Hydrolysis of cassava starch by amylases from maize
Table Of Contents
<p> </p><div><p>PAGE</p><p>Title Page i</p><p>Certification ii</p><p>Acknowledgements iv</p><p>Abstract v</p><p>Table of Contents vi</p><p>List of Figures ix</p><p><b>
Chapter ONE
: INTRODUCTION</b></p><p>11 Introduction 1</p><p>12 Biology of Cassava and Maize 2</p><p>121 Cassava 2</p><p>122 Maize 6</p><p>13 Starch 8</p><p>131 Starch properties 8</p><p>132 Test for starch 10</p><p>133 Cassava starch 11</p><p>134 Starch synthesis 12</p><p>135 General biosynthesis of polysaccharides 12</p><p>136 Biosynthesis of a glycosidic bond 14</p><p>137 Structural alterations to sugar nucleotide before polysaccharide assembly 16</p><p>138 Starch hydrolysis (degradation) 17</p><p>139 Acid hydrolysis 17</p><p>1310 Enzyme hydrolysis of starch 19</p><p>14 Amylases 19</p><p>141 General properties of amylases 19</p><p>142 Sources of amylases 20</p><p>143 Plant amylases 20</p><p>144 Amylases production in germinating cereals 21</p><p>145 Maize amylases 22</p><p>15 Aims and objectives of research 23</p></div><div><p><b>Chapter TWO
: MATERIALS AND METHODS</b></p><p>21 Materials 24</p><p>211 Sample collection and location(s) 24</p><p>2111 Cassava varieties 24</p><p>2112 Maize varieties 24</p><p>212 Chemicals/Reagents/Samples 25</p><p>213 Apparatus 26</p><p>22 Methods 26</p><p>221 Preparation of buffers 26</p><p>222 Extraction of cassava starch 27</p><p>223 Glucose calibration curve 27</p><p>224 Enzyme extraction 27</p><p>225 Method of enzyme assay 27</p><p>226 Effect of germination on maize amylase activity 27</p><p>227 Effect of pH on maize amylase activity 28</p><p>228 Germination of maize 28</p><p>229 Determination of activity in 20 varieties of hydrid maize 28</p><p>2210 Assay of amylase activity in maize 28</p><p>2211 Effect of Ca</p><p>2+</p><p>ions on amylase activity 29</p><p>2212 Determination of protein concentration in all enzyme extracts 29</p><p>2213 Protein determination 29</p><p>2214 Maize amylase specific activity 30</p><p>2215 Activity of maize amylase on cassava starch 30</p><p>2216 Effect of pH on amylase activity using cassava starch as substrate 30</p><p>2217 Effect of substrate concentration on enzyme activity 30</p><p>23 Statistical Analysis 31</p><p><b>Chapter THREE
: RESULTS</b></p><p>31 Effect of germination on amylase activity 32</p><p>32 Effect of pH on amylase activity 32</p><p>33 Amylase activity before imbibition at pH 55, 75 and 95 33</p><p>34 Amylase activity on day 3 after imbibition at pH 55, 75 and 95 34</p></div><div><p>35 Amylase activity on day 5 after imbibition at pH 55, 75 and 95 35</p><p>36 Protein determination 39</p><p>37 Maize amylase specific activity 41</p><p>38 Determination of maize variety with the highest amylase activity 45</p><p>39 Hydrolysis of cassava starch by enzyme extract from VARIF2 45</p><p>310 Effect of Ca</p><p>2+</p><p>on enzyme activity 45</p><p>311 Effect of substrate (starch) concentration on maize enzyme activity 45</p><p>312 Effect of pH on amylase activity using 1% cassava starch 46</p><p><b>Chapter FOUR
: DISCUSSION AND CONCLUSION</b></p><p>41 DISCUSSION 50</p><p>42 CONCLUSION 55</p><p><b>REFERENCES 57</b></p><p><b>APPENDICES 62</b></p></div><h3></h3><br> <br><p></p>Project Abstract
AbstractThe hydrolysis of cassava starch using amylases derived from maize presents an interesting avenue for the production of various value-added products. Amylases are enzymes that catalyze the hydrolysis of starch into simpler sugars, which can be further utilized in industries such as food, pharmaceuticals, and biofuels. In this study, we investigated the efficiency of maize-derived amylases in hydrolyzing cassava starch and the potential applications of the resulting products. The first step involved the extraction and purification of the amylases from maize. Various extraction methods, such as homogenization and centrifugation, were employed to isolate the enzymes effectively. Subsequently, the extracted enzymes were characterized for their optimal pH and temperature conditions to determine the most suitable conditions for the hydrolysis process. The enzymatic activity of the maize-derived amylases was also assessed to evaluate their efficiency in breaking down cassava starch. The hydrolysis of cassava starch was carried out using the maize-derived amylases under the optimized conditions. The progress of the hydrolysis reaction was monitored by analyzing the samples at regular time intervals to measure the concentration of reducing sugars produced. The efficiency of the enzymatic hydrolysis was compared with traditional chemical methods to assess the advantages of using the maize-derived enzymes. Furthermore, the hydrolyzed products were analyzed for their sugar composition using techniques such as high-performance liquid chromatography (HPLC) and thin-layer chromatography (TLC). The identification of the sugar components in the hydrolysate provided insights into the breakdown pattern of cassava starch by the maize-derived amylases. Additionally, the potential applications of the hydrolyzed products in various industries, such as the production of syrups, bioethanol, and other bioproducts, were explored. Overall, the results demonstrated the effectiveness of maize-derived amylases in hydrolyzing cassava starch and generating valuable sugar products. The study highlights the potential of utilizing plant-derived enzymes for starch hydrolysis and the production of diverse bioproducts. The findings contribute to the growing field of enzyme technology and offer insights into sustainable approaches for processing starch-rich raw materials like cassava.
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