Food Technology
Zahra Dehghan; Elnaz Milani; Neda Hashemi
Abstract
IntroductionGastrointestinal diseases are very important among human societies, especially in developing countries. Celiac disease is one of these diseases, caused by the interference of gluten in food, the body's immune system, genetics and environmental factors. Therefore, it is necessary to ...
Read More
IntroductionGastrointestinal diseases are very important among human societies, especially in developing countries. Celiac disease is one of these diseases, caused by the interference of gluten in food, the body's immune system, genetics and environmental factors. Therefore, it is necessary to provide a solution for the production of gluten-free products and also to improve their quality. The tremendous growth in the nutritional knowledge of the public has caused the development and production of healthy food products for certain groups. Baked products such as cookies are very popular among the society because of their textural characteristics as well as flavoring and attractive colors. Therefore, their enrichment is of interest. Most commercial gluten-free bakery products are based on pure starch or the combination of corn starch with gluten-free flour, which is associated with dryness and sandiness in the product. Materials and MethodsThe aim of this research was to investigate the functional characteristics of non-extruded and extruded chickpea flour samples and then the effect of adding different levels of it (0, 20 and 40%) on physicochemical, Lightness, porosity and sensory characteristics using completely randomized factorial design. The blend of chick pea flour- xanthan gum was extruded by a parallel twin-screw extruder (Jinan Saxin, China). Process was performed with die of 3 mm, and extrusion temperature of 140 ℃. The chemical composition of raw materials was measured by standard AOAC (2000) methods. The hardness of cookies was measured using Texture Analyzer (TA plus Ametek, UK). The cylinder steel probe (2 mm diameter) was set to move at a speed of 1 mm/s. Samples were punctured by the probe to a distance of 10 mm. The color values of L* (lightness), a*(redness), b*(yellowness) of the samples were determined by the Hunterlab instrument (Reston VA, US) (Rhee et al., 2004). Water absorption index in terms of grams of bonded water was calculated per gram of dry material in percent. Sensory evaluation was performed using a 5-point hedonic test. Results and DiscussionIn general, gluten-free products are unable to maintain carbon dioxide gas due to the lack of a coherent and uniform gluten network, which causes an increase in volume. As a result, the product is small in volume and the structure of the crumb is compressed. The extrusion baking process had a high potential to improve cookie quality. In such a way that the addition of extruded chickpea flour increased the porosity of the cookie samples. The results of the texture analysis show that the addition of extruded chickpeas up to a 40% improved the texture of the cookie and also increased its shelf life. Also, the sensory test results showed that the favorable effect of adding extruded chickpea flour up to 20%. Consequently, by summarizing the results of physical and sensory tests, it was determined that cookies with appropriate sensory and quality characteristics can be produced using 40% of extruded chickpea flour. Peas, and especially extruded peas, rich in protein and dietary fiber content and high water absorption ability, led to increase the moisture and reduced the hardness of the cookie texture. Considering the increase in demand for gluten-free products, it seems that enriching these products with nutrients such as chickpea flour can be an alternative method to improve the nutritional value of these products. Adding legumes is a good way to increase the consumption of legumes, which are rich in the amino acid lysine. Legumes, especially peas, have high nutritional value and functional characteristics, and including them in the diet by adding them to bakery products is a good way to increase their consumption. The use of chickpea flour as a nutrient source in cookie formulation increases the nutritional value, reduces the glycemic index and improves the variety of such products.
Food Technology
Elham Ghiami; Arash Koocheki; Elnaz Milani
Abstract
Introduction Quinoa, which is known as the mother grain,has higher protein content than common cereals and possesses a large lysine content. Quinoa is composed mainly of carbohydrates (60-75%), of which 10-13% is dietary fiber. Quinoa also has a slightly higher protein content (12-16%) compared ...
