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<p style="font-size:18px"> The experiment 1 illustrates the relationship between the concentration of glucose and the absorbance of the solution with DNS colorant. By using linear regression, we constructed a function with glucose concentration (μmol) as the x-axis and the ab-sorbance as the y-axis. </p> | <p style="font-size:18px"> The experiment 1 illustrates the relationship between the concentration of glucose and the absorbance of the solution with DNS colorant. By using linear regression, we constructed a function with glucose concentration (μmol) as the x-axis and the ab-sorbance as the y-axis. </p> | ||
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<p style="font-size:18px"> From the first half of the graph, we can clearly discover the linear relationship between enzyme concentration and the absorbance. Data suggest that as the concentration of enzyme becomes greater, the relative absorbance increase proportionately. This result justified our assumption. However, the latter half illustrated a negative-related relationship. We suspected that we didn’t use enough substrate to allow the decomposition reaction. Also, we assumed that excessive concentration of enzymes will negatively affect the reaction rate.</p> | <p style="font-size:18px"> From the first half of the graph, we can clearly discover the linear relationship between enzyme concentration and the absorbance. Data suggest that as the concentration of enzyme becomes greater, the relative absorbance increase proportionately. This result justified our assumption. However, the latter half illustrated a negative-related relationship. We suspected that we didn’t use enough substrate to allow the decomposition reaction. Also, we assumed that excessive concentration of enzymes will negatively affect the reaction rate.</p> | ||
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Revision as of 02:18, 18 October 2018
Experiment Data
Analysis
The experiment 1 illustrates the relationship between the concentration of glucose and the absorbance of the solution with DNS colorant. By using linear regression, we constructed a function with glucose concentration (μmol) as the x-axis and the ab-sorbance as the y-axis.
In the experiment 2, we measured the stability of sucrose and dextran, as well as pH stability. We let the reaction take place in the hot pot set at 100℃. We observed that dextran has a poor hot stability. Moreover, the sucrose will decompose spontaneous-ly under the acidic condition while heat doesn’t affect the decomposition of sucrose.
Analysis
From the first half of the graph, we can clearly discover the linear relationship between enzyme concentration and the absorbance. Data suggest that as the concentration of enzyme becomes greater, the relative absorbance increase proportionately. This result justified our assumption. However, the latter half illustrated a negative-related relationship. We suspected that we didn’t use enough substrate to allow the decomposition reaction. Also, we assumed that excessive concentration of enzymes will negatively affect the reaction rate.