Search

Your search keyword '"Kuktaite, R."' showing total 66 results
Start Over Author "Kuktaite, R."
66 results on '"Kuktaite, R."'

7. Impact of gluten separation process and transglutaminase source on gluten based dough properties

Author

Ceresino, E. B., Kuktaite, R., Sato, H. H., Hedenqvist, Mikael S., Johansson, E., Ceresino, E. B., Kuktaite, R., Sato, H. H., Hedenqvist, Mikael S., and Johansson, E.

Abstract

This study evaluated the effect of the wheat gluten (WG) separation process and transglutaminase (TG) microbial source on WG dough quality, and opportunities to use these factors to tailor dough quality. Two types of gluten (harshly and mildly separated), two types of TG (commercial and novel SB6), and three TG concentrations were evaluated for effects on dough mixing properties, protein structure and solubility. Mildly separated gluten improved dough development parameters, resulting into higher values of most compared with harshly separated gluten. Despite more strongly cross-linked proteins being found in the harshly separated gluten, both gluten types showed similar levels of cross-linking at optimum mixing time, although differences in the secondary protein structure were indicated. Thus, disulfide-sulfhydryl exchange reactions were found to be promoted by mixing, although restrictions on establishment of new bonds because of prior cross-links in the material were clearly indicated. Degree of polymerization in doughs made from mildly separated gluten increased to varying extents with TG addition depending on TG source and concentration. Thus, for the first time, we show that an appropriate combination of WG separation procedure and TG source can be used to tailor gluten dough end-use properties., QC 20181120

Published
2019
Full Text
View/download PDF

8. Effect of extraction routes on protein content, solubility and molecular weight distribution of Crambe abyssinica protein concentrates and thermally processed films thereof

Author

Newson, W. R., Prieto-Linde, M. L., Kuktaite, R., Hedenqvist, Mikael S., Gällstedt, M., Johansson, E., Newson, W. R., Prieto-Linde, M. L., Kuktaite, R., Hedenqvist, Mikael S., Gällstedt, M., and Johansson, E.

Abstract

To understand if and how extraction conditions influence properties of molded protein films, Crambe abyssinica protein concentrates were produced from deoiled seed meal under various extraction conditions. Properties of the resulting hot compression molded films were evaluated through the molecular weight distribution, protein polymerization behavior and tensile tests. Precipitated protein concentrates demonstrated higher protein content and a pronounced shift to higher molecular weight distributions and reduced solubility on heating, indicating increased protein polymerization compared to those from lyophilized supernatants. Thermally processed films from isoelectrically precipitated protein concentrates show a high resistance to extraction with a combination of reducing agent and denaturant, indicating the presence of non-disulfide covalent cross linking. Also, tensile strength was higher in concentrates from precipitated proteins compared to those from supernatants. The protein concentrates resulting in thermally processed films with a high protein content, the highest levels of protein-protein interaction and high tensile strength were based on alkaline extraction and isoelectric precipitation. Therefore, a combination of alkali extraction and isoelectric precipitation is recommended to produce protein concentrates for molded film production., QC 20170208

Published
2017
Full Text
View/download PDF

9. Commercial potato protein concentrate as a novel source for thermoformed bio-based plastic films with unusual polymerisation and tensile properties

Author

Newson, W. R., Rasheed, F., Kuktaite, R., Hedenqvist, Mikael S., Gällstedt, M., Plivelic, T. S., Johansson, E., Newson, W. R., Rasheed, F., Kuktaite, R., Hedenqvist, Mikael S., Gällstedt, M., Plivelic, T. S., and Johansson, E.

Abstract

Commercial potato protein concentrate (PPC) was investigated as a source of thermoformed bio-based plastic film. Pressing temperatures of 100 to 190°C with 15 to 25% glycerol were used to form PPC films. The shape of the tensile stress-strain curve in thermoformed PPC was controlled by glycerol level and was independent of processing temperature. Tensile testing revealed that elongation at break increased with processing temperature while Young's modulus was unaffected by processing temperature, both in contrast to previous results in protein based systems. Also in contrast to previous studies, Young's modulus was found to be only sensitive to glycerol level. Maximum tensile stress increased with increasing processing temperature for PPC films. Maximum stress and strain at break correlated with the extractable high molecular weight protein content of the processed films measured with size exclusion chromatography. Infrared absorption indicated that the content of β-sheet structure increased from the commercial protein concentrate to that pressed at 100°C, but did not further develop with increasing press temperature. Changes in structural arrangements were observed by small angle X-ray scattering indicating the development of different correlation distances with processing temperature but with no clear long range order at the supramolecular level. The novel Young's modulus behaviour appears to be due to constant secondary structure or the effect of aggregated protein structure formed during protein production. Unique strain at break behaviour with processing temperature was demonstrated, likely due to new connections formed between those aggregates., QC 20150609

Published
2015
Full Text
View/download PDF

13. Wheat gluten polymer structures : The impact of genotype, environment, and processing on their functionality in various applications

Author

Johansson, E., Malik, A. H., Hussain, A., Rasheed, F., Newson, W. R., Plivelic, T., Hedenqvist, Mikael S., Gällstedt, M., Kuktaite, R., Johansson, E., Malik, A. H., Hussain, A., Rasheed, F., Newson, W. R., Plivelic, T., Hedenqvist, Mikael S., Gällstedt, M., and Kuktaite, R.

Abstract

For a number of applications, gluten protein polymer structures are of the highest importance in determining end-use properties. The present article focuses on gluten protein structures in the wheat grain, genotype- and environment-related changes, protein structures in various applications, and their impact on quality. Protein structures in mature wheat grain or flour are strongly related to end-use properties, although influenced by genetic and environment interactions. Nitrogen availability during wheat development and genetically determined plant development rhythm are the most important parameters determining the gluten protein polymer structure, although temperature during plant development interacts with the impact of the mentioned parameters. Glutenin subunits are the main proteins incorporated in the gluten protein polymer in extracted wheat flour. During dough mixing, gliadins are also incorporated through disulfide-sulfhydryl exchange reactions. Gluten protein polymer size and complexity in the mature grain and changes during dough formation are important for breadmaking quality. When using the gluten proteins to produce plastics, additional proteins are incorporated in the polymer through disulfide-sulfhydryl exchange, sulfhydryl oxidation, β-eliminations with lanthionine formation, and isopeptide formation. In promising materials, the protein polymer structure is changed toward β-sheet structures of both intermolecular and extended type and a hexagonal close-packed structure is found. Increased understanding of gluten protein polymer structures is extremely important to improve functionality and end-use quality of wheat- and gluten-based products., QC 20131120

Published
2013
Full Text
View/download PDF

14. Changes in the hierarchical protein polymer structure : Urea and temperature effects on wheat gluten films

Author

Kuktaite, R., Plivelic, T. S., Türe, Hasan, Hedenqvist, Mikael S., Gällstedt, M., Marttila, S., Johansson, E., Kuktaite, R., Plivelic, T. S., Türe, Hasan, Hedenqvist, Mikael S., Gällstedt, M., Marttila, S., and Johansson, E.

