TBHQ). The crude phenolic compounds in the whole sorghum grain were extracted using the organic solvents (acetone and methanol) and its constituents were measured by HPLC method. Antioxidant effect of extracted compounds at three concentrations (500,1000 and 2000 ppm) was determined by measurement of peroxide value, Thiobarbitoric Acid Substances(TBAS) and induction period (rancimat) compared with control (sheep tail fat without extract) after 48 and 96 hours incubation at 80ºC. The antioxidant effect of crude phenolic extract at optimum concentration (1000 ppm) and TBHQ at 100 ppm was also determined by measurement of later factors compared with control at 4-day intervals during 20 days of storage at 80ºC. Total crude phenolic compounds were 1700 (mgGA/100gr) Phenolic acids (Gallic acid, Vanillic acid, Ferulic acid and Caffeic acid), flavonoids and anthocyanins were measured as main crude phenolic compounds that determined by HPLC. Anthocyanins were the main components of flavonoids. The most antioxidant effect on sheep tail fat was achieved by adding of 2000 ppm of crude phenolic extract from sorghum after 96 hours at 80ºC. The most effective concentration of crude phenolic extracts on sheep tail fat was determined 2000 ppm. Crude phenolic extract at 2000 ppm increase induction period significantly. Synthetic antioxidant (TBHQ) exhibits constant and higher antioxidant effect compared with crude phenolic extract during 20 days of storage. This antioxidant increase induction period of sheep tail fat more than crude phenolic extract. The results indicated that crude phenolic extract present in the sorghum grain may be introduced as natural antioxidant source with out any harmful effects on human health. But the presence of high amounts of anthocyanin as red pigment in crude phenolic extract and its negative effects on oil colour may limit use of this antioxidant.
Sanaz Ojnordi; Majid Javanmard; Simin Asadollahi
Abstract
Due to environmental risks generated by application of non-degradable and synthetic films, many researches have shown increasing tendency to edible coatings for storing food such as fruits and vegetables. Whey protein is considered one of the most common sources of edible coatings and its use has been ...
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Due to environmental risks generated by application of non-degradable and synthetic films, many researches have shown increasing tendency to edible coatings for storing food such as fruits and vegetables. Whey protein is considered one of the most common sources of edible coatings and its use has been studied in the current research. In this paper, the simultaneous effect of coating with whey protein and Zataria multiflora Boiss extract on the quality of peach kept in refrigerator has been studied. According to response surface methodology, were measured 20 treatments repeating 6 times in the center point and effects of the three factors including whey protein (2. 5 to 5 gr), Zataria multiflora Bioss extract (0 to 500 μL) and glycerol (0. 375 to 2. 25 gr) on the physicochemical characteristics, fungal decay and organoleptic traits of peach, were investigated in the condition 5±2 ̊C and 80% relative humidity during 21 days of storage. According to the results, by increasing Zataria multiflora Bioss extract concentration and whey protein of the coating, microbial decay and weight loss of the fruit was reduced and texture and soluble solids were conserved. Peel colour changes of the coated fruit was not significant compare to control and the coated samples had a light and bright colour. Coating peach resulted in natural ripening of the fruit and the coated fruits were softer and juicier than the fruits without any coating. The coating formulations had significant effect on TSS and TA. Optimized points of variables for achieving a coating with the maximum effect on shelf life improvement of peach (Prunus Persica cv. Anjiri) are: whey protein 4. 7475 gr, Zataria multiflora Bioss extract 498. 00 μL and glycerol 0. 6212 gr.
Fatemeh Hassani; Majid Javanmard; Farzaneh Garousi
Abstract
Edible coating can provide effective protection for fresh fruits. In the present paper we use an edible coating based on whey protein concentrate (WPC) and four different levels of rice bran oil (0, 0.2, 0.4, and 0.6 g/100ml) to maintain the quality of kiwifruit (A. deliciosa). We have tested and compared ...
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Edible coating can provide effective protection for fresh fruits. In the present paper we use an edible coating based on whey protein concentrate (WPC) and four different levels of rice bran oil (0, 0.2, 0.4, and 0.6 g/100ml) to maintain the quality of kiwifruit (A. deliciosa). We have tested and compared the following postharvest storage quality conditions of coated groups and a control group in four subsequent weeks: weight loss, color parameters (L*, a*, b*), texture changes, titratable acidity, soluble solids content, and sensory attributes. Coating application reduced the weight loss in kiwifruits. Our results indicate also a significant difference in the soluble solids content and a non-significant difference in titratable acidity between the control and coated kiwifruits after 4 weeks of storage at 8°C. Moreover, our results show that kiwifruits coated with whey protein concentrate-based coatings had higher L*, and lower a* than the uncoated kiwifruits. Our coated kiwifruits received higher scores than the control samples in sensory evaluations. Coating reduced texture loss up to 5% with respect to the control samples depending on the rice bran oil contents.
Keywords: Kiwifruit, Edible coating, Whey protein concentrate, Rice bran oil, Shelf-life
