Cereal Science

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Research from the Cereal Science program. The program website may be found at https://www.ag.ndsu.edu/cerealscience

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Application of Response Surface Methodology in the Development of Gluten-Free Bread with Yellow Pea Flour Addition
(North Dakota State University, 2012) Jeradechachai, Thunyaporn
Yellow pea (Pisum sativum L.) flour fortified gluten-free (GF) bread formulation was optimized by response surface methodology (RSM) and the final product was evaluated for shelf life and sensory acceptability. A second-order model was fitted to the precooking temperature of pea flour (PTPF), water level, and proof time as the factors. Higher PTPF and lower proof time significantly (P<0.05) reduced the brightness of bread crumb. Crumb firmness was influenced by the PTPF, water level and proof time. The optimized parameters for PTPF, water level, and proof time were 156.9 °C, 523.8 g, and 18.0 min, respectively. The optimized bread had a brightness (L* value), specific volume, crumb firmness, and cell diameter of 68.2, 2.6 ml/g, 174.2 gf, and 3.81 mm, respectively. The optimized GF bread had longer shelf-life, but had significantly (P<0.05) lower acceptance scores, than the commercial premix bread product.
Assessing Microbial Stability and Quality of Green Beans Using Various Home Canning Methods
(North Dakota State University, 2013) Kuchynski, Jenny
Today many consumers follow processing methods recommended either from family members or the internet, which they interpret as being safe. Processing temperature profiles, survival of B. stearothermophilus spores, texture, and color of green beans processed under four home canning methods were assessed. The products were processed using pressure, boiling water bath, steam, or oven canning methods. Pressure canning produced the greatest microbial reductions but this method resulted in the lowest bean quality. The boiling water bath, steam, and oven canning were found to be less safe because the product temperature never achieved 100°C and the resulting microbial counts, >1.7 log CFU/ml, were observed after processing. However, green bean quality was better than pressure canning, with beans from steam canning having the firmest texture and best green color. Although better green bean quality results were observed from internet or family based methods, their safety is questionable considering the high microbial survival.
Black Bean Milling
(North Dakota State University, 2014) Carter, Claudia Elizabeth
Black bean milling to produce whole-bean flour and cotyledon flour by using a centrifugal mill and a burr mill/roller milling system, respectively, were investigated. The effect of black bean seed pretreatment (cooked-dried, soaked-dried, and tempered) on flour physical, chemical, and pasting characteristics were investigated. Whole flour milling was done with a centrifugal mill using mesh size of 500 μm, rotor speed of 12,000 rpm, and mill feed of 267+18 g/min. Cooked-dried, soaked-dried, and tempered black bean milling yields for whole flour reached 58, 59, and 66%, respectively. Roller mill was used with durum wheat settings. Cooked-dried, soaked-dried, and tempered black bean milling yields for cotyledon flour reached 75, 73, and 75%, respectively. Black bean seed changed physically and internally by cooking or soaking. Differences in moisture content were reflected to change milling-ability and physical quality of flour. Cooked-dried affected the most starch damage and pasting properties and for flour color.
