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Structure and Dynamics of Macromolecules Absorption and Fluorescence Studies 1st Edition by Albani 9780444514493 044451449X

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Structure and Dynamics of Macromolecules Absorption and Fluorescence Studies 1st Edition J.R. Albani Digital Instant Download

Author(s): J.R. Albani
ISBN(s): 9780444514493, 044451449X
Edition: 1
File Details: PDF, 32.02 MB
Year: 2005
Language: english
SKU: EB-1208234 Category: Tag:

Structure and Dynamics of Macromolecules Absorption and Fluorescence Studies 1st Edition by Albani – Ebook PDF Instant Download/Delivery: 9780444514493, 044451449X

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Product details:

ISBN 10: 044451449X

ISBN 13: 9780444514493

Author: J.R. Albani

Structure and Dynamics of Macromolecules: Absorption and Fluorescence Studies is clearly written and contains invaluable examples, coupled with illustrations that demonstrate a comprehensible analysis and presentation of the data. This book offers practical information on the fundamentals of absorption and fluorescence, showing that it is possible to interpret the same result in different ways. It is an asset to students, professors and researchers wishing to discover or use absorption and fluorescence spectroscopy, and to scientists working on the structure and dynamics of macromolecules.

* Offers concise information on the fundamentals of absorption and fluorescence
* Critically reviews examples taken from previously published literature
* Highly illustrated, it is suitable for academic and institutional libraries and government laboratories

Table of contents:

