TIGER

Journal Articles: 23 results
Size Exclusion Chromatography: An Experiment for High School and Community College Chemistry and Biotechnology Laboratory Programs  Linda S. Brunauer and Kathryn K. Davis
Describes an experiment in which students use column chromatography to separate and characterize biomolecules, thus expanding their exposure to chromatographic procedures beyond those more commonly employed at the secondary level (e.g., paper or thin-layer chromatography).
Brunauer, Linda S.; Davis, Kathryn K. J. Chem. Educ. 2008, 85, 683.
Biotechnology |
Chromatography |
Enzymes |
Separation Science |
Spectroscopy
A Bioanalytical Chemistry Experiment for Undergraduate Students: Biosensors Based on Metal Nanoparticles  John Njagi, John Warner, and Silvana Andreescu
Describes a laboratory experiment on the development of a biosensor in which students apply electrochemical methods to deposit gold nanoparticles onto electrode surfaces, immobilize an enzyme using glutaraldehyde chemistry, and perform quantitative analysis of phenol using a biosensor with amperometric detection.
Njagi, John; Warner, John; Andreescu, Silvana. J. Chem. Educ. 2007, 84, 1180.
Bioanalytical Chemistry |
Electrochemistry |
Enzymes |
Oxidation / Reduction |
Phenols
An Enzyme Kinetics Experiment Using Laccase for General Chemistry   Yaqi Lin and Patrick M. Lloyd
This article describes the use of laccase, an oxidoreductase enzyme, to study the effects of enzyme catalysts on reaction rates.
Lin, Yaqi; Lloyd, Patrick M. J. Chem. Educ. 2006, 83, 638.
Aldehydes / Ketones |
Bioanalytical Chemistry |
Catalysis |
Enzymes |
Kinetics |
UV-Vis Spectroscopy
Glycosyltransferases A and B: Four Critical Amino Acids Determine Blood Type  Natisha L. Rose, Monica M. Palcic, and Stephen V. Evans
Human A, B, and O blood type is determined by the presence or absence of distinct carbohydrate structures on red blood cells. In this review the chemistry of the blood group ABO system and the role of glycosyltransferase A, glycosyltransferase B, and the four amino acids critical to determining blood group status are discussed.
Rose, Natisha L.; Palcic, Monica M.; Evans, Stephen V. J. Chem. Educ. 2005, 82, 1846.
Carbohydrates |
Enzymes |
Kinetics |
Bioorganic Chemistry |
Crystals / Crystallography |
Molecular Biology |
X-ray Crystallography |
Amino Acids
Removal of Zinc from Carbonic Anhydrase. A Kinetics Experiment for Upper-Level Chemistry Laboratories  Kathryn R. Williams and Bhavin Adhyaru
The Zn(II) ion in the active site of carbonic anhydrase can be removed by complexation with 2,6-pyridinedicarboxylate (dipicolinate).
Williams, Kathryn R.; Adhyaru, Bhavin. J. Chem. Educ. 2004, 81, 1045.
Kinetics |
Biophysical Chemistry |
Nuclear / Radiochemistry |
Enzymes |
Instrumental Methods
Chemistry and Flatulence: An Introductory Enzyme Experiment  John R. Hardee, Tina M. Montgomery, and Wray H. Jones
An enzyme experiment using raffinose family sugars extracted from green split peas as a substrate and the enzymes alpha-galactosidase and sucrase found in Beano. The reaction studied was the hydrolysis of raffinose family sugars to galactose, glucose, and fructose, and the reaction rate was determined using a retail glucometer to measure the concentration of glucose.
Hardee, John R.; Montgomery, Tina M.; Jones, Wray H. J. Chem. Educ. 2000, 77, 498.
Nonmajor Courses |
Enzymes |
Food Science |
Rate Law |
Catalysis |
Applications of Chemistry
Homogeneous Immunoassays: Historical Perspective and Future Promise  Edwin F. Ullman
The founding and growth of Syva Company is examined in the context of its leadership role in the development of homogeneous immunoassays. The simple mix and read protocols of these methods offer advantages in routine analytical and clinical applications.
Ullman, Edwin F. J. Chem. Educ. 1999, 76, 781.
Biotechnology |
Enzymes |
Atomic Properties / Structure |
Free Radicals |
Photochemistry |
Medicinal Chemistry |
Proteins / Peptides
A 19F NMR Study of Enzyme Activity  Keith E. Peterman, Kevin Lentz, and Jeffery Duncan
This basic enzyme activity laboratory experiment demonstrates how 19F NMR can be used in biochemical studies and presents the advantages of 19F NMR over 1H NMR for studies of this nature. This is a viable laboratory experiment for junior/senior-level courses in instrumental analytical chemistry, biochemistry, molecular biology, or spectroscopy.
Peterman, Keith E.; Lentz, Kevin; Duncan, Jeffery. J. Chem. Educ. 1998, 75, 1283.
Instrumental Methods |
Enzymes |
NMR Spectroscopy |
Spectroscopy
A Simple Method To Demonstrate the Enzymatic Production of Hydrogen from Sugar  Natalie Hershlag, Ian Hurley, and Jonathan Woodward
In the experimental protocol described here, it has been demonstrated that the common sugar glucose can be used to produce hydrogen using two enzymes, glucose dehydrogenase and hydrogenase. No sophisticated or expensive hydrogen detection equipment is required-only a redox dye, benzyl viologen, which turns purple when it is reduced. The color can be detected by a simple colorimeter.
Hershlag, Natalie; Hurley, Ian; Woodward, Jonathan. J. Chem. Educ. 1998, 75, 1270.