Characteristics of Yam Composite Flour: Properties and Function of Bread and Tortilla Making
(North Dakota State University, 2017) Asiyanbi-Hammed, Tawakalit Tope
Consumer interest in dietary fiber is on the rise as more information about its potential impact on health has become available. Flour from yam (Dioscorea rotundata) could have useful applications in the baking industry, in composite flour blends, because of its high level of dietary fiber and other essential nutrients. Study of the chemical composition, physicochemical characteristics, and pasting properties of unfermented-white yam flour (UYF) and fermented-brown yam flour (FYF) were investigated. Studies show that composite flour from yam has high ash, total starch, and fiber content than refined wheat flour. Thermal studies showed the energy required for composite flour gelatinization is greater than that of refined wheat flour. The firmness of FYF gel significantly increased with increasing number of days unlike UYF where slight hardness in texture was observed. This study revealed that each flour type exhibited different characteristics when compared to refined wheat flour. This necessitates further studies to substitute the yam flour samples with refined wheat flour to create composite flours that could be employed in bakery products. Inclusion of UYF and FYF flour at 5, 10, 15 and 20% levels of substitution with wheat flour affect the dough physicochemical, rheological pasting properties, and the nutritional quality. Proximate analysis of the flours carried out shows composite flours were of lower protein value but had higher fiber content than refined wheat flour. Impact on the gluten quality, gassing power, farinograph parameters was observed. The farinograph water absorption increased significantly (p<0.05) for blends prepared with UYF. Investigation revealed that the end-product quality (oven spring, loaf volume, bread crumb, tortilla weight, flexibility, thickness and color) of bread loaves and tortilla was significantly affected. This study demonstrated that incorporation of up to 10% FYF flour appears to give acceptable dough with good viscoelastic properties and bread with quality traits similar to refined wheat bread. This might be because bread itself is a fermented bakery product. For the tortilla; an unfermented product, 20% UYF inclusion seems to be more suitable to produce tortillas with good extensibility, acceptable thickness and whiteness with no dark spots that will appeal to the consumers.
Characterization of Edible Bean Flours: Properties and Functionality
(North Dakota State University, 2013) Simons, Courtney W.
Consumption of pulses is considered part of a healthy diet. Therefore, the opportunity exists for development of new pulse-based ingredients. However, a better understanding of their properties is necessary. The compositional and functional properties will vary depending on the bean type, their physical form (pre-cooked, raw flour, starch or protein fractionates) and growing location. In this study, edible bean flours (pinto, navy, black and small red) were subjected to extrusion cooking to produce snacks and texturized high-protein flour. The extrudates were studied to determine the effect of extrusion on the physical, physicochemical, chemical, sensory, and digestibility properties. Texturized high-protein flour was used in a bread formulation study. Finally, a preliminary study of location effect on production of grassy compounds, e.g. hexanal and hexanol, in pinto beans was conducted to determine importance of growing environment on flavor development during storage. The results of these studies showed that bean flours generally had excellent extrusion properties (good expansion and texture). However, pre-cooked flours had much lower expansion and textural integrity compared to raw bean flours and starch fractionates. Nutritional content (protein, total starch, fiber and ash) of flours were generally retained after extrusion. Lipids and resistant starch (RS) however were significantly reduced. Significant reduction in RS resulted in snacks having high glycemic index. Extrudates had 20% lower raffinose content suggesting reduced potential for flatulence after extrusion processing. Sensory evaluation of pinto, navy and black bean snacks indicated good overall acceptability. Pinto bean high-starch fraction differed in composition and functionality (viscosity and thermal properties) compared to its raw whole flour and extruded form. Adding 5% texturized pinto bean protein to bread increased its lysine content by 50%; without significantly affecting bread quality. A significant statistical interaction between growing location and storage time on hexanol and hexanal concentrations was observed for pinto beans grown in Forest River, Johnstown and Hatton North Dakota. This Dissertation will help processors understand the potential for beans as a food ingredient. Applications may include use in breads and other baked products, extruded puffed snacks, pasta, and soups. Bean flours can improve nutritional quality and provide unique functionality to food systems.
Composition and Stability of Phytochemicals during Food Processing
(North Dakota State University, 2015) Gebreselassie, Etsehiwot Yohannes
Dietary phytochemicals are thought to reduce the incidence of chronic degenerative diseases. The concentration of these phytochemicals has been extensively studied, but less is known about their stability during food processing. The objective of this study was to determine the stability of lignans and other phytochemicals during the vinification and brewing processes. The amount of secoisolariciresinol diglucoside (SDG), gallic acid, caffeic acid, coumaric acid, chlorogenic acid, and ferulic acid increased up to 45 % during the vinification process; however, the amount of folic acid remained unchanged. SDG content was determined in barley for the first time. The SDG content also varied among barley varieties and showed a year-to-year variation. In addition, no SDG was detected during the mashing, lautering, boiling, and fermentation steps of the brewing process. Overall, processing techniques used in this study caused various effects on the stability of phytochemicals.