Abstract

Understanding bio-based protein polymer structures is important when designing new materials with desirable properties. Here the effect of urea on the wheat gluten (WG) protein structure in WG-urea films was investigated. Small-angle X-ray scattering indicated the formation of a hexagonal close-packed (HCP) hierarchical structure in the WG-urea materials. The HCP structure was influenced significantly by the urea concentration and processing conditions. The interdomain distance d I between the HCP scattering objects increased with increasing content of urea and the objects seemed to be oriented in the extrusion direction. Additionally, the effect of temperature on the HCP structure was studied and it was shown that at ≥55°C the HCP structure disappeared. Transmission electron microscopy revealed a rather denatured pattern of both HMW-glutenins and gliadins in the WG-urea films. The molecular packing of the WG protein polymer can be highly affected by an additive and the processing method used., QC 20121214

Published
2012
Full Text
View/download PDF

15. Novel freeze-dried foams from glutenin- and gliadin-rich fractions

Author

Blomfeldt, Thomas O. J., Kuktaite, R., Plivelic, T. S., Rasheed, F., Johansson, E., Hedenqvist, Mikael S., Blomfeldt, Thomas O. J., Kuktaite, R., Plivelic, T. S., Rasheed, F., Johansson, E., and Hedenqvist, Mikael S.

Abstract

This is the first study on freeze-dried foams prepared from glutenin- and gliadin-rich fractions of wheat gluten and blends thereof. It was found that the foam density and stiffness could be controlled by a suitable choice of the glutenin/gliadin ratio. The glutenin-rich samples had the highest foam densities and the density decreased with increasing gliadin content. The compression modulus also decreased with increasing gliadin content, which was explained by the decrease in foam density, a more open porosity and the more aggregated/polymerized structure in the presence of glutenin. IR and SE-HPLC revealed that the least aggregated foams were those consisting only of the gliadin-rich fraction. Confocal laser scanning microscopy revealed the presence of both HMW-glutenin and gliadin (to a certain extent probably resisting the ethanol extraction process) in the glutenin-rich foams. SAXS indicated that the gliadin-rich fraction contributed with weakly correlated protein aggregates with a characteristic distance of 40-43 Å., QC 20120807

Published
2012
Full Text
View/download PDF

16. Application of accelerometry in the research of human body balance

Author

Kilikevicius, A., Malaiškaite, D., Tamošauskas, P., Morkuniene, V., Višinskiene, D., Kuktaite, R., Kilikevicius, A., Malaiškaite, D., Tamošauskas, P., Morkuniene, V., Višinskiene, D., and Kuktaite, R.

Abstract

This article provides methods for evaluating the parameters of human body balance by applying accelerometry and evaluates the impact of physical load on the balance parameters. The presented research work aims at assessing and comparing the parameters of static balance in comparatively healthy adults (20-25 years old) before and after physical activity.

Published
2012

17. Effects of fiber blending and diamines on wheat gluten materials reinforced with hemp fiber

Author

Wretfors, Christer, Cho, Sung-Woo, Kuktaite, R., Hedenqvist, Mikael S., Marttila, S, Nimmermark, S, Johansson, Eva, Wretfors, Christer, Cho, Sung-Woo, Kuktaite, R., Hedenqvist, Mikael S., Marttila, S, Nimmermark, S, and Johansson, Eva

Abstract

Wheat gluten (WG) is a promising base material for production of "green" plastics, although reinforcement is needed in more demanding applications. Hemp fiber is a promising reinforcement source but difficulties exist in obtaining desired properties with a WG-based matrix. This study aimed at improving fiber dispersion and fiber-matrix interactions using a high speed blender and a diamine as a cross-linker. Samples were manufactured using compression molding, two types of blenders and addition of diamine. Mechanical properties were assessed with tensile testing. Tensile-fractured surfaces were examined with scanning electron microscopy (SEM). Protein polymerization and fiber-protein matrix interactions were examined using high performance liquid chromatography (HPLC) and confocal laser scanning microscopy (CLSM). The results showed that a higher-speed grinding yielded a more even distribution of fibers and a more polymerized protein structure compared to a lower-speed grinding. However, these improvements did not result in increased strength, stiffness, and extensibility for the higher-speed grinding. The strength was increased when the grinding was combined with addition of a diamine (Jeffamine(R) EDR-176). HPLC, SEM, and CLSM, indicated that diamine added samples showed a more "plastic" appearance together with a stiffer and stronger structure with less cracking compared to samples without diamine. The use of the diamine also led to an increased polymerization of the proteins, although no effect on the fiber-protein matrix interactions was observed using microscopical techniques. Thus, for future successful use of hemp fibers to reinforce gluten materials, an appropriate method to increase the fiber-protein matrix interaction is needed., QC 20100708

Published
2010
Full Text
View/download PDF

24. The Influence of Dough Mixing Time on Wheat Protein Composition and Gluten Quality for Four Commercial Flour Mixtures.

Author

Buck, H. T., Nisi, J. E., Salomón, N., Kuktaite, R., Larsson, H., and Johansson, E.

Abstract

The effect of mixing time on wheat protein composition and gluten formation was studied for three commercial flour mixtures (biscuit, standard and strong) and one durum flour. Ultracentrifugation was used to separate the fresh, wet gluten from the wheat-flour dough immediately after mixing. Small deformation dynamic rheological measurements and RP- and SE-HPLC were used to determine the characteristics of the network formed, and the protein composition, respectively The gluten water content increased due to overmixing for most of the flours. However, no effect of mixing was observed for the storage modulus (G′) of gluten for any of the flours. The value of G′ of gluten was around 3, 3, 4 and 8 for Standard, Biscuit, Strong and Durum flour, respectively. Therefore, the increased water content during prolonged mixing was not related to the effect on G′ . The strong flour resulted in the lowest G′ for dough, a high G′ for gluten and no increase in gluten water content with overmixing. The weaker standard flour resulted in the highest gluten water content, which increased considerably with mixing time. The durum flour did not show gluten development and breakdown similar to the other flours. The differences in large UPP, total UPP and large UMP between gluten from the different flours and mixing times originated from the genetic composition of flour proteins [ABSTRACT FROM AUTHOR]

Published
2007
Full Text
View/download PDF

25. Alien introgression to wheat for food security: functional and nutritional quality for novel products under climate change.

Author

Johansson E, Lan Y, Olalekan O, Kuktaite R, Chawade A, and Rahmatov M

Abstract

Crop yield and quality has increased globally during recent decades due to plant breeding, resulting in improved food security. However, climate change and shifts in human dietary habits and preferences display novel pressure on crop production to deliver enough quantity and quality to secure food for future generations. This review paper describes the current state-of-the-art and presents innovative approaches related to alien introgressions into wheat, focusing on aspects related to quality, functional characteristics, nutritional attributes, and development of novel food products. The benefits and opportunities that the novel and traditional plant breeding methods contribute to using alien germplasm in plant breeding are also discussed. In principle, gene introgressions from rye have been the most widely utilized alien gene source for wheat. Furthermore, the incorporation of novel resistance genes toward diseases and pests have been the most transferred type of genes into the wheat genome. The incorporation of novel resistance genes toward diseases and pests into the wheat genome is important in breeding for increased food security. Alien introgressions to wheat from e.g. rye and Aegilops spp. have also contributed to improved nutritional and functional quality. Recent studies have shown that introgressions to wheat of genes from chromosome 3 in rye have an impact on both yield, nutritional and functional quality, and quality stability during drought treatment, another character of high importance for food security under climate change scenarios. Additionally, the introgression of alien genes into wheat has the potential to improve the nutritional profiles of future food products, by contributing higher minerals levels or lower levels of anti-nutritional compounds into e.g., plant-based products substituting animal-based food alternatives. To conclude, the present review paper highlights great opportunities and shows a few examples of how food security and functional-nutritional quality in traditional and novel wheat products can be improved by the use of genes from alien sources, such as rye and other relatives to wheat. Novel and upcoming plant breeding methods such as genome-wide association studies, gene editing, genomic selection and speed breeding, have the potential to complement traditional technologies to keep pace with climate change and consumer eating habits., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2024 Johansson, Lan, Olalekan, Kuktaite, Chawade and Rahmatov.)