Read More
Introduction Quinoa, which is known as the mother grain,has higher protein content than common cereals and possesses a large lysine content. Quinoa is composed mainly of carbohydrates (60-75%), of which 10-13% is dietary fiber. Quinoa also has a slightly higher protein content (12-16%) compared with cereal grains and fat content (5-9%) that is rich in unsaturated fatty acids. Quinoa seeds contain similar or slightly higheramounts of bioactive compounds such as polyphenols (2.7-3.8 g/kg). Moreover, quinoa is gluten-free, thus providing the ability to enhance the selection of gluten-free products forconsumers with celiac disease, but this type of characteristicis challenging to development of bakery products from quinoa with desirable physicochemical properties. Processing of cereal grains and pseudo-cereals into products that deliver a nutritive valueto consumers represents a considerable opportunity for large scale food processing. There havebeen some reported studies on roasting, extrusion, steam pre-conditioning and pearling of quinoafor further uses. Extrusion cooking is a promising technology for improvement of functional properties of quinoa flour. The Evaluation of physicochemical properties and microstructure of Expanded quinoa as affected by extrusion conditions was the main goal of this project. Material and Methods In this study, a parallel twin-screw extruder (Jinan Saxin, China) with die diameter of 3 mm was applied. The effects of extrusion process parameters including feed moisture content (14 and 16%) and die temperature (130, 150 and 170 °C) on final moisture content, bulk density, water absorption index (WAI), color parametersL* (lightness), a*(redness), b*(yellowness), hardness, and microstructure of Expanded quinoa were studied. Extrusion was carried out using a co-rotating twin screw extruder with L/D ratio of 10:1 and die diameter of 4 mm. The feed rate of flour and the screw speed were set at 40 kg/h and 200 rpm, respectively. The physicochemical properties were measured using standard methods. The hardness measurement was performed by a texture analyzer. The cylinder steel probe (2 mm diameter) was set to move at a speed of 1 mm/s The samples were punctured by the probe to a distance of 10 mm . The color parameters of the samples were determined by the Hunterlab machine. The morphology of samples was assessed using a scanning electron microscopy (SEM). Results and Discussion A comprehensive study on impacts of extrusion processing conditions on quinoa flour was conducted. The effect of process variables on the physicochemical attributes of the extrudates was observed. the expanded quinoa with higher feed moisture content had greater moisture and those extruded at higher die temperatures showed lower moisture content (p<0.05). Moisture can reduce the shear force as a plasticizer and increase the amount of moisture absorption of the product. While increasing the die temperature, the effect of shear force on starch dextrification increases and reduces moisture absorption (p<0.05). WAI was significantly influenced by extrusion variables. In fact, feed moisture content and die temperature both positively changed the WAI of quinoa flour so that all extruded samples had significantly higher WAI than the untreated sample (p<0.05). Moreover, the sample with the higher feed moisture content (24%) treated at the highest extrusion temperature (170 °C) showed the largest and lowest water absorption and Hardness respectively (p<0.05). Another important feature of expanded quinoa is the lightness index, the results revealed that extrusion cooking caused a reduction in L* and enhancements in a* and b*. While changes in color parameters were more pronounced at more severe die temperature, higher feed moisture content counteracted the effects of cooking temperature on the color of the products. As expected from changes in the abovementioned color parameters, the sample with lower feed moisture content (16%) treated at the highest extrusion temperature (170 °C) experienced the greatest color change (ΔE). The texture profile analysis (TPA) indicated that higher feed moisture content yielded extrudates with harder texture whereas, extrusion at higher temperature resulted in lower hardness. The scanning electron micrographs showed that the native quinoa flour encompassed both small- and large-sized starch granules while the extruded sample mainly consisted of disaggregated particles. Furthermore, extrusion cooking of samples with higher feed moisture content caused formation of more uniform starch aggregates with smoother surfaces.
Food Technology
Behdad Shokrollahi; Mohammad Ali Hesarinejad; Zahra Zamani; Negin Yousofi; Anna Abdolshahi; Ashkan Jebelli
Abstract
Introduction: Due to increasing the demand for new sources of protein and the lack of animal protein sources, using and replacing of plant proteins is widely considered. The purpose of this study was to identify the potential of Vicia villosa flour as a native and novel source of protein. In this research, ...
Read More
Introduction: Due to increasing the demand for new sources of protein and the lack of animal protein sources, using and replacing of plant proteins is widely considered. The purpose of this study was to identify the potential of Vicia villosa flour as a native and novel source of protein. In this research, the physical properties of vicia villosa seed and chemical composition (protein, fat, ash, and carbohydrate and moisture contents) and color parameters of its full fat flour were determined and compared with defatted flour as well as the effect of defatting and pH on the functional properties of full fat and defatted vicia villosa flour were investigated. Materials and methods: Vicia Villosa seed was obtained from the local market in Chaharmahal and Bakhtiari province and was cleaned, skinned and, milled. Half of the full fat flour was defatted. The obtained flours were then refrigerated at 4°C for further analysis. Physical properties of the seed including size, dimension, mass, true and bulk density as well as porosity were measured using standard methods and calibrated equipments. Chemical composition of both the seed and skinned seed’s flour (moisture content, fat, protein and ash) were determined using standard methods (AACC, 2003). The carbohydrate content of the samples was determined by subtraction of the sum of other compositional substances from 100. Color properties, protein solubility, water soluble index, water and oil absorption capacity, least gelation concentration, foaming capacity and emulsifying capacity and emulsion stability and foaming stability were also measured for the full fat and defatted Vicia Villosa flours. Results and discussion: The results obtained from the measurement of physical properties for the Vicia Villosa seed showed that length, width, and thickness of the seeds were 5.4 mm, 5.37 mm, and 5.38 mm respectively. The surface area of seeds was found to be 90.98 mm2. True density, bulk density, and porosity of samples were found to be 1286.3 mm3, 788.8 mm3, and 38.67%, respectively. The amount of protein for full fat and defatted Vicia Villosa flour was 28.3% and 31.02%, respectively. L* was measured for the obtained flours and the highest L* was belonged to defatted Vicia Villosa flour, probably due to the removal of the seed shells in the solvent removal stage. Defatting of flour would result in brighter and increase in protein content of flour. The test on protein solubility showed the high dependency of this parameter to pH of the flour proving the U form dependency in the pH range of 2-12. At an isoelectric point of 4.5, the minimum solubility of existing proteins was shown. Water and oil absorption capacity of Full fat were 1.33± 0.4 and 0.85± 0.07 and Defatted Vicia Villosa flour,were 1.94± 0.2 and 1.19± 0.1 respectively (grams of water or oil per grams of the sample). Furthermore, at pH= 4.5, the emulsion and foaming capacity decrease due to its proximity to the isoelectric point. It is noteworthy that in isoelectric pH, the highest foaming stability and the lowest emulsion stability were observed. In addition, the results showed that pH and defatting conditions have a significant effect on functional properties that can be created by changing these parameters, flours, and products with various characteristics. The results showed that changes in pH and defatting process affected the solubility, water and fat absorption, least gelation concentration, foaming capacity and emulsion capacity of flour, so that by defatting and changing pH, functional properties improved significantly.