Effect of Flaxseed Fiber on Bread Quality Obtained from Frozen Dough
(North Dakota State University, 2012) Schlepp, Emily Beth
Fiber in frozen bread dough is thought to reduce the loss of yeast vitality and improve nutrition and quality of bread. The objective of this study was to determine the applicability of flaxseed fiber in frozen bread dough. Fiber was extracted from two sources of brown flaxseed and added to bread formulas at 0%, 1% and 3%. Dough was blast chilled and kept frozen until thawed at scheduled intervals. Thawed dough was proofed, baked into bread. Bread was tested analytically and by a sensory panel. Loss of overall quality was observed overtime. Breads containing flaxseed fiber had significantly larger loaf volumes (cc) and reduced firmness (g). A trained sensory panel detected significantly lower crumb firmness and stale flavors in breads containing flaxseed fiber. These results suggest flaxseed fiber has the potential to improve the perceived quality of frozen bread dough.
Effect of Operational Parameters on Laboratory Determination of Malt Fermentability
(North Dakota State University, 2013) Sehrawat, Jaidev
Prediction and variability in malt fermentability is a concern for breeders and brewers. The primary purpose of this study was to determine the variation in fermentability using two different laboratory mash methods. Another experiment was conducted to develop a relationship between malt/wort parameters and malt fermentability with addition of adjunct. The prediction of malt fermentability was achieved by using stepwise multiple linear regression analysis to evaluate which quality factors were able to best explain the observed variation in fermentability. The hot water extract (HWE) mash protocol showed a wider range of fermentability values than did the Congress mash. However, hot water extract mash method clearly showed better discriminative power. Diastatic Power (DP) explained about 50% of the variation in fermentability when using the Congress mash with all malt (i.e. 100%) and also with adjunct. While in case of HWE extract protocol, limit dextrinase activity was able to explain 32% of variation in fermentability with all malt and also with adjunct.
Effect of polyaccharides and proteins on refrigerated dough quality
(North Dakota State University, 2009) Zhang, Yu
Refrigerated dough is considered one of the most popular dough products in the food industry. Consumers appreciate the convenience, storage stability, and good organoleptic properties of refrigerated dough products. However, in practice, the quality of refrigerated dough can deteriorate during the storage as a result of liquid formation in dough, which is called "dough syruping". The objectives of this study were (1) characterization of the structural properties of dough components that affect dough syruping; (2) identification of rheological changes that occur during refrigeration, and as they relate to arabinoxylans (AX), starch and protein solubility. The data showed that AX solubilization and degradation occurred simultaneously with dough syruping. Nuclear magnetic resonance (NMR) spectroscopy analysis and the viscosity analysis of AX aqueous solution confirmed that AX solubilization and degradation resulted in the increase of low molecular weight fraction and the decrease of high molecular weight fraction in water extractable AX (WEAX). The pasting properties and thermal properties of starch changed during the storage: peak viscosity decreased up to 23.1 % compared to flour samples during 34 days refrigerated storage. Variation in starch granular morphology was detected. These results showed that physicochemical properties of starch changed during refrigerated storage. The rheological properties of dough changed dramatically during refrigerated storage, which may have significant impacts on endproduct quality. Both, the elastic modulus (G') and viscous modulus (G") decreased. Dough exhibited the major decrease on the moduli on day 3 and day 16. By comparing the viscoelastic properties of dough samples on day O and day 16, 50% decrease on the elastic modulus and a roughly 30% decrease in the loss modulus were observed. Changes in the protein fractions of dough samples were related to their rheological properties. Therefore, the physicochemical properties of polysaccharides and proteins appear to be directly correlated to dough syruping, which may result in the diminishment of rheological and organoleptic properties of refrigerated doughs.