Published
2024
Full Text
View/download PDF

26. New Insights into the Bio-Chemical Changes in Wheat Induced by Cd and Drought: What Can We Learn on Cd Stress Using Neutron Imaging?

Author

Lan Y, Burca G, Yong JWH, Johansson E, and Kuktaite R

Abstract

Cadmium (Cd) and drought stresses are becoming dominant in a changing climate. This study explored the impact of Cd and Cd + drought stress on durum wheat grown in soil and sand at two Cd levels. The physiological parameters were studied using classical methods, while the root architecture was explored using non-invasive neutron computed tomography (NCT) for the first time. Under Cd + drought, all the gas exchange parameters were significantly affected, especially at 120 mg/kg Cd + drought. Elevated Cd was found in the sand-grown roots. We innovatively show the Cd stress impact on the wheat root volume and architecture, and the water distribution in the "root-growing media" was successfully visualized using NCT. Diverse and varying root architectures were observed for soil and sand under the Cd stress compared to the non-stress conditions, as revealed using NCT. The intrinsic structure of the growing medium was responsible for a variation in the water distribution pattern. This study demonstrated a pilot approach to use NCT for quantitative and in situ mapping of Cd stress on wheat roots and visualized the water dynamics in the rhizosphere. The physiological and NCT data provide valuable information to relate further to genetic information for the identification of Cd-resilient wheat varieties in the changing climate.

Published
2024
Full Text
View/download PDF

27. Chasing high and stable wheat grain mineral content: Mining diverse spring genotypes under induced drought stress.

Author

Lan Y, Kuktaite R, Chawade A, and Johansson E

Subjects
Minerals, Genotype, Plant Structures, Triticum genetics, Droughts
Abstract

Climate change-induced drought has an effect on the nutritional quality of wheat. Here, the impact of drought at different plant stages on mineral content in mature wheat was evaluated in 30 spring-wheat lines of diverse backgrounds (modern, old and wheat-rye-introgressions). Genotypes with rye chromosome 3R introgression showed a high accumulation of several important minerals, including Zn and Fe, and these also showed stability across drought conditions. High Se content was found in genotypes with chromosome 1R. Old cultivars (K, Mg, Na, P and S) and 2R introgression lines (Fe, Ca, Mn, Mg and Na) demonstrated high mineral yield at early and late drought, respectively. Based on the low nutritional value often reported for modern wheat and negative climate effects on the stability of mineral content and yield, genes conferring high Zn/Fe, Se, and stable mineral yield under drought at various plant stages should be explicitly explored among 3R, 1R, old and 2R genotypes, respectively., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Lan et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published
2024
Full Text
View/download PDF

28. Green Chemistry to Modify Functional Properties of Crambe Protein Isolate-Based Thermally Formed Films.

Author

Newson WR, Capezza AJ, Kuktaite R, Hedenqvist MS, and Johansson E

Abstract

Proteins are promising precursors to be used in production of sustainable materials with properties resembling plastics, although protein modification or functionalization is often required to obtain suitable product characteristics. Here, effects of protein modification were evaluated by crosslinking behavior using high-performance liquid chromatography (HPLC), secondary structure using infrared spectroscopy (IR), liquid imbibition and uptake, and tensile properties of six crambe protein isolates modified in solution before thermal pressing. The results showed that a basic pH (10), especially when combined with the commonly used, although moderately toxic, crosslinking agent glutaraldehyde (GA), resulted in a decrease in crosslinking in unpressed samples, as compared to acidic pH (4) samples. After pressing, a more crosslinked protein matrix with an increase in β-sheets was obtained in basic samples compared to acidic samples, mainly due to the formation of disulfide bonds, which led to an increase in tensile strength, and liquid uptake with less material resolved. A treatment of pH 10 + GA, combined either with a heat or citric acid treatment, did not increase crosslinking or improve the properties in pressed samples, as compared to pH 4 samples. Fenton treatment at pH 7.5 resulted in a similar amount of crosslinking as the pH 10 + GA treatment, although with a higher degree of peptide/irreversible bonds. The strong bond formation resulted in lack of opportunities to disintegrate the protein network by all extraction solutions tested (even for 6 M urea + 1% sodium dodecyl sulfate + 1% dithiothreitol). Thus, the highest crosslinking and best properties of the material produced from crambe protein isolates were obtained by pH 10 + GA and pH 7.5 + Fenton, where Fenton is a greener and more sustainable solution than GA. Therefore, chemical modification of crambe protein isolates is effecting both sustainability and crosslinking behavior, which might have an effect on product suitability., Competing Interests: The authors declare no competing financial interest., (© 2023 The Authors. Published by American Chemical Society.)

Published
2023
Full Text
View/download PDF

29. Impacts of heat, drought, and combined heat-drought stress on yield, phenotypic traits, and gluten protein traits: capturing stability of spring wheat in excessive environments.

Author

Lama S, Leiva F, Vallenback P, Chawade A, and Kuktaite R

Abstract

Wheat production and end-use quality are severely threatened by drought and heat stresses. This study evaluated stress impacts on phenotypic and gluten protein characteristics of eight spring wheat genotypes (Diskett, Happy, Bumble, SW1, SW2, SW3, SW4, and SW5) grown to maturity under controlled conditions (Biotron) using RGB imaging and size-exclusion high-performance liquid chromatography (SE-HPLC). Among the stress treatments compared, combined heat-drought stress had the most severe negative impacts on biomass (real and digital), grain yield, and thousand kernel weight. Conversely, it had a positive effect on most gluten parameters evaluated by SE-HPLC and resulted in a positive correlation between spike traits and gluten strength, expressed as unextractable gluten polymer (%UPP) and large monomeric protein (%LUMP). The best performing genotypes in terms of stability were Happy, Diskett, SW1, and SW2, which should be further explored as attractive breeding material for developing climate-resistant genotypes with improved bread-making quality. RGB imaging in combination with gluten protein screening by SE-HPLC could thus be a valuable approach for identifying climate stress-tolerant wheat genotypes., Competing Interests: Author PV is employed by company Lantmännen Lantbruk. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2023 Lama, Leiva, Vallenback, Chawade and Kuktaite.)