Masoud Taghizadeh; Hesam Akhoondzadeh; Zahra Zamani
Abstract
Introduction: Grains are important food sources for human diet because of high protein content. There are different kinds of grains used as food worldwide. Today herbal proteins play an important role as food sources in societies. Herbal protein sources are actually strategic points for improving national ...
Read More
Introduction: Grains are important food sources for human diet because of high protein content. There are different kinds of grains used as food worldwide. Today herbal proteins play an important role as food sources in societies. Herbal protein sources are actually strategic points for improving national dietary all over the world. (Mashayekh et al, 2008). Food experts are becoming more open to Quinoa, because of high protein content, (Dallagnol et al., 2013). FAO compares Quinoa grain with concentered milk powder considering high nutritional facts, and called grains as multi vitamin (FAO, quinoa, 2011). According to scientific reports quinoa grain can be replaced with rice in national dietary (Ferreira et al, 2015. Oelk et al., 1992). Quinoa originally cultivated in South America (barazil, Chile, Peru etc.) and known as semi-cereals (Schoenlechner&Berghofe2010).Furthermore, Quinoa flour is a highly nutritional alternative to feed animals as well as in the production of foods which are suitable for patients with celiac disease and gluten-sensitive patient worldwide. (Dallagnol et al, 2013). From the technological point of view, functional properties hold an important position, Water and oil absorption capacity, protein solubility, gelatinization capacity, foam ability and foam stability are the most important functional properties. (Kaur and Singh, 2007. Ameri shahrabi, 1390). Functional properties are affected by different parameters such as protein network structure, lipid, carbohydrate, temperature and pH, respectively. (Alukoand Yada, 1995). This study proposed to investigate the physicochemical properties of Quinoa flour of three different varieties and monitor the effect of pH on their functional characteristics Materials and methods: three different variety of Quinoa grain, originated and cultivated in Peru, were used for experiments, varieties were black (BLACK COLLANA), white (SALCEDO INIA) and red (PASANKALLA), respectively. Grains were grind by 75 degree in mesh and refrigerated during storage. Carbohydrate, fat, ash, moisture content and protein were measured by AACC, (2003) methods. Functional properties were also measured using scientific methods, Owusu-Apenten, (2002), Kaur and Singh (2007) and customized Adebowale et al, (2005) method which used to measure protein solubility, Water and oil absorption capacity, foam ability and foam stability, respectively. Emulsion capacity and emulsion stability were measured using majzoobi et al, (2012) method. Results and discussion: chemical properties are important in both technological and nutritional aspects, chemical characteristics were observed and reported for three studied varieties. Protein solubility known as the first criteria in protein functional properties (Asadpour et al., 2010), this parameter is influenced by pH and the least value were observed in pH=4.5 (protein isoelectric point). Water and oil absorption capacity is one of the most important characteristics in flours (Kinsella, 1979), this parameter is a physical phenomenon which is known as oil or water confined in non-polar protein chains that is dependent on protein spatial shape. (Kinsella, 1979؛ Kaur and Singh, 2007؛ Trayunham et al., 2007) responses led to 1.285, 1.475 and 1.295 for white, red and black varieties, respectively. Foam ability and foamstability, actually known as volume increase caused by fast stirring and usually results in convenient rheological properties in products texture like ice cream and bread.this parameter refers to the ability of protein to make stable foam aginst mechanical and Gravitational stresses and measured in a 90 min. period of time (Oladela & Aina,2007) (Kinsella,1979). Least responses in this case were observed in pH=4.5 which is an isoelectric range of pH for protein chains. Results were corresponded by responses of El Nasri and El Tinay (2007), Lawal) 2004(, Taghizadeh et al, (2017) and Asadpour et al (2010) about other semi-cereal grains. Last metered parameter was emulsifying ability and emulsion stability, emulsifying in protein structure is an equilibrium between hydrophilic and hydrophobic parts of protein and affected by alkaline range of pH (Ragab et al., 2003( this parameter is influenced by protein solubility which is in the least measures in isoelectric point (Feizi et al., 2013). Results had shown that foam stability would decrease during time passes. This may be due to the coupling of dispersed phase particles (oil droplets) over time. Concerning the effect of pH on emulsion stability, the results showed that the stability values at alkaline pH were higher than that of acidic pH, so that this stability at pH = 9 was significantly different from other pHs. Among the three varieties of quinoa, the amount of protein in the black variety (16.81%) was higher than the other varieties, which could be further investigated as a potential protein source. In addition, results indicate functional properties are influenced by pH, which means out of iso electric point, protein solubility increase and other fictional properties were improve followed.
Soussene Boudraa; Sara Zidani; Driss Elothmani; Mouni Saadoudi
Abstract
Impact of microwave-grill -drying (MWGD) at different powers (300, 450 and 600 Watts) on functional properties of berry "Russian olive" was investigated. The effect of microwave’s water and oil holding capacities, gelation, foaming and emulsifying, which will provide novel and applicable knowledge ...