Effects of Pasteurization (Heating) on Milled Flaxseed Quality
(North Dakota State University, 2013) Turner, Cody Troy
Current food industry practices include the use of pasteurization (heat treatment) as a means to reduce the microbial counts of flaxseed (Linum usitatissimum). Flaxseed was pasteurized using a dry air heat treatment of 148 °C for 16.25 minutes and the oxidative stability was observed over a 20 week storage period. Flaxseed quality was measured using peroxide value, percent free fatty acid (as oleic), and propanal content. Peroxide values of the pasteurized milled flaxseed were found to significantly increase (P ≤ 0.05) by week 2. Propanal formation coincided with peroxide value development over 20 weeks of storage. Pasteurized flaxseed milled under refrigerated temperatures (10 – 18 °C) did not exhibit any significant (P > 0.05) improvement in oxidative stability. Flaxseed pasteurization at 148 °C for 16.25 minutes using dry heat was found to be detrimental to the oxidative stability flaxseed once milled.
Evaluation of Extraction Methods and Groat Type With Effects on Quality Analysis of Oat Beverage
(North Dakota State University, 2021) Olson, Brandon Robert
The recent uptick in consumption of plant-based beverages has forced companies to modify production methods to further optimize the process. The objective of this study was to evaluate how groat type, water to grain ratio, and extraction method affect the quality and composition of oat beverage. Wet milling and the use of an amylase treatment produced significantly (p<0.05) higher values of degree Brix, solids, and total starch within the beverage base. Stabilized groats produced the highest value of total starch of 61.97%. Microbial analysis revealed that amylase treated products had a much lower colony forming units per gram (CFU/g), when compared to dry and wet milling. To produce an oat beverage with ideal rheological and composition values, the beverage must be derived from heat treated groats, a grain to water ratio of 1:4, and must undergo an α-amylase treatment.
Evaluation of Pea Protein and Modified Pea Protein as Egg Replacers
(North Dakota State University, 2012) Hoang, Hieu Duy
Native yellow pea (Pisum sativum) protein isolates (PPIs) showed good foaming and emulsifying properties but a poor gelling characteristic. However, this can be corrected by Transglutaminase (TGase) treatment. PPIs were obtained using alkaline extraction method in which extracting pH, precipitating pH, flour–to–water ratio, and extraction time were optimized to obtain maximum yields and least change in protein functionalities. Extraction pH of 10.0, precipitating pH of 4.3, flour–to–water ratio of 1:6, and 30 minute extraction time were found to be optimum values for pea protein extraction. SDS–PAGE gels showed that the PPI had a very similar protein molecular weight profile as its original flour. TGase treatment was applied on PPIs at different pH levels from 4.3 to 7.0. The SDS–PAGE and RVA tests showed that treatment at pH 6.0 provided the best overall functionality. Large molecular weight (MW) proteins (~ 90,000 Da) and medium MW proteins (~50,000 – 80,000 Da) were the main substrates for TGase catalyzed reaction whereas most low MW the proteins (< 45,000 Da) were not involved. RVA results indicated that treatments at pH 6.0 and 7.0 had the highest viscosities but the treatment at pH 6.0 had better stability and consistency. Functionality tests indicated that modified PPIs possessed a better viscosity profile than the native PPIs but no improvement in gelling capacity and only minor impact on foaming and emulsifying properties. PPIs performance greatly depended on their final pHs. The foaming capacity, foaming stability, and emulsion capacity were significantly improved when the final pH of PPIs was adjusted from 4.3 to 7.0. The overall sensory evaluation results suggested that TGase–treated PPIs and PPIs were not yet able to replace egg in the cake system. Only PPI can replace egg in the cookie system. TGase–treated samples had a lower acceptability due to an “off–taste” and a “strange” flavor. Future work, therefore, should study TGase combined with other treatments to further improve PPIs functionalities. Purification should be integrated into extraction process and other food systems should also be included to extent the scope and role of modified PPIs in food industry.
