Browsing by Person "Srivastava, Shubhangi"

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Experimental investigation of CO2 uptake in CO2 hydrates formation with amino acids as kinetic promoters and its dissociation at high temperature
(2022) Srivastava, Shubhangi; Kollemparembil, Ann Mary; Zettel, Viktoria; Claßen, Timo; Gatternig, Bernhard; Delgado, Antonio; Hitzmann, Bernd; Srivastava, Shubhangi; Department of Process Analytics and Cereal Science, University of Hohenheim, Stuttgart, Germany; Kollemparembil, Ann Mary; Department of Process Analytics and Cereal Science, University of Hohenheim, Stuttgart, Germany; Zettel, Viktoria; Department of Process Analytics and Cereal Science, University of Hohenheim, Stuttgart, Germany; Claßen, Timo; Department of Process Analytics and Cereal Science, University of Hohenheim, Stuttgart, Germany; Gatternig, Bernhard; German Engineering Research and Development Center LSTME Busan, Busan, Republic of Korea; Delgado, Antonio; German Engineering Research and Development Center LSTME Busan, Busan, Republic of Korea; Hitzmann, Bernd; Department of Process Analytics and Cereal Science, University of Hohenheim, Stuttgart, Germany
The dissociation of CO2 gas hydrates (GH) with amino acid kinetic promoters and without promoters was studied at a high temperature of 90 °C for a period of 20 min to understand the percentage of CO2 gas and to select the best promoter that aids CO2 gas entrapment along with stability at a high temperature. The possibility of using four hydrophobic food grade amino acids, namely cysteine, valine, leucine, and methionine, and one surfactant, lecithin, as kinetic promoters for CO2 GH has been studied. The amino acids were added 0.5 g (wt%), and lecithin was added 5 g for the GH production. Furthermore, the amino acids leucine and methionine gave some positive results, therefore, these amino acids were carried further for the experimentation purpose in the production of CO2 GH. Also, a combinational use of these amino acids was studied to investigate the effect on % CO2 retention in comparison to the normal GH. From the results, it was observed that the stability of GH decreases with an increase in temperature, but the addition of promoters, especially leucine + methionine + lecithin increased the CO2 uptake during GH formation.
An innovative approach in the baking of bread with CO2 gas hydrates as leavening agents
(2022) Srivastava, Shubhangi; Kollemparembil, Ann Mary; Zettel, Viktoria; Claßen, Timo; Mobarak, Mohammad; Gatternig, Bernhard; Delgado, Antonio; Jekle, Mario; Hitzmann, Bernd
Gas (guest) molecules are trapped in hydrogen-bonded water molecules to form gas hydrates (GH), non-stoichiometric solids that resemble ice. High pressure and low temperature are typical conditions for their development, with van der Waals forces joining the host and guest molecules. This article study investigates the application of CO2 gas hydrates (CO2 GH) as a leavening agent in baking, with particular reference to the production of wheat bread. The main intention of this study is to better understand the complex bread dough formed by CO2 GH and its impact on product quality. This may enable the adaptation of CO2 GH in baking applications, such as those that can specifically influence wheat bread properties, and so the final bread quality. The present research further examines the comparative evaluation of yeast bread with the GH bread’s impact on bread quality parameters. The amount of GH was varied from 10 to 60%/amount of flour for the GH breads. The GH breads were compared with the standard yeast bread for different quality parameters such as volume, texture, and pore analysis. The results show that the bread with 20% and 40% GH obtained the best results in terms of volume and pore size. Moreover, this article also sheds some light on the future applications of the use of CO2 GH as leavening agents in foods. This knowledge could help to create new procedures and criteria for improved GH selection for applications in bread making and other bakery or food products.
