Biosensors: Kinetics of Binding and Dissociation Using Fractals

Other | December 1, 2003

bySadana, Ajit, Ajit Sadana

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This title brings to the attention of researchers in the industry, and in academia, the application of fractals to help in modeling the analyte/receptor binding and dissociation kinetics on biosensor surfaces.

The work builds on that done in Engineering Biosensors: Kinetics and Design Applications, published by Academic Press in 2002. In particular, more examples are provided of where biosensors may be effectively used. This sequel is extremely timely, given the anticipation that the applications and reliance on biosensors will increase due to the advances in miniaturization, (wireless) communications, and the development of new materials (especially biological and chemical). Other applications of biosensors on the increase can be found in: the protection of civilian structures and infrastructures; protection from possible biological and chemical threats; health care; energy; food safety; and the environment to name a few.

- Covers all areas of applications of biosensors
- No other book on biosensors describes the kinetics of binding
- Provides numerous examples of where biosensors may be used

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From the Publisher

This title brings to the attention of researchers in the industry, and in academia, the application of fractals to help in modeling the analyte/receptor binding and dissociation kinetics on biosensor surfaces.The work builds on that done in Engineering Biosensors: Kinetics and Design Applications, published by Academic Press in 2002. I...

Format:OtherDimensions:418 pages, 1 × 1 × 1 inPublished:December 1, 2003Publisher:Elsevier ScienceLanguage:English

The following ISBNs are associated with this title:

ISBN - 10:0080528139

ISBN - 13:9780080528137

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Table of Contents

Introduction
Influence of Reynolds Number on Fractal Binding Kinetics on a Surface-based Biosensor
DNA Fractal Binding and Dissociation Kinetics
Fractal Analysis of Binding and Dissociation Interactions of Estrogen Receptors to Ligands on Biosensor Surfaces
Fractal Analysis of Estrogen Receptor Binding and Dissociation Kinetics
Fractal Analysis of Analyte-Estrogen Receptor Binding and Dissociation
Fractal Analysis of Binding Interactions of Nuclear Estrogen Receptors Occurring On Biosensor Surfaces
Fractal Analysis of Cholera Toxin and Peptide-Protein Binding and Dissociation in Biosensors
The Temporal Nature of the Binding and Dissociation Rate Coefficients and the Affinity Values for Biosensor Kinetics
Fractal Analysis of Analyte-Receptor Binding and Dissociation, and Dissociation Alone for Biosensor Applications
Fractal Analysis of Cellular Analyte-Receptor Binding and Dissociation on Biosensors
Fractal Analysis of Analyte-Receptor Binding Kinetics on Microarrays
Fractal Analysis of Cre-loxP Interactions and the Influence of Cl, O, and'S on Drug/Liposome Interactions on Biosensors
Fractal Analysis of Binding and Dissociation Kinetics on Randomly Coupled and Oriented Coupled Receptors on Biosensor Surfaces: Electrostatic Effects
Fractal Analysis of Analyte-Receptor Binding and Dissociation on Biosensor Surfaces: Kinetics of Regeneration and Multiple Analyte Immunoassay (MAIA)
Fractal Analysis of Analyte-Receptor Binding and Dissociation Kinetics in Microcantilever Biosensors