Fabrication and Characterization of Antifungal Essential Oil-In-Water Nanoemulsion Delivery System Targeting Fusarium Graminearum In Vitro and During the Malting Process
(North Dakota State University, 2019) Wan, Jing
Fusarium mycotoxins represent the most food safety concern for the malting industry. The complete prevention of Fusarium mycotoxins in the grains by limiting toxigenic fungi in the field and during storage is not practical. The common way to control Fusarium mycotoxins in malting industry is to avoid infected grains. However, avoidance is not always possible. To ensure the quality and safety of food products, development of food-grade antifungal strategies that can be applied in food processing, would benefit growers and the food industry. Recently, plant-based essential oils (EOs) have received considerable attentions in the food industry due to broad-spectrum of antifungal activities and inhibitory effect against mycotoxin biosynthesis. However, direct application of EOs during the malting process is impractical. In this project, parameters that impact on the formation of EO-in-water nanoemulsions and functional properties including antifungal and mycotoxin inhibitory efficacy were evaluated in vitro. The proper-designed EO-in-water nanoemulsions were then applied in micro-malting process. Results indicated that physically stable EO-in-water nanoemulsions can be fabricated by incorporating either ≥75 wt% of corn oil or ≥50 wt% of medium chain triacylglycerol (MCT) into EO before homogenization and homogenized under optimized processing conditions (68.95 MPa and 2 passes). In general, the mycotoxin inhibitory efficacy of EO was enhanced considerably in nanoemulsion form than bulk oil. Among all selected five EOs, thyme and clove oil-in-water nanoemulsions had the greatest antifungal and mycotoxin inhibitory activities. In terms of emulsifiers, the antifungal activity was mainly dominated by EO rather than emulsifier to alter mycelial and spore cell membrane integrity. At last, clove oil-in-water nanoemulsions stabilized by three different emulsifiers (Tween 80, bovine serum albumin, quillaja saponins) were selected to apply in micro-malting process according to our germinative energy test of barley seeds. All clove oil-in-water nanoemulsions had the capability to inhibit fungal growth and DON production during the micro-malting process. Among the three emulsifiers, Tween 80-stablized clove oil nanoemulsion displayed largest reduction of mycotoxin and least flavor impact on the final malt. The overall project showed a great potential for utilization of EO-in-water nanoemulsion as antifungal agent and mycotoxin inhibitor in the food industry.
Factors Influencing the Formation of Zein and Gum Arabic Complex Coacervates
(North Dakota State University, 2014) Wadhawan, Kirty
Complex Coacervates are mixtures of biopolymers such as proteins and polysaccharides. The objectives of this research were to (1) determine the optimum biopolymer ratio and pH for the formation of Zein protein and gum arabic complex coacervates, (2) determine the stability of Zein: GA coacervates as an emulsifier using flax oil, Transglutaminase (Tgase), Tween 80, and Span 80 (surfactants), and (3) determine optimum temperature for the stability of formed Zein: GA complex coacervates. The optimum ratio, pH and temperature were determined using turbidimetric and Zeta (ζ) potential analysis. Analysis confirmed the formation of stable Zein: GA coacervates at ratio 2:1, at pH 4.5 ± 0.05 and most stable at temperature 25 ± 2 °C. Zeta (ζ) potential analysis also confirmed the formation of stable emulsion using Zein: GA coacervates at 5% Tgase and 25% Span 80. Therefore, Zein: GA complex coacervates could be used as an emulsifier in food industry.
Genetic and Phenotypic Assessment of Iron and Folate Concentration in Lentil (Lens Culinaris Medik.)