Read More
Impact of microwave-grill -drying (MWGD) at different powers (300, 450 and 600 Watts) on functional properties of berry "Russian olive" was investigated. The effect of microwave’s water and oil holding capacities, gelation, foaming and emulsifying, which will provide novel and applicable knowledge for the food industry, was determined. We specifically focused the kinetics drying. By increasing microwave -grill powers (300–600W), drying time decreased from 270 to 120 s. For dried Russain olive berry at each applied microwave-grill power, water holding capacity values were higher than oil holding capacity values. However, drying at 450W is the best method of retention of functional properties of fresh fruit of E.angustifolia L.
Somayeh Niknia; Seyed Mohammad Ali Razavi; Mehdi Varidi
Abstract
In this study, sodium caseinate was hydrolyzed with Withania coagulans extract and the response surface methodology (RSM) was applied to optimize the effects of hydrolysis conditions including hydrolysis temperature, enzyme concentration and hydrolysis time on the degree of hydrolysis, solubility, and ...
Read More
In this study, sodium caseinate was hydrolyzed with Withania coagulans extract and the response surface methodology (RSM) was applied to optimize the effects of hydrolysis conditions including hydrolysis temperature, enzyme concentration and hydrolysis time on the degree of hydrolysis, solubility, and foaming properties. The analysis of variance in RSM showed that the linear effects of enzyme level and hydrolysis time and quadratic effects of hydrolysis temperature were important factors affecting the hydrolysis process remarkably (P<0.0001). Results were indicative of the fact that the increase in responses was obtained by an increase in hydrolysis time and enzyme level. The generated quadratic model showed that the optimum conditions for maximizing the responses were when enzyme concentration of 1.75 (%w/w), temperature of 55.43°C and hydrolysis time of 490 min.
Maryam Mahfoozy; Arash Koocheki; Seyed Mohammad Ali Razavi
Abstract
Introduction: Freezing is one of the ways to extend the shelf life and improve the chemical and microbiological stability of food products. Food products are exposed to different processes and the functional properties of the products change during these processing. Hydrocolloids are used to stabilize ...
Read More
Introduction: Freezing is one of the ways to extend the shelf life and improve the chemical and microbiological stability of food products. Food products are exposed to different processes and the functional properties of the products change during these processing. Hydrocolloids are used to stabilize the products undergoing different food processing. However the addition of hydrocolloids to food products shifts the foods characters. On the other hand, hydrocolloids decrease the growing rate of ice crystals in dispersions. Lipidium perfoliatum locally called Qodume shahri. The study on the functional properties of Lipidium perfoliatum seed gum (LPSG) proved that this gum was able to bind with a large amount of water and increase the product consistency. The main purpose of this study was to understand the effect of freezing condition on functional properties including the rheological properties (steady shear rate), emulsion particle size distribution and foaming stability at different gum concentration of LPSG.
Materials and methods: The materials were purchased from a local detailer. LPSG was extracted in optimum condition (T: 48±1 ºC, pH=8, proportion water to seed 30 to 1, t: 1.5 h) according to method previously described by koocheki et al. (2009). After the preparation of the freeze-dried gum powder, dispersions of LPSG were prepared in distilled water at different concentrations (0.5, 0.75 and 1% w/v). In order to study the effects of freezing condition on the functional properties of LPSG, the samples were freezed at slow and fast conditions. The flow behavior was described by fitting the shear stress (τ) to shear rate (γ) data with the models to determine the best model to describe the flow behavior of LPSG. For the Emulsion preparation, the aqueous phase was prepared by mixing 2 g WPC into 30 g distilled water and an appropriate amount of LPSG (0.1 and 0.2 g) into 50 g distilled water on a magnetic stirrer for 10 min at room temperature. The dispersions were then left overnight at 4 ºC prior to emulsion preparation. The emulsion was prepared by mixing 20 g sunflower oil with WPC using a magnetic stirrer for 10 min. The mixture was subsequently pre-homogenized with a laboratory homogenizer at a rate of 20,000 rpm for 2 min at room temperature. After that, the gum solution was added to the emulsion and homogenized for 4 min at the same rate. The particle size analyzer was used to measure the mean diameter. For the foaming stability, the gum dispersions were prepared at 0.5% gum concentration and left overnight in a refrigerator to ensure a complete hydration. Afterwards, they were treated with different temperatures. 2% of egg white powder was added to the solutions and mixed by a homogenizer for 2 min at 20000 rpm. The foam stability was calculated as the foam volume after 30 minutes. A completely randomized design with the factorial arrangement was used for statistical analysis. All experiments were statistically analysed by Analysis of Variance (ANOVA) in Minitab R14. The p-values of < 0.05 were considered significant. All measurements were triplicated and the average values were reported.
Results and discussion: Results showed that the LPSG apparent viscosity increased insignificantly after the fast freezing condition. All samples illustrated non-Newtonian shear thinning behavior. Herschel- bulkley model was the best model to describe the flow behavior of the LPSG solution with the high determination coefficients. Among the selected rheological models, the flow behavior indices and consistency coefficients were unchanged. However freezing condition had no significant effect on the emulsion particle size. After 30 min foam stabilized by LPSG was constant. Therefore, LPSG can be considered as an appropriate stabilizer and thickening agent during freezing condition.
Masoud Taghizadeh; Behdad Shokrollahi; Fatemeh Hamedi
Abstract
Due to the need to find new protein sources with considering the fact that the bitter vetch seed has high levels of protein content, physicochemical and mechanical properties of bitter vetch seed and functional properties of its flour were evaluated in this study. The effects of altering the pH on protein ...