Production of CO₂ gas hydrates with its application in wheat bread making process
(2023) Srivastava, Shubhangi; Hitzmann, Bernd
The basic requirements necessary for gas hydrate (GH) formation are low temperature, high pressure, the presence of guest molecules, and the desired amounts of water molecules. The most common guest molecules used for the GH are ethane, methane, butane, propane, nitrogen, and carbon dioxide. Hydrate based technological applications almost always require rapid hydrate formation along with high gas uptake to be economically viable. One possible approach to achieving the same is the introduction of particular additives into the system. These additives are known as hydrate promoters. In recent times, amino acids have emerged as a highly effective class of promoters, and unlike surfactants, they promise a clean mode of kinetic action, i.e., no foam formation. Hence, the first part of the thesis dealt with the optimisation of GH formation with the application of amino acid promoters. The optimisation of the GH production was performed with different combinations of promoter ingredients namely cysteine, valine, leucine, and methionine. The amino acids leucine and methionine gave some positive results with the application of promoters for the production of GH therefore, these two amino acids were carried further for the experimentation purpose in the production of GH. Also, a combinational use of these amino acids (leucine and methionine) was studied to investigate the effect on percentage CO₂ retention in comparison to the normal water GH. The conventional baker’s yeast, Saccharomyces cerevisiae, remains the popular leavening agent in the bread baking industry. Carbon dioxide required for the rising of dough is produced by the metabolism of yeast with the consumption of sugars in the dough, which is a time and energy-consuming process. This research attempts to utilize carbon dioxide gas hydrate as a leavening agent in bread. Despite plentiful experiments on CO₂ gas hydrates in other fields, there is still an urge to carry out more analysis to elucidate various applications of GH in baking and positively validate its sustainability. The temperature stability of GH is important while baking due to the exposure to high temperatures during the various steps involved. In order to effectively use CO₂ GH as a leavening agent in the baking industry, a concise evaluation of the formation of CO₂ GH and its gas containment capacity should be adequately analysed and documented. Also, the effect of CO₂ GH properties by the addition of promoters should be taken into consideration as baking involves higher temperatures, and stabilising the GH at higher temperatures is an important criterion in the context of baking different products. Hence, the effect of a higher temperature of 90 ℃; on the CO₂ gas entrapment of the produced GH with promoters was studied. It was observed that the stability of GH decreases with an increase in temperature, but the addition of promoters, especially leucine + methionine + lecithin increased the CO₂ uptake during GH formation. Another part of the thesis was the application of GH in the baking bread with/without promoters and the study of physio chemical properties of bread. By varying the percentage of gas hydrates from 10-60 %, analysis of the performance of CO₂ GH as a leavening agent during baking was done. The effectiveness of GH bread was evaluated by comparing its characteristics to those of standard bread made with yeast. Also, a comparative evaluation was made for bread with and without promoters GH as leavening agents in terms of different physio chemical characteristics of the bread, such as moisture analysis, volume analysis, pore analysis, texture profile analysis, and baking loss. The results show that the bread with 20 % and 40 % GH obtained the best results in terms of volume and pore size. The next part of the thesis dealt with a comparative analysis of the partial replacement of yeast with CO₂ GH as leavening agents in bread baking. By partially eliminating the yeast, variations of bread dough were produced by the addition of GH in different percentages (20-70 %). The effectiveness of GH on bread manufacture was evaluated by comparing its characteristics to that of standard bread made with yeast. Once the bread was baked, the texture profile, volume, moisture content, and pore size were recorded to compare the leavening effect of GH with the standard recipe when partial addition of yeast was done. The best results combinations with respect to specific volume, pore analysis and hardness were obtained with 70 % GH + 50 % yeast and 70 % GH + 75 % yeast, respectively. As the final part of the thesis, the influence of additives on wheat bread baked with promoter induced CO₂ GH as leavening agents was studied. The additives used for the study were ascorbic acid (AC), egg white (EW), and rice flour (RF). These additives were added to the GH bread containing different amounts of GH (40, 60, and 70 % GH). Also, a combination of these additives in a wheat GH bread recipe was studied for each respective percentage of GH. Based on the results of the study, it was found that 70 % GH+ AC+EW+RF wheat bread was found to be the best in terms of textural analysis, pore size analysis, and other physiochemical parameters. Therefore, this research study will help us in understanding the application of GH in the bread baking process with replacement of conventional baking agents such as yeast.