Published
2023
Full Text
View/download PDF

30. Screening of Spore-Forming Bacteria with Probiotic Potential in Pristine Algerian Caves.

Author

Rehamnia B, Lee NM, Kuktaite R, and Kacem Chaouche N

Subjects
Humans, Algeria, Lactose, Ecosystem, Bacteria, Spores, Anti-Bacterial Agents pharmacology, beta-Galactosidase, Gliadin, Probiotics
Abstract

The interest and exploration of biodiversity in subsurface ecosystems have increased significantly during the last 2 decades. The aim of this study was to investigate the in vitro probiotic properties of spore-forming bacteria isolated from deep caves. Two hundred fifty spore-forming microbes were enriched from sediment samples from 10 different pristine caves in Algeria at different depths. Isolates showing nonpathogenic profiles were screened for their potential to produce digestive enzymes (gliadinase and beta-galactosidase) in solid and liquid media, respectively. Different probiotic potentialities were studied, including (i) growth at 37°C, (ii) survival in simulated gastric juice, (iii) survival in simulated intestinal fluid, and (iv) antibiotic sensitivity and cell surface properties. The results showed that out of 250 isolates, 13 isolates demonstrated nonpathogenic character, probiotic potentialities, and ability to hydrolyze gliadin and lactose in solution. These findings suggest that a selection of cave microbes might serve as a source of interesting candidates for probiotics. IMPORTANCE Previous microbial studies of subsurface ecosystems like caves focused mainly on the natural biodiversity in these systems. So far, only a few studies focused on the biotechnological potential of microbes in these systems, focusing in particular on their antibacterial potential, antibiotic production, and, to some extent, enzymatic potential. This study explores whether subsurface ecosystems can serve as an alternative source for microbes relevant to probiotics. The research focused on the ability of cave microbes to degrade two substrates (lactose and gliadin) that cause common digestive disorders. Since these enzymes may prove to be useful in food processing and in reducing the effect of lactose and gliadin digestion within intolerant patients, isolation of microbes such as in this study may expand the possibilities of developing alternative strategies to deal with these intolerances.

Published
2022
Full Text
View/download PDF

31. Striving for Stability in the Dough Mixing Quality of Spring Wheat under the Influence of Prolonged Heat and Drought.

Author

Lama S, Kuzmenkova M, Vallenback P, and Kuktaite R

Abstract

The effects of prolonged heat and drought stress and cool growing conditions on dough mixing quality traits of spring wheat ( Triticum aestivum L.) were studied in fifty-six genotypes grown in 2017 and 2018 in southern Sweden. The mixing parameters evaluated by mixograph and the gluten protein characteristics studied by size exclusion high-performance liquid chromatography (SE-HPLC) in dough were compared between the two growing seasons which were very different in length, temperature and precipitation. The genotypes varying in gluten strength between the growing seasons (≤5%, ≤12%, and ≤17%) from three groups (stable (S), moderately stable (MS), and of varying stability (VS)) were studied. The results indicate that most of the mixing parameters were more strongly impacted by the interaction between the group, genotype, and year than by their individual contribution. The excessive prolonged heat and drought did not impact the buildup and mixing time expressed as peak time and time 1-2. The gluten polymeric proteins (unextractable, %UPP; total unextractable, TOTU) and large unextractable monomeric proteins (%LUMP) were closely associated with buildup and water absorption in dough. Major significant differences were found in the dough mixing parameters between the years within each group. In Groups S and MS, the majority of genotypes showed the smallest variation in the dough mixing parameters responsible for the gluten strength and dough development between the years. The mixing parameters such as time 1-2, buildup, and peak time (which were not affected by prolonged heat and drought stress) together with the selected gluten protein parameters (%UPP, TOTU, and %LUMP) are essential components to be used in future screening of dough mixing quality in wheat in severe growing environments.

Published
2022
Full Text
View/download PDF

32. Innovatively processed quinoa (Chenopodium quinoa Willd.) food: chemistry, structure and end-use characteristics.

Author

Kuktaite R, Repo-Carrasco-Valencia R, de Mendoza CC, Plivelic TS, Hall S, and Johansson E

Subjects
Dietary Fiber analysis, Flour analysis, Starch chemistry, Temperature, Chenopodium quinoa chemistry
Abstract

Background: Quinoa (Chenopodium quinoa Willd.) flour and processed traditional Peruvian quinoa breakfast foods were studied to evaluate the effect of extrusion and post-processing on protein properties, morphology and nutritional characteristics (amino acids and dietary fibers)., Results: The extrusion increased quinoa protein crosslinking and aggregation observed by size exclusion high-performance liquid chromatography and the amount of soluble fibers, as well as decreasing the amounts of insoluble fibers in the processed foods. The post-processing drying resulted in additional crosslinking of large protein fractions in the quinoa products. The microstructure of the extruded quinoa breakfast flakes and heat-post-processed samples studied by scanning electron microscopy and X-ray tomography differed greatly; post-drying induced formation of aerated protein microstructures in the heat-treated samples. Nanostructures revealed by small-angle and wide-angle X-ray scattering indicated that extrusion imparted morphological changes in the quinoa protein and starch (dominance of V-type). Overall, extrusion processing only reduced the content of most of the essential amino acids to a minor extent; the content of valine and methionine was reduced to a slightly greater extent, but the final products met the requirements of the Food and Drug Organization., Conclusion: This study presents innovative examples on how extrusion processing and post-processing heat treatment can be used to produce attractive future food alternatives, such as breakfast cereal flakes and porridge powder, from quinoa grains. Extrusion of quinoa flour into Peruvian foods was shown to be mostly impacted by the processing temperature and processing conditions used. Protein crosslinking increased due to extrusion and post-processing heating. Starch crystallinity decreased most when the product was dried after processing. © 2021 The Authors. Journal of The Science of Food and Agriculture published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry., (© 2021 The Authors. Journal of The Science of Food and Agriculture published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.)

Published
2022
Full Text
View/download PDF

33. Climate Change Impact on Wheat Performance-Effects on Vigour, Plant Traits and Yield from Early and Late Drought Stress in Diverse Lines.

Author

Lan Y, Chawade A, Kuktaite R, and Johansson E

Subjects
Climate Change, Phenotype, Plant Breeding, Droughts, Triticum genetics
Abstract

Global climate change is threatening wheat productivity; improved yield under drought conditions is urgent. Here, diverse spring-wheat lines (modern, old and wheat-rye introgressions) were examined in an image-based early-vigour assay and a controlled-conditions (Biotron) trial that evaluated 13 traits until maturity. Early root vigour was significantly higher in the old Swedish lines (root length 8.50 cm) and introgressed lines with 1R (11.78 cm) and 1RS (9.91 cm) than in the modern (4.20 cm) and 2R (4.67 cm) lines. No significant correlation was noted between early root and shoot vigour. A higher yield was obtained under early drought stress in the 3R genotypes than in the other genotype groups, while no clear patterns were noted under late drought. Evaluating the top 10% of genotypes in terms of the stress-tolerance index for yield showed that root biomass, grains and spikes per plant were accountable for tolerance to early drought, while 1000-grain weight and flag-leaf area were accountable for tolerance to late drought. Early root vigour was determined as an important focus trait of wheat breeding for tolerance to climate-change-induced drought. The responsible genes for the trait should be searched for in these diverse lines. Additional drought-tolerance traits determined here need further elaboration to identify the responsible genes.