Read More
Due to the need to find new protein sources with considering the fact that the bitter vetch seed has high levels of protein content, physicochemical and mechanical properties of bitter vetch seed and functional properties of its flour were evaluated in this study. The effects of altering the pH on protein solubility, foaming capacity, foaming stability, emulsion capacity and emulsion stability were studied. The average length, width and height of the grains were 3.5638 mm, 3.6197 mm and 3.8365 mm. the arithmetic and the geometric mean diameter, sphericity and the area were 3.6733mm, 3.6701mm, 1. 0318 and 42.405mm2 respectively. The average true density, bulk density and porosity were 1326.6 kg/m3, 0.7962 kg/m3 and 40.2753% respectively. also the average coefficients of static friction of the plywood, glass, rubber, fiberglass and galvanized iron surface layer were 0.4348, 0.1943, 0.4244, 0.3249 and 0.3739 respectively. Flour produced from this seed contains 24% protein and 9% fat. water and oil absorbing capacity were obtained 2.01 ±0.01 and 1.77±0.03 respectively (grams of water or oil per grams of sample). The results also showed that changes in pH, affected the solubility, foaming capacity, foaming stability, emulsion capacity and emulsion stability of bitter vetch flour.
Sareh Boostani; Marzieh Moosavi-Nasab; Mahmoud Aminlari; Mehrdad Niakosari; Gholam Reza Mesbahi
Abstract
Introduction: Proteins play a fundamental role in biological systems and are often sensitive against organic solvents, heat and other damaging factors. Proteins are the basic component of food formulations and enhancement the functional characteristics and stability of the proteins has always been the ...
Read More
Introduction: Proteins play a fundamental role in biological systems and are often sensitive against organic solvents, heat and other damaging factors. Proteins are the basic component of food formulations and enhancement the functional characteristics and stability of the proteins has always been the main goal of food industry engineers. One of the natural ways used for protein modifications is Maillard reaction. Maillard reaction as a result of covalent binding between the available amino groups of the proteins and carbonyl containing moiety of the polysaccharides, causes a loss in free amino group content of the mixture. Protein- polysaccharide hybrids, as a result of dry heating of two biopolymers mixture under controlled reaction conditions, cause the emergence of conjugates with novel functionalities. Much research has shown that conjugation can increase thermal stability and functional characteristics of food proteins and also reduce the allergenicity of suspected proteins. Although many studies have been conducted on the effects of conjugation on functional properties of proteins, the impacts of conjugation on proteins behavior after food processing have been less investigated. So, in this paper the influences of Maillard reaction on functional properties of soy proteins have been investigated. In addition, characteristics of conjugated proteins after pasteurization treatment was also studied. Materials and methods: Construction of protein- polysaccharide conjugates was done in several steps. First, soy proteins and dextran were mixed with phosphate buffer (0.1 M, pH: 8.5) and 1 to 4 ratio of protein to polysaccharide. After mixing and incubating at ambient temperature for some hours, solutions were frozen at –80 ℃ and freeze dried. Then the lyophilized powder was incubated at different times, at 60℃, under the 79 percent relative humidity in presence of saturated KBr. For each treatment a non conjugated sample was prepared in the exact same condition. Conjugation of proteins to polysaccharides was monitored by SDS-PAGE electrophoresis, browning intensity measurement and UV absorbance analysis. SDS-PAGE was conducted according to Laemmli procedure using a discontinuous buffer system. A vertical gel electrophoresis unit was used with 3% acrylamide stacking gel and 10% acrylamide running gel. Evaluation of the color changes as an indicator of grafting intensity was investigated by monitoring absorption at a wavelength of 420 nm. To investigate the UV absorption of conjugated proteins, the samples were diluted with SDS (Sodium dodecyl sulfate) solution and the absorption was read by a UV-visible spectrophotometer at 294 nm. The impact of modification on characteristics of soy proteins was monitored by examining the functional properties changes of protein samples. In the last stage soy drinks were prepared from conjugated and non conjugated proteins then the prepared beverages were subjected to thermal processing conditions and the influences of Maillard conjugation on the stability of soy drinks was monitored over time. Results and Discussion: SDS-PAGE electrophoresis profile showed that proteins-polysaccharide conjugates were formed. As a result of conjugation, the protein-dextran covalent binding occurs, leads to the formation of higher molecular weight components, resulting in its accumulation on the top of the separating gel. When heating time increased a wider and higher molecular weight bands appeared near the top of the running gel however they were not observed in the native soy pattern. Covalent linkage between amino group of proteins and carbonyl group of polysaccharides causes a color changes from light yellow to brown, browning intensity results showed that the even during early incubation time, a significant absorption was observed at 420 nm compared to the control samples. UV absorption results showed similar trend of changes in browning intensity measurement. Increasing UV absorption is due to the intermediate Maillard reaction products (MRP). Increasing UV absorption with increasing heating time indicates the fact that Maillard reaction products (MRP) formation are more favorable in the long incubation time. Data of UV absorption are a good evidence for SDS-PAGE and browning intensity results. Functional properties results indicated that grafted proteins had better functional properties. The storage stability of soy drinks prepared from conjugated proteins was significantly higher than the samples prepared from non conjugated proteins. Stability of beverages after thermal processing and during storage is one of the most important features of protein drinks and many efforts have been made to develop mentioned characteristics. Stability of soy drinks produced from the conjugated proteins was significantly higher than those prepared from non conjugated soy proteins. Functional characterization of proteins is dependent on several factors, the majority of soy drink composed of proteins that could be denaturated by heating applied during thermal processing, as the results showed conjugation with dextran caused an increase in denaturation temperature of soy proteins which enhance the resistance of proteins during thermal processing treatment. In addition, the solubility and emulsifying properties of soy proteins increased with conjugation which can be a good reason for improvement the relation between protein and surrounding water molecules and therefore increases the protein storage stability. It can be concluded that Maillard reaction could be applied as a means to prepare soy proteins–dextran conjugates with better functional properties and more stable during processing and storage.
