Abstract A fractal analysis is presented for the binding of riboflavin binding protein (RBP) in solution to riboflavin (Rf) derivative immobilized on a sensor chip. The influence of complexation of RBP with Rf in solution on its binding kinetics to immobilized Rf is also analyzed. A better understanding of the kinetics provides physical insights into these interactions and complements the original work of [I. Caelen, A. Kalman, L. Wahlstrom, Anal. Chem. 76 (2004) 137]. These authors [I. Caelen, A. Kalman, L. Wahlstrom, Anal. Chem. 76 (2004) 137] used a surface plasmon resonance (SPR) biosensor where no kinetic binding rate coefficients were provided. Numerical values of the binding rate coefficient are presented and linked to the degree of heterogeneity made quantitative by the fractal dimension, Df, on the sensor chip surface. Both, single- and dual-fractal analysis are used to provide an adequate fit. The results presented here are consistent with the original work [I. Caelen, A. Kalman, L. Wahlstrom, Anal. Chem. 76 (2004) 137]. Predictive relations are presented for the binding rate coefficient, k, and for the fractal dimension, Df, as a function of the RBP concentration in solution. The binding rate coefficient, k, is very sensitive to the degree of heterogeneity that exists on the surface (order of dependence equal to 6.583). In general, the changes in the degree of heterogeneity (fractal dimension, Df) on the sensor chip surface and in the binding rate coefficient, k, are in the same direction. Both the fractal dimension, Df, and the binding rate coefficient, k, exhibit rather low orders of dependence equal to 0.087 and 0.576, respectively, on the RBP concentration in solution. At the lowest RBP concentration (0.1 μg/mL) in solution, a dual-fractal analysis is required to describe the binding kinetics, whereas in the 0.2–10.0 μg/mL RBP concentration range in solution a single-fractal analysis is adequate. This indicates that there is a change in the binding mechanism at the lowest RBP concentration in solution (0.1 μg/mL).
[1]
Sorensen,et al.
The Prefactor of Fractal Aggregates
,
1997,
Journal of colloid and interface science.
[2]
A. Sadana,et al.
A mathematical analysis using fractals for binding interactions of estrogen receptors to different ligands on biosensor surfaces
,
2003
.
[3]
Stephen J. Martin,et al.
Effect of surface roughness on the response of thickness-shear mode resonators in liquids
,
1993
.
[4]
A. Sadana,et al.
A fractal analysis of analyte-estrogen receptor binding and dissociation kinetics using biosensors: environmental and biomedical effects.
,
2003,
Bio Systems.
[5]
Andras Kalman,et al.
Biosensor-based determination of riboflavin in milk samples.
,
2004,
Analytical chemistry.
[6]
Shyi-Long Lee,et al.
Multifractal scaling analysis of reactions over fractal surfaces
,
1995
.
[7]
Ajit Sadana,et al.
A fractal analysis of analyte-estrogen receptor binding and dissociation kinetics using biosensors: environmental effects.
,
2003,
Journal of colloid and interface science.
[8]
P. Finglas,et al.
Determination of biotin and folate in infant formula and milk by optical biosensor-based immunoassay.
,
2000,
Journal of AOAC International.