Published
2022
Full Text
View/download PDF

34. Innovative Green Way to Design Biobased Electrospun Fibers from Wheat Gluten and These Fibers' Potential as Absorbents of Biofluids.

Author

Muneer F, Hedenqvist MS, Hall S, and Kuktaite R

Abstract

In this study, a new method was developed to successfully design sustainable microfibers from wheat gluten proteins using a nonreducing solvent and electrospinning. We explored the morphology by X-ray tomography, scanning electron microscopy (SEM), and confocal laser scanning microscopy (CLSM), protein chemistry and cross-linking by size exclusion-high-performance liquid chromatography (SE-HPLC), and secondary structure by Fourier transform infrared spectroscopy (FT-IR) of fibers containing 15 and 20% of gluten. The impact of heat (130 °C) post-treatment on the polymerization properties of fibers and their absorption performance in different biofluids were also evaluated. The fibers with 20% gluten showed a uniform architecture supported by a relatively stronger fibrous network as compared to irregular and brittle fibers from 15% gluten. Heat treatment of fibers increased the protein cross-linking in all electrospun fibers as compared to the non-heat-treated fibers, as evidenced by SE-HPLC. An increase in the amount of α-helices and random coils was observed in the proteins of all of the heat-treated fibers compared to the nontreated fibers by FT-IR. This suggested that the heat treatment contributed positively to the gluten protein's chemical rearrangements, e.g., aggregation, new hydrogen and isopeptide bonding, and conversion of some of the sulfhydryl groups into disulfide cross-links, contributing positively to the functional performance. The heat-treated electrospun fibers with 20% gluten showed a very attractive blood absorption capacity (323%) and reasonable stability in phosphate-buffered saline (PBS) buffer compared to 15% gluten fibers and non-heat-treated fibers. Cotton-like fiber architecture, high blood absorption capacity, and reasonable stability in PBS buffer are properties desired for absorbents of biofluids and should be further explored in healthcare and medical applications., Competing Interests: The authors declare no competing financial interest., (© 2022 The Authors. Published by American Chemical Society.)

Published
2022
Full Text
View/download PDF

35. Fundamental study on changes in the FODMAP profile of cereals, pseudo-cereals, and pulses during the malting process.

Author

Ispiryan L, Kuktaite R, Zannini E, and Arendt EK

Subjects
Chromatography, High Pressure Liquid, Chromatography, Ion Exchange, Cicer growth & development, Cicer metabolism, Disaccharides analysis, Fagopyrum growth & development, Fagopyrum metabolism, Fructans analysis, Germination, Lens Plant growth & development, Lens Plant metabolism, Monosaccharides analysis, Oligosaccharides analysis, Triticum growth & development, Triticum metabolism, Disaccharides metabolism, Edible Grain metabolism, Food Handling methods, Fructans metabolism, Monosaccharides metabolism, Oligosaccharides metabolism
Abstract

Whole grains and pulses are rich in nutrients but often avoided by individuals with gastrointestinal disorders, due to high levels of fermentable oligo-, di-, monosaccharides and polyols (FODMAPs). This study investigated the impact of malting as delivery-system for endogenous enzymes. Malts from barley and wheat (naturally high in fructans), lentils and chickpeas (high in galactooligosaccharides), oat and buckwheat (low in FODMAPs) were produced. While barley and wheat malts had slightly elevated fructan-levels, in oat malt 0.8 g/100 g DM fructans were de novo synthesized. In lentils and chickpeas galactooligosaccharides diminished by 80-90%. Buckwheat did not contain any FODMAPs commonly investigated, but fagopyritols which may have a similar physiological effect. Also fagopyritols were degraded. While malted pulses and buckwheat are directly suitable for low FODMAP applications, using the combined approach of malting and fermentation, malted cereals could contribute to high nutritional values of such products., (Copyright © 2020. Published by Elsevier Ltd.)

Published
2021
Full Text
View/download PDF

36. Lupin Protein Isolate Structure Diversity in Frozen-Cast Foams: Effects of Transglutaminases and Edible Fats.

Author

Ceresino EB, Johansson E, Sato HH, Plivelic TS, Hall SA, Bez J, and Kuktaite R

Subjects
Dietary Fats, Freezing, Lupinus chemistry, Plant Proteins chemistry, Transglutaminases chemistry
Abstract

This study addresses an innovative approach to generate aerated foods with appealing texture through the utilization of lupin protein isolate (LPI) in combination with edible fats. We show the impact of transglutaminases (TGs; SB6 and commercial), glycerol (Gly), soy lecithin (Lec) and linoleic acid (LA) on the micro- and nanostructure of health promoting solid foods created from LPI and fats blends. 3-D tomographic images of LPI with TG revealed that SB6 contributed to an exceptional bubble spatial organization. The inclusion of Gly and Lec decreased protein polymerization and also induced the formation of a porous layered material. LA promoted protein polymerization and formation of homogeneous thick layers in the LPI matrix. Thus, the LPI is a promising protein resource which when in blend with additives is able to create diverse food structures. Much focus has been placed on the great foamability of LPI and here we show the resulting microstructure of LPI foams, and how these were improved with addition of TGs. New food applications for LPI can arise with the addition of food grade dispersant Lec and essential fatty-acid LA, by improved puffiness, and their contributing as replacer of chemical leavening additives in gluten-free products.

Published
2021
Full Text
View/download PDF

37. Impact of pH Modification on Protein Polymerization and Structure⁻Function Relationships in Potato Protein and Wheat Gluten Composites.

Author

Muneer F, Johansson E, Hedenqvist MS, Plivelic TS, and Kuktaite R

Subjects
Glutens chemistry, Hydrogen-Ion Concentration, Plant Proteins chemistry, Protein Aggregates physiology, Protein Structure, Secondary, Protein Unfolding, Spectroscopy, Fourier Transform Infrared, Temperature, Tensile Strength, Glutens metabolism, Plant Proteins metabolism, Solanum tuberosum metabolism, Triticum metabolism
Abstract

Wheat gluten (WG) and potato protein (PP) were modified to a basic pH by NaOH to impact macromolecular and structural properties. Films were processed by compression molding (at 130 and 150 °C) of WG, PP, their chemically modified versions (MWG, MPP) and of their blends in different ratios to study the impact of chemical modification on structure, processing and tensile properties. The modification changed the molecular and secondary structure of both protein powders, through unfolding and re-polymerization, resulting in less cross-linked proteins. The β-sheet formation due to NaOH modification increased for WG and decreased for PP. Processing resulted in cross-linking of the proteins, shown by a decrease in extractability; to a higher degree for WG than for PP, despite higher β-sheet content in PP. Compression molding of MPP resulted in an increase in protein cross-linking and improved maximum stress and extensibility as compared to PP at 130 °C. The highest degree of cross-linking with improved maximum stress and extensibility was found for WG/MPP blends compared to WG/PP and MWG/MPP at 130 °C. To conclude, chemical modification of PP changed the protein structures produced under harsh industrial conditions and made the protein more reactive and attractive for use in bio-based materials processing, no such positive gains were seen for WG.

Published
2018
Full Text
View/download PDF

38. Unraveling the Structural Puzzle of the Giant Glutenin Polymer-An Interplay between Protein Polymerization, Nanomorphology, and Functional Properties in Bioplastic Films.