  1. Light Absorption by a Molecule
  2. Jablonski Diagram or Diagram of Electronic Transitions
  3. Singlet and Triplet States
  4. Forbidden and Non Forbidden Transitions
  5. Reading the Jablonski Diagram
  6. Chemical Bonds
  7. Atomic and Molecular Orbitals
  8. The Coordinated Bond
  9. Absorption Spectroscopy
  10. Origin and Properties of the Absorption Spectra
  11. Beer-Lambert-Bouguer Law
  12. Determination of the Molar Extinction Coefficient of Proteins
  13. Effect of High Optical Densities on the Beer-Lambert-Bouguer Law
  14. Effect of the Environment on the Absorption Spectra
  15. Absorption Spectroscopy and Electron Transfer Mechanism in Proteins
  16. Second – Derivative Absorption Spectroscopy
  17. Theory
  18. Binding of Progesterone to Alpha1-Acid Glycoprotein
  19. Fluorescence: Principles and Observables
  20. Introduction
  21. Fluorescence Properties
  22. Stokes Shift
  23. Relation between Emission Spectrum and Excitation Wavelength
  24. Relation between the Fluorescence Intensity and the Optical Density
  25. Fluorescence Excitation Spectrum
  26. The Mirror-Image Rule
  27. Fluorescence Lifetime
  28. Definition of the Fluorescence Lifetime
  29. Mean Fluorescence Lifetime
  30. Fluorescence Lifetime Measurement
  31. Time Correlated Single Photon Counting
  32. The Strobe Technique
  33. Excitation with Continuous Light: the Phase and Demodulation Method
  34. Principles
  35. Multifrequency and Cross-Correlation
  36. Fluorescence Quantum Yield
  37. Fluorescence and Light Diffusion
  38. Fluorophores: Descriptions and Properties
  39. Introduction
  40. Types of Fluorophores
  41. Intrinsic Fluorophores
  42. Aromatic Amino Acids
  43. The Co-factors
  44. Extrinsinc Fluorophores
  45. Fluorescein and Rhodamine
  46. Naphthalene Sulfonate
  47. Nucleic Bases
  48. Ions Detectors
  49. Carbohydrates Fluorescent Probes
  50. Oxidation of Tryptophan Residues with N-bromosuccinimide
  51. Nitration of Tyrosine Residues with Tetranitromethane (TNM)
  52. Effect of the Environment on the Fluorescence Observables
  53. Polarity Effect on the Quantum Yield and the Position of the Emission Maximum
  54. Effect of the Viscosity on the Fluorescence Emission Spectrum
  55. Effect of the Environment on the Fluorescence Lifetime
  56. Relation between Fluorescence and a Specific Sequence in a Protein
  57. Fluorescence Quenching
  58. Introduction
  59. Collisional Quenching : the Stern-Volmer Relation
  60. The Different Types of Dynamic Quenching
  61. Static Quenching
  62. Theory
  63. Cytochrome c – Cytochrome b2 Core Interaction
  64. Cytochrome b2 Core – Flavodehydrogenase Interaction
  65. Determination of Drug Binding to Alpha1 – Acid Glycoprotein
  66. Comparison between Dynamics and Static Quenching
  67. Combination of Dynamic and Static Quenching
  68. Thermal Intensity Quenching
  69. Photoquenching
  70. Fluorescence Polarization
  71. Aims and Definition
  72. Principles of Polarization or of Photoselection
  73. Absorption Transitions and Excitation Polarization Spectrum
  74. Fluorescence Depolarization
  75. Principles and Applications
  76. Measurements of Rotational Correlation Time of Tyrosine in Small Peptides
  77. Fluorescence Lifetime
  78. Fluorescence Intensity Quenching of Tyrosine Residues by Iodide
  79. Quenching Emission Anisotropy
  80. DNA-Protein Interaction
  81. Fluorescence Anisotropy Decay Time
  82. Depolarization and Energy Transfer
  83. Forster Energy Transfer
  84. Principles
  85. Energy Transfer Parameters
  86. Relation between Energy Transfer and Static Quenching
  87. Origin of Proteins Fluorescence
  88. Description of the Structure and Dynamics of Alpha1-Acid Glycoprotein by Fluorescence Studies
  89. Introduction
  90. Methods
  91. Fluorescence Properties of TNS Bound to Sialylated Alpha1-Acid Glycoprotein
  92. Binding Parameters
  93. Fluorescence Lifetime
  94. Dynamics of TNS Bound to Alpha1-Acid Glycoprotein
  95. Fluorescence Properties of Calcofluor Bound to Alpha-Acid Glycoprotein
  96. Fluorescence Parameters of Calcofluor Bound to Alpha1-Acid Glycoprotein
  97. Binding Parameters
  98. Nature of the Interaction of Calcofluor with Alpha1 -Acid Glycoprotein and HSA
  99. Titration of Carbohydrate Residues with Calcofluor
  100. Fluorescence Lifetime of Calcofluor Bound to Alpha1-Acid Glycoprotein
  101. Binding Parameters of Calcofluor White – Alpha1-Acid Glycoprotein by following the Fluorescence Life
  102. Dynamics of Calcofluor Bound to Alpha1-Acid Glycoprotein at Equimolar Concentrations
  103. Dynamics of Calcofluor Bound to Sialylated Alpha1-Acid Glycoprotein
  104. Dynamics of Calcofluor Bound to Asialylated Alpha1 – Acid Glycoprotein
  105. Dynamics of Calcofluor Bound to Alpha1-Acid Glycoprotein at Excess Concentration of Calcofluor
  106. Fluorescence Properties of the Trp Residues in Alpha1-Acid Glycoprotein
  107. Fluorescence Spectral Properties
  108. Effect of High Calcofluor Concentration on the Local Structure of Alpha1-Acid Glycoprotein
  109. Deconvolution of the Emission Spectra Obtained at Low and High Concentrations of Calcofluor into Dif
  110. Analysis as a Sum of Gaussian Bands
  111. The Ln-Normal Analysis
  112. Forster Energy Transfer Experiments from Trp Residues to Calcofluor White
  113. Relation between the Secondary Structure of Carbohydrate Residues of Alpha1-Acid Glycoprotein and th
  114. Effect of the Secondary Structure of Carbohydrate Residues of Alpha1-Acid Glycoprotein on the Local
  115. Fluorescence Emission Intensity of Alpha1-Acid Glycoprotein as a Function of Temperature
  116. Fluorescence Emission Anisotropy of Alpha1-Acid Glycoprotein as a Function of Temperature
  117. Tertiary Structure of Alpha1-Acid Glycoprotein : First Model Describing the Presence of a Pocket
  118. Are there any other Alternative Fluorescence Methods other than the QREA or the Weber’s Method to Pu
  119. Experiments giving Proofs of the Presence of a Pocket within Alpha1-Acid Glycoprotein
  120. Binding of Progesterone to Alpha1-Acid Glycoprotein
  121. Binding of Hemin to Alpha1- Acid Glycoprotein
  122. Homology Modeling of Alpha1- Acid Glycoprotein
  123. Dynamics of Trp Residues in Crystals of Human Alpha1- Acid Glycoprotein
  124. Introduction
  125. Protein Preparation
  126. Fluorescence Excitation and Emission Spectra
  127. Dynamics of the Microenvironments of the Hydrophobic Trp Residues
  128. Structural Studies of Human Alpha1-Acid Glycoprotein followed by X-Rays Scattering and Transmission
  129. Small Angle Diffraction Studies (SAXS)
  130. Wide Angle Diffraction Studies (WAXS)
  131. Carbohydrate Residues Studies
  132. Electron Microscopy Studies
  133. Structure and Dynamics of Hemoglobin Subunits and of Myoglobin
  134. Introduction
  135. Dynamics of Trp Residues in Hemoglobin and in its Subunits
  136. Properties of Protoporphyrin IX in Different Solvents and in Apomyoglobin
  137. Chemical Structure of Porphyrins
  138. Spectral Properties of Protoporphyrin IX in Different Solvents
  139. Spectral Properties of Protoporphyrin IX Bound to Apomyoglobin (MbdesFe)
  140. Dynamics of Protoporphyrin IX Embedded in the Heme Pocket
  141. Protein Rotational Correlation Time
  142. Activation Energy of the Porphyrin Motions in the Heme-Pocket
  143. Residual Internal Motions of Porphyrin
  144. Effect of Metal on the Porphyrin Dynamics
  145. Dynamics of the Protein Matrix and the Heme Pocket
  146. Significance of the Upward Curvature
  147. Effect of Sucrose on the Bimolecular Diffusion Constant
  148. Fluorescence Fingerprints of Animal and Vegetal Species and/or Varieties
  149. Fluorescence Fingerprints of Eisenia Fetida and Eisenia Andrei
  150. Introduction
  151. Results
  152. Structural Characterization of Varieties of Crops among a Species and of Genetically Modified Organi
  153. Pioneering Work of Zandomeneghi
  154. Structural Characterization of Crops

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Tags: Albani, Structure, Dynamics, Macromolecules, Absorption