Sareh Boostani; Mahmoud Aminlari; Marzieh Moosavi-Nasab; Mehrdad Niakosari; Gholam Reza Mesbahi
Abstract
Introduction : Soybean is an excellent plant protein source with diverse applications in food systems. Despite numerous commercial applications and rich nutritional properties of soybeans, soy proteins are sensitive to heat and other damaging agents during food processing which can limit their applications ...
Read More
Introduction : Soybean is an excellent plant protein source with diverse applications in food systems. Despite numerous commercial applications and rich nutritional properties of soybeans, soy proteins are sensitive to heat and other damaging agents during food processing which can limit their applications in food industries. Maillard reaction includes a series of chemical reactions between the free carbonyl groups of carbohydrates and the un-protonated amino groups of proteins under mild experimental conditions. This is one of the most desirable approaches for applying in food systems, because of the safety of the procedure and the independency of adding extra chemicals. Natural occurring Maillard reaction can be a relatively safe and inexpensive method in order to improve functionalities of food proteins. The production of conjugates haspositive influences on food proteins functionality such as solubility, water holding capacity, emulsion activity and stability, foaming properties, thermal stability, whipping ability, textural and gelation properties and also reduce allergenicity of proteins. Due to the positive characteristics and reasonable price of both soy proteins and maltodextrin in food industries, the aim of current study was to enhance the heat stability and functional properties of soy proteins through glycosylation with maltodextrin. In addition, assessment of changes in protein properties as a function of incubation time were evaluatedMaterials and methods: Preparation of purified soy proteins (Acid precipitated soy proteins) was done by a multistage process of washing, centrifugation, dialysis and freeze drying. The resulting powder contained pure soy globulins. Conjugation of acid precipitated soy proteins with maltodextrin was performed according to the method described as follows: protein-polysaccharide at a weight ratio of 1: 3 were dissolved in 0.01 M phosphate buffer, at pH values of 8, and were incubated at ambient temperature for 1 hr. Solutions were frozen at –80°C and then freeze dried. Lyophilized powders were incubated at 60 °C for 1, 3, 5 and 7 days, under 79% of relative humidity provided by saturated KBr. For each treatment an un-conjugated (control) sample was prepared under the same conditions. The formation of protein-polysaccharide conjugates was confirmed by sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE) and gel filtration chromatography (Sephadex G-100 chromatographic system was used to separate the conjugated proteins from the un conjugated samples). Determination of protein denaturation temperature changes were carried out using METTLER TA Q100-DSC thermal analyser.The emulsifying properties of the samples including emulsifying activity and emulsion stability were assessed according to the procedure established by Pearce and Kinsella. Protein solubility was measured by calculating the amount of nitrogen in the supernatant and total nitrogen content of the samples and reported as percentage of protein solubility at pH 3, 5, 7 and 9. Foaming properties of the samples including foaming capacity and foaming stabilitywere determined using calibrated measuring cylinderDiscussion & Results: When the heating duration is increased, wider and heavier molecular weight bands emerge near the top of the running gel of SDS-PAGE, and yet these were not observed in the control. As a result of conjugation, the protein-carbohydrate covalent binding occurs, producing heavier molecular weight species, and thus leading to its accumulation on top of the separating gel. Compared with un-modified soy proteins, the conjugated soy proteins eluted in the void volume of G-100 gel permeation chromatography column, suggesting increase in the size and molecular weight of soy proteins due to the covalent attachment of maltodextrin. According to differential scanning calorimetry (DSC) analysis, thermal stability of soy proteins was remarkably increased by conjugation with maltodextrin and maximum denaturation temperature was observed for the mixture incubated for 7 days. The improved thermal stability is manifested in increase in denaturation temperature of globular proteins, hence conjugation leads to significant improvement of soy proteins stability. Increase in thermal stability is the result of inclusion of the hydrophilic carbohydrate moiety to the surface of the proteins. Compared to control sample, the solubility, foaming characteristics and emulsifying properties were significantly improved by increasing incubation time. The protein solubility of conjugate remarkably increased at all pH’s compared with the un-conjugated proteins. Covalent links between hydrophilic maltodextrin and soy proteins could enhance the reaction tendency between proteins and water molecules under unfavorable conditions. Improvements in the emulsifying properties of the conjugated samples can be explained by the fact that there is a combination among the emulsifying activity of proteins and the stabilizing impacts of polysaccharides per molecule. Foaming capacity of proteins can be affected by the solubility of proteins. Furthermore, maltodextrin is a hydrophilic carbohydrate which can improve the stability of soy proteins foams by acting as a thickener, thus increasing the strength of bubbles. It should also be considered that functionality of proteins are frequently influenced by protein solubility, and this could also serve the understanding of why improvements occur in functional properties of conjugated proteins, compared to un-conjugated ones. The results indicate that physiochemical and functional properties of soy proteins were modified and improved by conjugation with maltodextrin.