Author

Rasheed F, Plivelic TS, Kuktaite R, Hedenqvist MS, and Johansson E

Abstract

A combination of genotype, cultivation environment, and protein separation procedure was used to modify the nanoscale morphology, polymerization, and chemical structure of glutenin proteins from wheat. A low-polymerized glutenin starting material was the key to protein-protein interactions mainly via SS cross-links during film formation, resulting in extended β-sheet structures and propensity toward the formation of nanoscale morphologies at molecular level. The properties of glutenin bioplastic films were enhanced by the selection of a genotype with a high number of cysteine residues in its chemical structure and cultivation environment with a short grain maturation period, both contributing positively to gluten strength. Thus, a combination of factors affected the structure of glutenins in bioplastic films by forming crystalline β-sheets and propensity toward the ordered nanostructures, thereby resulting in functional properties with high strength, stiffness, and extensibility., Competing Interests: The authors declare no competing financial interest.

Published
2018
Full Text
View/download PDF

39. The impact of newly produced protein and dietary fiber rich fractions of yellow pea (Pisum sativum L.) on the structure and mechanical properties of pasta-like sheets.

Author

Muneer F, Johansson E, Hedenqvist MS, Plivelic TS, Markedal KE, Petersen IL, Sørensen JC, and Kuktaite R

Subjects
Carbohydrate Conformation, Chromatography, Gel, Chromatography, High Pressure Liquid, Cooking, Elastic Modulus, Hot Temperature, Microscopy, Electron, Scanning, Nutritive Value, Particle Size, Plant Proteins, Dietary isolation & purification, Polymerization, Protein Conformation, Scattering, Small Angle, Spectroscopy, Fourier Transform Infrared, Structure-Activity Relationship, Surface Properties, X-Ray Diffraction, Dietary Carbohydrates analysis, Dietary Fiber analysis, Food Handling methods, Functional Food analysis, Pisum sativum chemistry, Plant Proteins, Dietary chemistry
Abstract

Two fractions from pea (Pisum sativum L.), protein isolate (PPI) and dietary fiber (PF), were newly produced by extraction-fractionation method and characterized in terms of particle size distribution and structural morphology using SEM. The newly produced PPI and PF fractions were processed into pasta-like sheets with varying protein to fiber ratios (100/0, 90/10, 80/20, 70/30 and 50/50, respectively) using high temperature compression molding. We studied protein polymerization, molecular structure and protein-fiber interactions, as well as mechanical performance and cooking characteristics of processed PPI-PF blends. Bi-modal particle size distribution and chemical composition of the PPI and PF fractions influenced significantly the physicochemical properties of the pasta-like sheets. Polymerization was most pronounced for the 100 PPI, 90/10 and 80/20 PPI-PF samples as studied by SE-HPLC, and polymerization decreased with addition of the PF fraction. The mechanical properties, as strength and extensibility, were likewise the highest for the 100 PPI and 90/10 PPI-PF blends, while the E-modulus was similar for all the studied blends (around 38 MPa). The extensibility decreased with the increasing amount of PF in the blend. The highest amounts of β-sheets were found in the pasta-like sheets with high amounts of PPI (100, 90 and 80%), by FT-IR. An increase in PF fraction in the blend, resulted into the high amounts of unordered structures as observed by FT-IR, as well as in an increase in the molecular scattering distances observed by SAXS. The water uptake increased and cooking loss decreased with increased proportions of the PF fraction, and the consistency of 10 min cooked pasta-like sheets were alike al dente texture. The new knowledge obtained in this study on the use of extraction-fractionation method to produce novel PPI and PF fractions for developing innovative high nutritious food can be of a great importance. The obtained knowledge on the pea protein and fiber processing behaviour could greatly contribute to a better control of functional properties of various temperature-processed products from yellow pea., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published
2018
Full Text
View/download PDF

40. Transglutaminase from newly isolated Streptomyces sp. CBMAI 1617: Production optimization, characterization and evaluation in wheat protein and dough systems.

Author

Ceresino EB, de Melo RR, Kuktaite R, Hedenqvist MS, Zucchi TD, Johansson E, and Sato HH

Subjects
Flour, Spectroscopy, Fourier Transform Infrared, Plant Proteins metabolism, Streptomyces, Transglutaminases metabolism, Triticum
Abstract

The popularity of transglutaminase (TG) by the food industry and the variation in functionality of this enzyme from different origins, prompted us to isolate and evaluate a high-yielding TG strain. Through the statistical approaches, Plackett-Burman and response surface methodology, a low cost fermentation media was obtained to produce 6.074±0.019UmL -1 of TG from a novel source; Streptomyces sp. CBMAI 1617 (SB6). Its potential exploitation was compared to commonly used TG, from Streptomyces mobaraensis. Biochemical and FT-IR studies indicated differences between SB6 and commercial TG (Biobond™ TG-M). Additions of TG to wheat protein and flour based doughs revealed that the dough stretching depended on the wheat protein fraction, TG amount and its origin. A higher degree of cross-linking of glutenins and of inclusion of gliadin in the polymers was seen for SB6 as compared to commercial TG. Thus, our results support the potential of SB6 to tailor wheat protein properties within various food applications., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published
2018
Full Text
View/download PDF

41. Carotenoid Content in Organically Produced Wheat: Relevance for Human Nutritional Health on Consumption.

Author

Hussain A, Larsson H, Kuktaite R, Olsson ME, and Johansson E

Subjects
Carotenoids genetics, Edible Grain genetics, Genetic Variation, Genotype, Humans, Organic Agriculture, Sweden, Carotenoids analysis, Edible Grain chemistry, Flour analysis, Food, Organic analysis, Nutritive Value, Triticum chemistry, Triticum genetics
Abstract

In this study, 33 spring and winter wheat genotypes were analyzed for carotenoid content and composition. Investigated genotypes were divided into four genotype groups i.e., spelt, landraces, old cultivars and primitive wheat. The results showed a high level of variation among the genotypes in amount of carotenoids in the grain with high values (around 4 mg/Kg) especially in one of the genotypes-Öland 8. Lutein was the most common carotenoid in all the investigated genotypes, contributing 70%-90% of the carotenoids in the grain. Variation in carotenoid content and composition was found not only among genotypes, but also between genotype groups and wheat type, although there is a need to analyze more genotypes to confirm the differences found between groups and types. This study showed that 40% of the daily requirements of lutein can be achieved from the genotypes with the highest lutein content (Öland 8) produced using organic farming through the average human consumption of 200 grams of wheat per day. Furthermore, this study showed, by the use of principal component analyses, an opportunity to select genotypes combining high values of certain nutritional compounds. By a further breeding and commercial production of such genotypes, the nutritional value of wheat flour for human consumption can be improved.

Published
2015
Full Text
View/download PDF

42. Macromolecular changes and nano-structural arrangements in gliadin and glutenin films upon chemical modification: Relation to functionality.

