Influence of Different Parameters on a Dual-Fractal Analysis for Antigen–Antibody Binding Kinetics for Biosensor Applications

“…An analysis of the binding kinetics of the antigen in solution to antibody immobilized on the biosensor surface is available (39). The influence of lateral interactions on the surface and variable rate coefficients is also available (32).…”

“…These investigators noted that for an increasing binding rate coefficient, after a brief time interval, as time increases, the concentration of the antigen near the surface decreases, as expected for the cases when lateral interactions are present or absent. The diffusion-limited binding kinetics of antigen (or antibody or substrate) in solution to antibody (or antigen or enzyme) immobilized on a biosensor surface has been analyzed within a fractal framework (38,39). Furthermore, experimental data presented for the binding of human immunodeficiency virus (HIV) (antigen) to the antibody anti-HIV immobilized on a surface show a characteristic ordered "disorder" (42).…”

“…These authors noted that the prefactor (in our case, the binding or the dissociation rate coefficient) displays uniform trends with the fractal dimension, D f . Fractal dimension values for the kinetics of antigen-antibody binding (38,39), analytereceptor binding (34), and analyte-receptor binding and dissociation (6,27) are available. We would like to further extend these ideas now to two cases: binding and dissociation phase(s), and the dissociation phase alone as well.…”

A Kinetic Study of Analyte–Receptor Binding and Dissociation, and Dissociation Alone, for Biosensor Applications: A Fractal Analysis

“…An analysis of the binding kinetics of the antigen in solution to antibody immobilized on the biosensor surface is available (39). The influence of lateral interactions on the surface and variable rate coefficients is also available (32).…”

“…These investigators noted that for an increasing binding rate coefficient, after a brief time interval, as time increases, the concentration of the antigen near the surface decreases, as expected for the cases when lateral interactions are present or absent. The diffusion-limited binding kinetics of antigen (or antibody or substrate) in solution to antibody (or antigen or enzyme) immobilized on a biosensor surface has been analyzed within a fractal framework (38,39). Furthermore, experimental data presented for the binding of human immunodeficiency virus (HIV) (antigen) to the antibody anti-HIV immobilized on a surface show a characteristic ordered "disorder" (42).…”

“…These authors noted that the prefactor (in our case, the binding or the dissociation rate coefficient) displays uniform trends with the fractal dimension, D f . Fractal dimension values for the kinetics of antigen-antibody binding (38,39), analytereceptor binding (34), and analyte-receptor binding and dissociation (6,27) are available. We would like to further extend these ideas now to two cases: binding and dissociation phase(s), and the dissociation phase alone as well.…”

A Kinetic Study of Analyte–Receptor Binding and Dissociation, and Dissociation Alone, for Biosensor Applications: A Fractal Analysis

“…An analysis of the binding kinetics of the antigen in solution to antibody immobilized on the biosensor surface is available (37). The influence of lateral interactions on the surface and variable rate coefficients is also available (40).…”

“…Fractal dimension values for the kinetics of antigen-antibody binding (36,37) and analyte-receptor binding (38) are available. A fractal analysis of analyte-receptor binding kinetics for SPR applications is available (39).…”

A Predictive Approach Using Fractal Analysis for Analyte–Receptor Binding and Dissociation Kinetics for Surface Plasmon Resonance Biosensor Applications

Interferometric silicon biochips for label and label‐free DNA and protein microarrays