Atefeh Farahmand; Mehdi Varidi; Arash Koocheki
Abstract
Introduction: Exploiting natural substances with dual or multiple functionalities is getting more attention in food industry due to the requirement from the health- conscious consumers and the trends for sustainable environment. Hydrocolloids are high molecular weight macromolecules that can be easily ...
Read More
Introduction: Exploiting natural substances with dual or multiple functionalities is getting more attention in food industry due to the requirement from the health- conscious consumers and the trends for sustainable environment. Hydrocolloids are high molecular weight macromolecules that can be easily dissolved and dispersed in water under appropriate conditions. They can modulate rheological properties of foods, and are generally used as food thickeners, texture modifier, stabilizers and emulsifiers for various applications. Mucilage is a high molecular weight polyuronides consisting of sugar and uronic acid units. It is partially soluble in water and can form highly viscous solution. It exhibits hampering effect on the diffusion of glucose, help to postpone the absorption and digestion of carbohydrates. The mucilage extracted from the seeds of the quince fruit contained cellulose micro-fibrils strongly associated whit a glucuronoxylan possessing a very high proportion of glucuronic acid residues. Analysis of quince seed mucilage (QSM) has shown the presence of more cellulosic fraction and hydrolysable polysaccharide.Quince seed mucilage is one of the endemic hydrocolloids, which due to high viscosity, its extraction needs a method to reduce the extraction time, energy consumption and especially raise the extraction efficiency. The traditional extraction method of polysaccharide from plant tissues are maceration, mechanical rabbling and heat reflux. Theses extraction methods depend largely on energy input and agitation to improve the solubility and mass transfer efficiency of polysaccharides. Usually, the convention extraction method requires long extraction time and high extraction temperature with low extraction yield, but high energy consumption. Ultrasound in combination with conventional extraction is a potential technique, which is a fully reproducible food process, completed in shorter time with high reproducibility, reduced processing cost, simplified manipulation and work-up. To achieve this goal, in this study ultrasound- assisted extraction (UAE) as a novel extraction method was used.Materials andMethods:Quince seed used in this study was purchased from a local market (KhorasanRazavi, Mashhad). They were cleaned manually by removing the foreign matter such as stones, dirt and broken seeds. They were packed in hermetic plastic vessels and stored at 5ºC until further use. For mucilage extraction, first conventional extraction was optimized to select the best hydration conditions and after that UAE (24 KHz probe and 400 W power) was performed at three different levels of intensity (20, 60 and 100%) and times (5, 15 and 30 min).All chemicals used were analytical grades. Yield value of hydrocolloid was calculated by dividing the weight of dried hydrocolloid by the weight of initial dry seeds. Emulsion heat stability was determines by the method described in previous studies. In order to measuring the water absorption capacity (WAC), 0.05 g of mucilage was added to deionized water until QSM was completely wet (~ 10ml). The tubes were then centrifuged at 1600×g for 10 min. Excess water was discarded and residue was weighted. Apparent viscosity of QSM solution with 0.1% (w/v) concentration was measured using a rotational viscometer (Brookfield, DV- ІІІ, USA). Shear rate increased linearly from 2.5 - 35 s-1 at 25˚C.For measuring the foam stability and emulsion heat stability, the mucilage dispersions were prepared at 0.25 and 0.5 (w/v) respectively, and kept overnight at 4˚C. After complete hydration, 2% (w/v) egg white powder was added and then foamed by whipping at 8600 rpm for 2 min using adisperser.Results and Discussion: Optimized conditions of conventional extraction were 45 min, 47˚C and 32.5: 1 water to seed ratio. The results showed that extraction at 30 min with 100% intensity raised the extraction yield to 42.7% in comparison with control sample.Improvement in hydrocolloid extraction by ultrasound is attributed to ultrasound pressure wave diffusion which results in cavitation phenomenon.Amplitude level and exposure time had a significant (p
Samira Feyzi; Mehdi Varidi; Fatemeh Zare; Mohammad Javad Varidi
Abstract
Introduction: Plant proteins play a significant role in the human diet, and among which legumes are excellent foods with several nutritional and functional advantages and low price. Among legumes, fenugreek (Trigonella foenum graecum) seed, belonging to the Fabaceae family, is a great source of plant ...