Author

Rasheed F, Newson WR, Plivelic TS, Kuktaite R, Hedenqvist MS, Gällstedt M, and Johansson E

Subjects
Ammonium Hydroxide chemistry, Disulfides chemistry, Gliadin isolation & purification, Glutens isolation & purification, Polymerization, Protein Aggregates, Protein Structure, Secondary, Salicylic Acid chemistry, Sodium Hydroxide chemistry, Tensile Strength, Gliadin chemistry, Glutens chemistry, Membranes, Artificial, Nanostructures chemistry, Triticum chemistry
Abstract

Protein macromolecules adopted for biological and bio-based material functions are known to develop a structured protein network upon chemical modification. In this study, we aimed to evaluate the impact of chemical additives such as, NaOH, NH4OH and salicylic acid (SA), on the secondary and nano-structural transitions of wheat proteins. Further, the effect of chemically induced modifications in protein macromolecular structure was anticipated in relation to functional properties. The gliadin-NH4OH-SA film showed a supramolecular protein organization into hexagonal structures with 65 Å lattice parameter, and other not previously observed structural entities having a characteristic distance of 50 Å. Proteins in gliadin-NH4OH-SA films were highly polymerized, with increased amount of disulfide crosslinks and β-sheets, causing improved strength and stiffness. Glutenin and WG proteins with NH4OH-SA showed extensive aggregation and an increase in β-sheet content together with irreversible crosslinks. Irreversible crosslinks hindered a high order structure formation in glutenins, and this resulted in films with only moderately improved stiffness. Thus, formation of nano-hierarchical structures based on β-sheets and disulfide crosslinks are the major reasons of high strength and stiffness in wheat protein based films., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published
2015
Full Text
View/download PDF

43. Nanostructural morphology of plasticized wheat gluten and modified potato starch composites: relationship to mechanical and barrier properties.

Author

Muneer F, Andersson M, Koch K, Menzel C, Hedenqvist MS, Gällstedt M, Plivelic TS, and Kuktaite R

Subjects
Carbohydrate Conformation, Crystallization, Glutens ultrastructure, Glycerol chemistry, Nanocomposites ultrastructure, Oxygen chemistry, Permeability, Polymerization, Protein Structure, Secondary, Scattering, Small Angle, Solanum tuberosum chemistry, Starch ultrastructure, Tensile Strength, Triticum chemistry, Water chemistry, X-Ray Diffraction, Glutens chemistry, Nanocomposites chemistry, Starch chemistry
Abstract

In the present study, we were able to produce composites of wheat gluten (WG) protein and a novel genetically modified potato starch (MPS) with attractive mechanical and gas barrier properties using extrusion. Characterization of the MPS revealed an altered chain length distribution of the amylopectin fraction and slightly increased amylose content compared to wild type potato starch. WG and MPS of different ratios plasticized with either glycerol or glycerol and water were extruded at 110 and 130 °C. The nanomorphology of the composites showed the MPS having semicrystalline structure of a characteristic lamellar arrangement with an approximately 100 Å period observed by small-angle X-ray scattering and a B-type crystal structure observed by wide-angle X-ray scattering analysis. WG has a structure resembling the hexagonal macromolecular arrangement as reported previously in WG films. A larger amount of β-sheets was observed in the samples 70/30 and 30/70 WG-MPS processed at 130 °C with 45% glycerol. Highly polymerized WG protein was found in the samples processed at 130 °C versus 110 °C. Also, greater amounts of WG protein in the blend resulted in greater extensibility (110 °C) and a decrease in both E-modulus and maximum stress at 110 and 130 °C, respectively. Under ambient conditions the WG-MPS composite (70/30) with 45% glycerol showed excellent gas barrier properties to be further explored in multilayer film packaging applications.

Published
2015
Full Text
View/download PDF

44. Effect of additives on the tensile performance and protein solubility of industrial oilseed residual based plastics.

Author

Newson WR, Kuktaite R, Hedenqvist MS, Gällstedt M, and Johansson E

Subjects
Citric Acid pharmacology, Hot Temperature, Hydrogen-Ion Concentration, Sodium Hydroxide pharmacology, Solubility, Tensile Strength, Brassica chemistry, Crambe Plant chemistry, Plant Oils chemistry, Plant Proteins chemistry, Plastics chemistry
Abstract

Ten chemical additives were selected from the literature for their proposed modifying activity in protein-protein interactions. These consisted of acids, bases, reducing agents, and denaturants and were added to residual deoiled meals of Crambe abyssinica (crambe) and Brassica carinata (carinata) to modify the properties of plastics produced through hot compression molding at 130 °C. The films produced were examined for tensile properties, protein solubility, molecular weight distribution, and water absorption. Of the additives tested, NaOH had the greatest positive effect on tensile properties, with increases of 105% in maximum stress and 200% in strain at maximum stress for crambe and a 70% increase in strain at maximum stress for carinata. Stiffness was not increased by any of the applied additives. Changes in tensile strength and elongation for crambe and elongation for carinata were related to changes in protein solubility. Increased pH was the most successful in improving the protein aggregation and mechanical properties within the complex chemistry of residual oilseed meals.

Published
2014
Full Text
View/download PDF

45. Contribution of organically grown crops to human health.

Author

Johansson E, Hussain A, Kuktaite R, Andersson SC, and Olsson ME

Subjects
Animals, Food Contamination analysis, Humans, Metals, Heavy analysis, Organic Agriculture, Pesticide Residues analysis, Public Health, Food, Organic analysis
Abstract

An increasing interest in organic agriculture for food production is seen throughout the world and one key reason for this interest is the assumption that organic food consumption is beneficial to public health. The present paper focuses on the background of organic agriculture, important public health related compounds from crop food and variations in the amount of health related compounds in crops. In addition, influence of organic farming on health related compounds, on pesticide residues and heavy metals in crops, and relations between organic food and health biomarkers as well as in vitro studies are also the focus of the present paper. Nutritionally beneficial compounds of highest relevance for public health were micronutrients, especially Fe and Zn, and bioactive compounds such as carotenoids (including pro-vitamin A compounds), tocopherols (including vitamin E) and phenolic compounds. Extremely large variations in the contents of these compounds were seen, depending on genotype, climate, environment, farming conditions, harvest time, and part of the crop. Highest amounts seen were related to the choice of genotype and were also increased by genetic modification of the crop. Organic cultivation did not influence the content of most of the nutritional beneficial compounds, except the phenolic compounds that were increased with the amounts of pathogens. However, higher amounts of pesticide residues and in many cases also of heavy metals were seen in the conventionally produced crops compared to the organic ones. Animal studies as well as in vitro studies showed a clear indication of a beneficial effect of organic food/extracts as compared to conventional ones. Thus, consumption of organic food seems to be positive from a public health point of view, although the reasons are unclear, and synergistic effects between various constituents within the food are likely.