(North Dakota State University, 2015) Gupta, Debjyoti Sen
Micronutrients and vitamins are chemical elements required in trace quantities for normal human growth and development. Micronutrients and vitamin deficiency is prevalent throughout the world. The first objective of this research was to determine folate concentration in 10 lentil genotypes and evaluate the effect of environment on folate concentration. Folate concentration ranged from 216 to 290 μg/100 g with a mean of 255 μg/100 g and the concentration differed across years and locations. A significant genotype × environment interaction effect was observed for lentil folate concentration. The second objective was to measure the iron, zinc, copper, calcium and magnesium concentration in 26 cultivated and wild lentils. Significant variation in Fe, Zn, Cu, Ca, and Mg concentration among Lens species and no single genotype had high concentrations of all micronutrients.The third objective was to determine genetic diversity among 29 cultivated and wild lentils using 39 simple sequence repeat markers. Thirteen of 39 SSR markers were polymorphic among the 29 lentil genotypes. Cluster analysis grouped the genotypes into 4 clusters broadly based on the genotyping data and this grouping had correspondence with the pedigree relationships of the genotypes. The fourth objective was to develop expressed sequence tags-simple sequence repeats (EST-SSRs) markers in lentil. Lentil EST sequences (9513) from the NCBI database were assembled into 4053 unigenes. Unigenes were screened for simple sequence repeats and 348 primer pairs were designed. Fifty-seven primer pairs were polymorphic among the 22 lentil genotypes providing additional gene-specific primers for use in lentil breeding. The fifth objective was to develop gene specific molecular markers for iron metabolism related genes in lentil and to study their gene expression in the presence of excess iron. Gene specific markers were developed for Ferritin-1, BHLH-1, and IRT-1 to allow detailed study of the iron metabolic pathway in lentil. Differential gene expression of Ferritin-1 and IRT-1 under excess iron was observed at 2 hours but not at 8 hours and 24 hours. Results of these studies contribute to a broad understanding of the genetic variation, environmental influence on and expression of genes related to micronutrient and vitamin concentration and metabolism in lentil.
Growth of Fusarium Graminearum on Wheat Bran/Agar Cultures in Relation to Fusarium Head Blight Susceptibility
(North Dakota State University, 2012) Abeyratne, Meliza Stephnie
Research investigates the chemical basis for Fusarium head blight (FHB) resistance and initiating development of a screening test for resistant wheat genotypes. The focus is on minimizing cost of screening and gaining chemical approach against FHB. Wheat bran/agar plates (8% bran, w/v) prepared from hard red spring wheat with different susceptibility to FHB were inoculated with F. graminearum. Fusarium plaque diameters and ergosterol levels after 4 days of growth were significantly lower (p< 0.05) on plates prepared from genotypes with low FHB susceptibility than from high FHB susceptible genotypes. F. graminearum growth was lower, when methanol-soluble compounds (MSC) extracted from a low FHB susceptibility genotype, Glenn, were added to high susceptibility genotype, Samson. Wheat bran/agar plates enriched with linoleic acid significantly (p<0.05) reduced the growth rate of F. graminearum in both Glenn and Samson genotypes. Oxygenated fatty acids, including monohydroxy- and dihydroxy- fatty acids were identified in the MSC.
Hard Red Spring Wheat Quality Evaluation with Various Roller Mill Types and Breadmaking Methods
(North Dakota State University, 2016) Baasandorj, Tsogtbayar
Roller mill type and breadmaking methods might be a source of variation in the evaluation of the end-use quality of Hard Red Spring (HRS) wheat. In this study, various roller mill types and baking methods have been used to investigate whether they affect end-use quality evaluation of HRS wheat cultivars. In addition, a quality scoring system has been developed to determine if ranking of the HRS wheat cultivars would change when different roller mills and breadmaking methods were used. Both the roller mill type and breadmaking method had an effect on the end-use quality of HRS wheat cultivars. When using different roller mills for quality evaluation, HRS wheat samples of MN Bolles and ND Glenn from Gulf/Great Lakes (G/GL) region and ND Glenn from Casselton location had overall quality scores of 6.5 or above when averaged across mill types. When using various baking methods and conditions for quality evaluation, ND 817, MN Bolles, ND Glenn cultivars from Pacific Northwest region, and MN Bolles and ND Glenn from G/GL region received overall baking quality scores of 6.5 or above hence these cultivars were considered to have “excellent” baking quality characteristics under different baking conditions. The results in the current research study indicate that although there are differences in the mill type and breadmaking methods on the end-use quality evaluation, the ranking of HRS wheat flours is not affected by the mill type or baking methods and conditions. In other words, cultivars considered to have “fair” quality tend to have low end-use quality, while “excellent” cultivars will have superior end-use quality regardless of the roller mills and/or baking method and processing conditions used. The proposed overall wheat scoring system could assist farmers and breeders in selection of wheat cultivars considering the wheat end-use quality. Development of a comprehensive scoring system will also enable a more detailed scoring system for screening new lines for suitable end-use.