Enzymes |
Kinetics |
UV-Vis Spectroscopy |
Carbohydrates |
Applications of Chemistry
Working with Enzymes - Where Is Lactose Digested? An Enzyme Assay for Nutritional Biochemistry Laboratories  Sandi R. Pope, Tonya D. Tolleson, R. Jill Williams, Russell D. Underhill, and S. Todd Deal
An enzyme assay utilizing lactase enzyme from crushed LactAid tablets and a 5% lactose solution ("synthetic milk"). In the experiment, the students assay the activity of the enzyme on the "synthetic milk" at pHs of approximately 1, 6, and 8 with the stated goal of determining where lactose functions in the digestive tract. The activity of the lactase may be followed chromatographically or spectrophotometrically.
Pope, Sandi R.; Tolleson, Tonya D.; Williams, R. Jill; Underhill, Russell D.; Deal, S. Todd. J. Chem. Educ. 1998, 75, 761.
Enzymes |
Carbohydrates |
Catalysis |
Chromatography |
Spectroscopy |
Nutrition
Disadvantages of Double Reciprocal Plots  R. Bruce Martin
Because they involve grossly uneven weightings of points, the linear and formally similar double reciprocal Benesi-Hildebrand and Lineweaver-Burke plots should never be used to resolve equilibrium and enzyme kinetic results.
Martin, R. Bruce. J. Chem. Educ. 1997, 74, 1238.
Biophysical Chemistry |
Enzymes |
Equilibrium |
Kinetics
Detoxifying enzymes and insect symbionts  Shen, Samuel K.; Dowd, Patrick F.
Enzymes and pathways for the detoxification of substances in a variety of organisms.
Shen, Samuel K.; Dowd, Patrick F. J. Chem. Educ. 1992, 69, 796.
Enzymes |
Toxicology
A biochemistry project to study mushroom tyrosinase: Enzyme localization, isoenzymes, and detergent activation  Rodriquez, Marta Olga; Flurkey, William H.
Investigating mushroom tyrosinase isoenzymes in different tissue sections of commercial mushrooms.
Rodriquez, Marta Olga; Flurkey, William H. J. Chem. Educ. 1992, 69, 767.
Enzymes |
Electrophoresis |
Kinetics
Enzyme activity: The ping-pong ball torture analogy  Helser, Terry L.
The author uses this analogy to help students visualize and understand the effect of reaction conditions on the initial rate of an enzyme-catalyzed reaction.
Helser, Terry L. J. Chem. Educ. 1992, 69, 137.
Enzymes |
Reactions
Enzyme activity: A simple analogy   Abel, Kenton B.; Halenz, Donald R.
Presented here is a simple analogy that has helped students in our classes grasp the concept of enzyme activity
Abel, Kenton B.; Halenz, Donald R. J. Chem. Educ. 1992, 69, 9.
Enzymes
An NMR study of the stereochemistry of the fumarase-catalyzed hydration of fumaric acid  Olsen, Julie A.; Olsen, Robert J.
An NMR study of the stereochemistry of the fumarase-catalyzed hydration of fumaric acid.
Olsen, Julie A.; Olsen, Robert J. J. Chem. Educ. 1991, 68, 436.
Acids / Bases |
NMR Spectroscopy |
Enzymes |
Molecular Modeling |
Diastereomers
Superoxide dismutase and the Briggs-Rauscher reaction  Franz, David A.
Oxygen-derived species provide chemistry teachers with excellent examples for discussion of molecular-orbital theory, bond order and reactivity, redox potentials, radical reactivity, disproportionation, and enzyme activity.
Franz, David A. J. Chem. Educ. 1991, 68, 57.
Enzymes |
Biophysical Chemistry |
MO Theory |
Oxidation / Reduction |
Covalent Bonding
RNA's as catalysts: A new class on enzymes  McCorkle, George M.; Altman, Sidney
Analysis of two RNA's that act as enzymes, upsetting the long-held position that all enzymes are proteins.
McCorkle, George M.; Altman, Sidney J. Chem. Educ. 1987, 64, 221.
Catalysis |
Enzymes
Optical projection experiments to demonstrate new curricula contents   Perina, Ivo
Demonstration of experiments by optical projection compared with classic demonstration of experiments has a number of advantages.
Perina, Ivo J. Chem. Educ. 1986, 63, 344.
Alcohols |
Enzymes |
Atmospheric Chemistry
The catalytic function of enzymes  Splittgerber, Allan G.
Review of the structure, function, and factors that influence the action of enzymes.
Splittgerber, Allan G. J. Chem. Educ. 1985, 62, 1008.
Catalysis |
Enzymes |
Mechanisms of Reactions |
Proteins / Peptides |
Molecular Properties / Structure
A demonstration of enzyme activity for the "Sceptical Chymist"  Fried, Rainer; Howse, Margaret
A simple laboratory or demonstration that illustrates the nature and fundamental properties of enzymes through a color change.
Fried, Rainer; Howse, Margaret J. Chem. Educ. 1971, 48, 847.
Enzymes |
Rate Law
Simple method for demonstrating an enzymatic reaction  Tang, Chung-Shih
Uses taste sensations of papaya seeds under varying conditions to demonstrate an enzymatic reaction.
Tang, Chung-Shih J. Chem. Educ. 1970, 47, 692.
Enzymes |
Proteins / Peptides |
Food Science |
Reactions |
Consumer Chemistry |
Applications of Chemistry
Reaction rate analysis and instrumentation: An experiment for the analytical laboratory  Pardue, Harry L.; Burke, Michael F.; Jones, David O.
This experiment exemplifies the use of operational amplifiers for measurement and analog computation in determining the glucose utilizing glucose enzyme.
Pardue, Harry L.; Burke, Michael F.; Jones, David O. J. Chem. Educ. 1967, 44, 684.
Kinetics |
Rate Law |
Catalysis |
Enzymes |
Carbohydrates