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Improvement of zein dough characteristics using dilute organic acidsSly, Alexandra Claire January 2013 (has links)
The only treatment for coeliac disease, a common autoimmune disorder, is life-long adherence to a gluten-free diet. However, the replacement of wheat gluten, a key structural and functional component in bread, poses a major technological challenge for food scientists. The use of non-wheat cereal proteins, as alternatives to gluten, shows much promise in gluten-free bread making. Literature has shown that when zein, the maize prolamin protein, is subjected to wet heat above its glass transition temperature (Tg), the protein becomes viscoelastic, rubbery and dough-like. Gluten-like fibrils are visible, which form complex protein networks similar to those found in wheat dough. The resulting zein dough has viscoelastic characteristics and can be successfully used with hydrocolloids to produce gluten-free bread.
This project examined the influence of wet heat treatment and dilute organic acids (lactic acid and acetic acid) on the dough-making quality of non-wheat cereal proteins, such as kafirin and zein. Zein was the only non-wheat cereal protein to show any physical change when it was subjected to wet heat treatments, forming a dough-like substance. Acidification of the zein dough prepared at 40°C with concentrations of 0.7, 1.3 and 5.4% (v/v) organic acid in distilled water solutions, showed that the higher the concentration of acid used, the greater its effect on the dough's rheological properties. Tensile tests using a Keifer rig on zein dough showed that as the concentration of organic acid was increased from 0.7 to 1.3 and to 5.4% (v/v) the dough become softer and increasingly more extensible. The dough also exhibited less resistance to extension and reduced elasticity. CLSM revealed that the zein doughs contained a protein network, made up of fine protein fibrils, which became smoother and more homogenous as the concentration of acid was increased. Although SDS-PAGE revealed that no oligomerization took place with acid addition,
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FTIR showed that zein dough prepared with distilled water at 40°C had elevated levels of β-sheets. When organic acids were added in increasing levels, corresponding increases in the quantities of α-helices in the protein were observed. Alveography showed that zein-based doughs prepared with dilute organic acids retained gases well and that the concentration of dilute organic acids influenced dough distensibility (biaxial extensibility) and stability (the ability of the dough to retain gas). Low concentration of acids (0.7 and 1.3%) increased dough stability to levels similar to that of strong wheat flour, 103 mm H2O, but higher concentrations of acids (5.4%) led to a marked reduction in dough stability. Thus, by increasing zein dough functionality to such an extent, the apparent usefulness of the doughs and their ability to retain gases produced during fermentation is reduced. Simple distensibility tests on zein doughs showed that added organic acids promoted ‘clumping’ of the fine protein fibrils in the dough network into pronounced fibres. This would account for the decreased dough stability when high levels (5.4%) of organic acids were used. Baking trials with zein doughs were not successful as adequate leavening was impossible without an acid-tolerant leavening agent.
It is believed that dilute organic acids influence the rheological properties of zein dough by creating a positively charged environment, in which the protein is partially solubilized. The higher the level of organic acid used, the greater the positive net charge and the more pronounced the effect on the protein network structure. Organic acids could also improve fluidity of the zein dough by acting as plasticizers.
From this work it can be seen that although a protein network is present in all zein-based doughs, the ability of this network to retain gases is dependant on the level of organic acids present. The functional properties of zein-doughs made with low levels of organic acids (0.7 and 1.3%) shows potential in the production of gluten-free bread for individuals suffering from coeliac disease. / Dissertation (MSc)--University of Pretoria, 2013. / gm2014 / Food Science / unrestricted
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Potatisfibers inverkan på bröd : hur påverkas deg och bröd av potatisfiberns malningsgrad? / The impact of using potato fiber in bread : how does the potato fiber grind affect dough and bread?Rothman, Emma, Erlandsson, Jakob January 2019 (has links)
Introduktion: Potatisfibern utgör ca 1 % av potatisens vikt och är en restprodukt vid tillverkningen av potatisstärkelse. Idag tillsätter flera välkända livsmedelsföretag potatisfiber i sina produkter. Den främsta anledningen till detta är för att fibern kan binda vätska 7–12 gånger sin egen vikt vilket kan ge en ekonomisk fördel. Syfte: Syftet med studien är att jämföra hur grovmalen respektive finmalen potatisfiber påverkar utvalda egenskaper i degen och brödet med särskilt fokus på brödets lagringsstabilitet. Metod: Pilottester Observationer av degegenskaper Mätning av vätskeförlust och brödvolym Instrumentell färgmätning med en kolorimeter Sensorisk bedömning av lagringsstabilitet Resultat: Pilottester av båda malningsgraderna av potatisfibern visade att vid en jämförelse av olika förbehandlingar så som skållning, blötläggning och tillsats direkt i degen, gav direkt tillsats av potatisfiber i degen flest fördelar, främst gällande mjukheten i degen. Vid observationen fanns en synlig färgskillnad mellan bröden med tillsatts potatisfiber och referensbrödet men detta säkerställdes inte vid den instrumentella färgmätningen. Brödens volym och vattenhållande förmåga påverkades inte av tillsats av potatisfiber. Den sensoriska bedömningen visade en upplevd torrhetskänsla för bröd med tillsatt potatisfiber (båda malningsgraderna) när det testades mot ett referensbröd. Den finmalda fibern påverkade lagringsstabiliteten mer än den grovmalda fibern gjorde. Slutsats: Malningsgraden gav inga märkbara skillnader på de utvalda deg- och brödegenskaperna. Potatisfiber hade inte tillräckligt stor påverkan på deg eller bröd för att antas vara lönsam att tillsätta vid brödbakning. / Introduction: The potato fiber constitutes about 1 % of the weight of the potato and is a residual product in the manufacture of potato starch. Today, several well-known companies add potato fiber to their products. The main reason for this is because the fiber can bind liquid 7–12 times its own weight, which gives an economic advantage. Aim: The aim of this study is to investigate how the grind of potato fiber affects selected characteristics in dough and bread, with particularly focus on the storage stability of the bread. Method: Pilot tests Observations of dough characteristics Measure of water exchange and bread volume Instrumental color measurement with a colorimeter Sensory evaluation of storage stability Results: Pilot tests with both grinds of potato fiber showed that when comparing pre-treatments such as scalding, soaking and direct addition into the dough, a direct addition resulted with the most advantages, mainly regarding the softness of the dough. During the observations there was a visible difference in color between the potato fiber loaves and the reference loaf, which was not ensured in the instrumental color measurement. The volume and water retention in the bread was not affected by an addition of potato fiber. The sensory evaluation showed a perceived dryness for bread with added potato fiber (both grinds), when tested against a reference bread. The finely ground fiber affected the storage stability more than the coarse grounded fiber did. Conclusion: The grind gave no notable differences on the selected properties of dough and bread. The impact that grind had on dough characteristics and the finished bread were small.
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