Historical and Modern Hard Red Spring Wheat Comparison: Analysis of Proximate, Enzyme Activity, Phenolic Acid, and Starch Properties
(North Dakota State University, 2016) Schwebach, Catherine Suzanne
Some claim modern wheat is biochemically different from historic wheat and contributes to chronic diseases. This research was necessary to determine if any significant differences existed between historic and modern hard red spring (HRS) wheat in several physical and chemical components. Thirty HRS cultivars were grown in the same year and location and underwent laboratory analysis. In relation to release year, significant (P<0.05) differences were found for ash content (AC), phosphorous, potassium, zinc, arabinose-to-xylose ratio, enzyme activities, and phenolic acids in whole wheat, AC, and α-amylase and xylanase activities in white flour, and total starch in bread. The remaining parameters displayed no significant (P>0.05) differences in correlation to release year, including starch digestibility. The majority of results indicate no significant biochemical variations between the historic and modern HRS cultivars. Parameters that demonstrated differences have the potential to affect consumer health and nutrition, but are dependent on bioavailability and consumer choice.
Investigation of Protein Composition in Historical and Modern Hard Red Spring Wheat Cultivars
(North Dakota State University, 2016) Malalgoda, Marie Maneka Rajini
Many hard red spring (HRS) wheat cultivars have been released in North Dakota with improved traits. In this study, 30 HRS wheat cultivars released between 1910 and 2013 were investigated. The objectives of this study were to determine how wheat protein chemistry changed over the last century, and if modern wheat is more toxic in terms of celiac disease in comparison to historical wheat. The gliadin and glutenin protein profiles were analyzed using HPLC, and immunogenic peptides causing celiac disease was determined using mass spectrometry. Cluster analysis was performed to evaluate how the cultivars clustered with regard to parentage and protein separation profiles. The results indicated that ω-gliadin together with glutenin proteins may have a positive contribution towards favorable dough properties, and that these cultivars can be clustered according year when parentage and protein HPLC area data are used. Additionally, immunogenic peptides were detected in both historical and modern wheat.
Iron Biofortification Potential of Field Pea (Pisum Sativum L.)
(North Dakota State University, 2012) Amarakoon, Amarakoon Rajapakse Wasala Mohotti Mudiyanselage Darshika
Iron (Fe) deficiency affects more than 3 billion of the global population. The objectives of this study were to (1) determine the genetic and environmental variation of seed Fe concentration and food matrix factors that govern Fe bioavailability in field peas (Pisum sativum L.) grown in North Dakota, USA in 2010 and 2011, and (2) determine the genetic variation of Fe uptake by field pea grown under greenhouse conditions with different Fe treatments. Seed Fe concentration in field pea samples from the field study ranged between 46-53 mg/kg with a mean of 51 mg/kg. Mean concentrations of the food matrix factors in those field peas were as follows: phytic acid=5.1 mg/g, xanthophyll=17.3 mg/100 g, canthaxanthin=86.8 mg/100 g, beta-carotene=516.8 μg/100 g, kestose=1697 mg/100g, quercetin=54.3 mg/100 g, and ferulic acid=46.9 mg/100 g. DS Admiral and CDC Golden showed high concentrations of Fe promoter compounds and low concentrations of phytic acid. DS Admiral showed high Fe uptake with increasing Fe fertilizer rates in the greenhouse study. Therefore, DS Admiral and CDC Golden could be potential field pea genotypes for future Fe biofortification efforts.

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