Chapter 1 Developing Process of Light Scattering Technique Analysis 1.1 Resonance Light Scattering Technique Used for Biochemical and Pharmaceutical Analysis 1.2 The Principles and Analytical Applications of Total Internal Reflected Resonance Light Scattering Technique 1.3 Recent Developments of the Resonance Light Scattering Technique: Technical Evolution, New Probes and Applications Chapter 2 Analytical Applications in DNA Detection of Light Scattering Technique 2.1 Determination of Nucleic Acids by a Resonance Light-scattering Technique with α,β,γ,δ-tetrakis [4-(trimethylammoniumyl)phenyl]Porphine 2.2 Hybridization Detection of DNA by Measuring Organic Small Molecule Amplified Resonance Light Scattering Signals 2.3 Determination of Nanograms of Nucleic Acids by their Enhancement Effect on the Resonance Light Scattering of the Cobalt(II)/4-[(5-chloro -2-pyridyl) azo]-1,3-diaminobenzene complex 2.4 Interactions of Janus Green B with Double Stranded DNA and the Determination of DNA Dased on the Measurement of Enhanced Resonance Light Scattering 2.5 A Sensitive and Selective Assay of Nucleic Acids by Measuring Enhanced Total Internal Reflected Resonance Light Scattering Signals Deriving from the Evanescent Field at the Water/Tetrachloromethane Interface 2.6 Backscattering Light Detection of Nucleic Acids with Tetraphenylporphyrin-Al(III)-Nucleic Acids at Liquid/Liquid Interface 2.7 Directly Light Scattering Imaging of the Aggregations of Biopolymer Bound Chromium(Ill) Hydrolytic Oligomers in Aqueous Phase and Liquid/Liquid Interface Chapter 3 Analytical Applications in Protein Detection of Light Scattering Technique 3.1 Determination of Protein Concentration by Enhancement of the Preresonance Light-scattering of α,β,γ,δ-tetrakis(5-sulfothienyl) Porphine 3.2 On the Factors Affecting the Enhanced Resonance Light Scattering Signals of the Interactions Between Proteins and Multiply Negatively Charged Chromophores Using Water Blue as an Example 3.3 Determination of Proteins with a;fl,),,rtetrakis(4-sulfophenyl) Porphine by Measuring the Enhanced Resonance Light Scattering at the Air/Liquid Interface 3.4 A Backscattering Light Detection Assembly for Sensitive Determination of Analyte Concentrated at the Liquid/Liquid Interface Using the Interaction of Quercetin with Proteins as the Model System 3.5 Flow-injection Resonance Light Scattering Detection of Proteins at the Nanogram Level 3.6 Resonance Light Scattering Imaging Detection of Proteins with α,β,γ,δ-tetrakis (p-sulfophenyl) Porphyrin Chapter 4 Analytical Applications in Organic Mieromolecles and Medicines Detection of Light Scattering Technique 4.1 Enhanced Plasmon Resonance Light Scattering Signals of Colloidal Gold Resulted from its Interactions with Organic Small Molecules Using Captopril as an Example 4.2 Total Internal Reflected Resonance Light Scattering Determination of Chlortetracycline in Body Fluid with the Complex Cation of Chlortetracycline-europium-trioctyl Phosphine Oxide at the water/tetrachloromethane interface 4.3 Novel Assay of Thiamine Based on its Enhancement of Total Internal Reflected Resonance Light Scattering Signals of Sodium Dodecylbenzene Sulfonate at the Water/Tetrachloromethane Interface 4.4 Adsorption of Penicillin-berberine Ion Associates at a Water/Tetrachloromethane Interface and Determination of Penicillin Based on Total Internal-reflected Resonance Light Scattering Measurements 4.5 Pharmacokinetic Detection of Penicillin Excreted in Urine using a Totally Internally Reflected Resonance Light Scattering Technique with Cetyltrimethylammonium Bromide 4.6 A Wide Dynamic Range Detection of Biopolymer Medicines with Resonance Light Scattering and Absorption Ratiometry 4.7 A resonance Light Scattering Ratiometry Applied for Binding Study of Organic Small Molecules with Biopolymer 4.8 A Light Scattering and Fluorescence Emission Coupled Ratiometry Using the Interaction of Functional. CdS Quantum Dots with Aminoglycoside Antibiotics as a Model System 4.9 Resonance Light Scattering Imaging Determination of Heparin 4.10 Visual Detection of Sudan Dyes Based on the Plasmon Resonance Light Scattering Signals of Silver Nanoparticles
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