Read More
Introduction: Plant proteins play a significant role in the human diet, and among which legumes are excellent foods with several nutritional and functional advantages and low price. Among legumes, fenugreek (Trigonella foenum graecum) seed, belonging to the Fabaceae family, is a great source of plant proteins, with a total protein content of about 25.00 – 38.60%. Functional properties are defined as physical and chemical properties, which could be altered due to the protein source and procedures used for flour preparation, protein concentrate and isolate extraction. Physiochemical parameters such as pH, temperature, salt and ionic strength can also highly affect proteins, functional properties.Therefore, in this study color parameters and functional properties of fenugreek protein isolate (FPI) were investigated. Also, the effect of pH changes on protein solubility, foaming capacity (FC) and stability (FS), emulsifying capacity (EC) and stability (ES) was studied. Materials and methods: Fenugreek seeds were obtained from a retail market in Isfahan, Iran. All chemicals were of analytical grade, and were purchased from Sigma Chemical Co. (St Louis, MO, USA), and Merck KGaA (Darmstadt, Germany). Protein Isolation: Protein from 10g defatted fenugreek flour (DFF) was extracted with 0.33M sodium chloride solution; the ratio of DFF to NaCl solution was set at 1:20 (w/v) and pH was adjusted to 9.25. The stirring period was 2 h, during which pH was also adjusted. Aliquots were then centrifuged and supernatants were adjusted to pH 4.5 (isoelectric pH of fenugreek protein). Again, the protein solution was centrifuged in order to precipitate the protein. Protein precipitate was washed twice with deionized water, followed by centrifugation and resolubiliztion by adjusting the pH to 7.2. The extraction process was carried out at room temperature (25°C). Color parameters: A digital colorimeter was used to measure the color of full fat and defatted fenugreek flours, and FPI samples. Color parameters were recorded in L*a*b* space. Protein solubility: Protein solubility of FPI at pH 2-10 was determined. A 1.5% (w/v) solution of sample was made in deionized water for each pH. The solutions were treated with either 0.5M HCl or 0.5M NaOH to obtain certain pH (2-10), while stirring. The slurry was centrifuged to separate the supernatant. Protein content was determined by the Biuret method using spectrophotometer at 540nm wavelength. Calibration was done using bovine serum albumin (BSA) as external standard. Viscosity: A suspension of 5% (w/v) FPI in distilled water was prepared. Viscosity of sample was determined using a programmable Brookfeildrheometer, using spindle ULA at room temperature. Coagulated protein: Percent of coagulated protein was measured by preparing 0.2g of FPI in 10mL of 0.025M citrate-phosphate buffer (pH 7.0). The solution was stirred, followed by centrifugation. The remaining supernatant was heated for 15min in a 100°C water bath, after cooling the same procedure was repeated. The absorbance of both samples, before heating (A1) and after heating (A2), was measured at 540nm according to Biuret method. The percent of coagulated protein was calculated by the following equation: Coagulated protein = (A1 – A2 / A1) × 100 (1) Foaming capacity and stability: FC and FS were determined using 2% (w/v) FPI solution in distilled water. For each sample solution, the pH was adjusted to desired level (2, 3, 4.5, 6, 8, and 10). The solution was stirred slightly for 5min and then was whipped vigorously by a disperser. The volume of solution before whipping, also the total volume of solution and foam after whipping were recorded as V0 and V1, respectively. The foam capacity percentage was calculated as: FC (%) = (V1- V0/V0) × 100 (2) Foam stability was determined as the total volume of solution and foam at 30, 60, 90 and 120 min at room temperature and it was recorded as V2. Foam stability (FS) was calculated as: FS (%) = (V2 - V0) × 100/ (V1 - V0) (3) Emulsifying capacity and stability:For EC and ES, a 1% (w/v) FPI solution in distilled water was prepared. The pH was adjusted to desirable level (2, 3, 4.5, 6, 8, and 10) followed by stirring for 5min, then sunflower oil was added. The mixture was homogenized to make emulsion, followed by centrifugation. Then the height of both emulsified layer after centrifugation (H1) and the total height of content before centrifugation (H0) were measured. Emulsion capacity was calculated as: EC (%) = (H1/H0) × 100 (4) The ES (%) was calculated at 0, 30, 60, 90 and 120 min by measuring height changes (H2). ES (%) = (H2/ H1) × 100 (5) Results and Discussion: FPI with 89.1% protein content had significantly (p < 0.05) lower L* than DFF, while its L* was higher than the full fat fenugreek flour. Also, FPI showed shear thinning behavior with viscosity equal to 1150, 922.5 and 787.5 cP at 15, 30 and 50 (1/s) shear rates, respectively. pH changes had noticeable effect (p
Maryam Ravaghi; Mostafa Mazaheri Tehrani; Ahmad Asoodeh
Abstract
Soy protein concentrate (SPC) is a functional and nutritional product which is produced under conditions where soy proteins are immobilized in soy flour and soluble carbohydrates are removed. In this study, four different soy flours including defatted soy flour (fat content 3.67, PDI 55.10), defatted ...
Read More
Soy protein concentrate (SPC) is a functional and nutritional product which is produced under conditions where soy proteins are immobilized in soy flour and soluble carbohydrates are removed. In this study, four different soy flours including defatted soy flour (fat content 3.67, PDI 55.10), defatted and toasted soy flour (fat content 3.78, PDI 10.72), low fat soy flour (fat content 14.34, PDI 32.71), and whole soy flour (fat content 22.08, PDI 28.72) and two washing methods including alcohol washing and acid washing were used to produce SPC Then yield, changes in chemical and functional properties including PDI, dispersible solids, water holding and fat binding capacity, emulsifying and foaming properties were determined. The results showed that SPC from whole soy flour had higher yield and higher increase in fat content but presence of fat reduced protein concentration. Acid washing had lower production yield than alcohol washing due to better removalg of soluble carbohydrates but it increased fat and protein content. Functional properties of SPC from defatted soy flour was changed significantly during its process while fat content or heat denaturation occurred during toasting diminished its effect except for emulsification stability. During the process, water holding capacity increased specially in products with higher amounts of fat content. Although most of PDI changes arose from drying step, but the effect of processing on emulsification and foaming properties was much higher than drying.