Published
2014
Full Text
View/download PDF

46. Molecular structure of citric acid cross-linked starch films.

Author

Menzel C, Olsson E, Plivelic TS, Andersson R, Johansson C, Kuktaite R, Järnström L, and Koch K

Subjects
Copper Sulfate chemistry, Cross-Linking Reagents chemistry, Molecular Structure, Molecular Weight, Solubility, Temperature, Water chemistry, Amylopectin chemistry, Amylose chemistry, Citric Acid chemistry
Abstract

The effect of citric acid (CA) on starch films has been examined. A new method to detect cross-linking of starch by CA in solution-cast films by molecular weight measurements is described. Furthermore, we managed to distinguished between free, mono- and di-esterified CA and quantify di-ester content within starch films by using a modification in the method of complexometric titration with copper(II)-sulfate. Cross-linking of starch by CA occurred at low temperature, 70°C, which we assumed is so far the lowest temperature reported where cross-linking reaction occurred. This is essential for starch coating applications within paper industry since no high temperatures for curing will be required. However, curing at 150°C and high CA concentrations, 30 pph, increased cross-linking reaction. Furthermore, the physical properties like water solubility, gel content and glass transition temperature, were highly reflected by changes in the molecular structure i.e. cross-linking and hydrolysis, as well as CA content and curing temperature., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published
2013
Full Text
View/download PDF

47. Healthy food from organic wheat: choice of genotypes for production and breeding.

Author

Hussain A, Larsson H, Kuktaite R, and Johansson E

Subjects
Crops, Agricultural chemistry, Crops, Agricultural growth & development, Crops, Agricultural metabolism, Flour analysis, Food, Organic analysis, Humans, Metals, Heavy analysis, Metals, Heavy metabolism, Minerals analysis, Minerals metabolism, Nutritive Value, Phylogeny, Principal Component Analysis, Seeds chemistry, Seeds genetics, Seeds metabolism, Species Specificity, Sweden, Tocopherols analysis, Tocopherols metabolism, Tocotrienols analysis, Tocotrienols metabolism, Triticum chemistry, Triticum genetics, Triticum metabolism, Breeding, Food Quality, Functional Food analysis, Genotype, Organic Agriculture methods, Seeds growth & development, Triticum growth & development
Abstract

Background: In the present study, 40 wheat genotypes were grown in the same soil in organic farming system trials in Alnarp, Sweden. The purpose was to evaluate opportunities for production and breeding of organic wheat of high nutritious value., Results: The results showed a large variation in content of minerals, total tocochromanols and heavy metals in the grain of 40 organically produced wheat genotypes. Principal component and cluster analysis were used as tools for selection of the most suitable genotypes for production and breeding of organic wheat of high nutritious value. No single genotype group was found particularly superior from the studied material to produce this specific type of wheat. However, certain genotypes from different groups were found with promising nutritional characters. The most promising genotypes as related to nutritionally relevant compounds were 6356 spelt, Triticum monococcum, Ölands 17 borst spelt, Lv Dal 16 brun borst and Fylgia., Conclusion: By choosing these genotypes for organic production and future wheat breeding, nutritionally improved organic wheat products might be developed. However, for future breeding, nutritional components such as protein, fibre, glycaemic index and B-group vitamins should also be considered., (Copyright © 2012 Society of Chemical Industry.)

Published
2012
Full Text
View/download PDF

48. Concentration of some heavy metals in organically grown primitive, old and modern wheat genotypes: implications for human health.

Author

Hussain A, Larsson H, Kuktaite R, and Johansson E

Subjects
Genotype, Humans, Metals, Heavy metabolism, Organic Agriculture, Soil Pollutants metabolism, Triticum genetics, Metals, Heavy analysis, Metals, Heavy toxicity, Soil Pollutants analysis, Soil Pollutants toxicity, Triticum chemistry, Triticum metabolism
Abstract

The concentration of six HMs (Cd, Cr, Co, Pb, Hg and Ni) was analysed in 321 organically grown winter and spring wheat genotypes from six genotype groups, i.e. selections, old landraces, primitive wheat, spelt, old cultivars and cultivars. Also the potential risk of individual toxic HM to human health was estimated by using the Hazard Quotient (HQ). Significantly the lowest grain concentration of Cd was found in primitive wheat as compared to all other investigated genotype groups. Intake of HM by consumption of whole wheat grain was not found to pose a health risk to human for any of the investigated genotype groups. The bio-concentration factor of Cd for the different genotype groups indicated a lower ability to accumulate Cd for primitive wheat as compared to other genotype groups. The primitive wheat was found the most promising and might be of interest in future wheat breeding programs to develop wheat genotypes with low HMs concentration in the grain.

Published
2012
Full Text
View/download PDF

49. Individual and interactive effects of cultivar maturation time, nitrogen regime and temperature level on accumulation of wheat grain proteins.

Author

Malik AH, Prieto-Linde ML, Kuktaite R, Andersson A, and Johansson E

Subjects
Glutens biosynthesis, Glutens chemistry, Molecular Weight, Polymerization, Quality Control, Seed Storage Proteins chemistry, Sodium Dodecyl Sulfate chemistry, Solubility, Species Specificity, Surface-Active Agents, Sweden, Temperature, Time Factors, Water analysis, Weather, Dietary Proteins metabolism, Fertilizers, Flour analysis, Nitrogen Cycle, Seed Storage Proteins biosynthesis, Seeds growth & development, Seeds metabolism, Triticum growth & development, Triticum metabolism
Abstract

Background: Background and reasons for differences in wheat grain protein accumulation and polymerization are not fully understood. This study investigated individual and interactive effects of genetic and environmental factors on wheat grain protein accumulation and amount and size distribution of polymeric proteins (ASPP)., Results: Individual factors, e.g. maturation time of a cultivar, nitrogen regime and temperature level, influenced grain protein accumulation and ASPP, although interaction of these factors had a greater influence. Early maturation time and long grain maturation period (GMP) in a cultivar resulted in high amounts of sodium dodecyl sulphate (SDS)-extractable proteins (TOTE) and low percentage of SDS-unextractable polymeric proteins in total polymeric proteins (%UPP). Cultivars with late maturation time and short GMP resulted in low TOTE and high %UPP. Late versus early nitrogen application regime resulted in low %UPP versus low TOTE and high %UPP, respectively. High versus low temperature resulted in high %UPP and low %UPP, respectively. Differences in ASPP at maturity started as changes in protein accumulation from 12 days after anthesis., Conclusion: Length of GMP, especially in relation to length until maturity, governs gluten strength (%UPP) and grain protein concentration (TOTE). Length of GMP is determined by cultivar, temperature during GMP and late nitrogen availability., (Copyright © 2011 Society of Chemical Industry.)

Published
2011
Full Text
View/download PDF

50. Mechanical properties and network structure of wheat gluten foams.

Author

Blomfeldt TO, Kuktaite R, Johansson E, and Hedenqvist MS

Subjects
Chromatography, Gel, Chromatography, High Pressure Liquid, Materials Testing, Microscopy, Electron, Scanning, Glutens chemistry, Triticum chemistry
Abstract

This Article reports the influence of the protein network structure on the mechanical properties of foams produced from commercial wheat gluten using freeze-drying. Foams were produced from alkaline aqueous solutions at various gluten concentrations with or without glycerol, modified with bacterial cellulose nanosized fibers, or both. The results showed that 20 wt % glycerol was sufficient for plasticization, yielding foams with low modulus and high strain recovery. It was found that when fibers were mixed into the foams, a small but insignificant increase in elastic modulus was achieved, and the foam structure became more homogeneous. SEM indicated that the compatibility between the fibers and the matrix was good, with fibers acting as bridges in the cell walls. IR spectroscopy and SE-HPLC revealed a relatively low degree of aggregation, which was highest in the presence of glycerol. Confocal laser scanning microscopy revealed distinct differences in HMW-glutenin subunits and gliadin distributions for all of the different samples.

Published
2011
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results