Showing papers by "Richard B.M. Schasfoort published in 2009"

Integrated electrokinetic sample focusing and surface plasmon resonance imaging system for measuring biomolecular interactions.

Abstract: Label-free biomolecular binding measurement methods, such as surface plasmon resonance (SPR), are becoming increasingly more important for the estimation of real-time binding kinetics. Recent advances in surface plasmon resonance imaging (iSPR) are emerging for label-free microarray-based assay applications, where multiple biomolecular interactions can be measured simultaneously. However, conventional iSPR microarray systems rely on protein printing techniques for ligand immobilization to the gold imaging surface and external pumps for analyte transport. In this article, we present an integrated microfluidics and iSPR platform that uses only electrokinetic transport and guiding of ligands and analytes and, therefore, requires only electrical inputs for sample transport. An important advantage of this new approach, compared to conventional systems, is the ability to direct a single analyte to a specific ligand location in the microarray, which can facilitate analysis parallelization. Additionally, this simple approach does not require complicated microfluidic channel arrangements, external pumps, or valves. As a demonstration, kinetics and affinity have been extracted from measured binding responses of human IgG and goat antihuman IgG using a simple 1: 1 model and compared to responses measured with conventional pressure driven analyte transport. The measured results indicate similar binding kinetics and affinity between the electrokinetic and pressure-driven sample manipulation methods and no cross contamination to adjacent measurement locations has been observed.

Single injection microarray-based biosensor kinetics

Abstract: Binding affinity of biomolecular interactions can be directly extracted from measured surface plasmon resonance biosensor sensorgrams by fitting the data to the appropriate model equations. The conventional method for affinity estimation uses a series of analytes and buffers that are injected serially to a single immobilized ligand on the sensing surface, including a regeneration step between each injection, to generate information about the binding behavior. We present an alternative method to estimate the affinity using a single analyte concentration injected to multiple ligand densities in a microarray format. This parameter estimation method eliminates the need for multiple analyte injections and surface regeneration steps, which can be important for applications where there is limited analyte serum, fragile ligand-surface attachment, or the detection of multiple biomolecule interactions. The single analyte injection approach for binding affinity estimation has been demonstrated for two different interactant pairs, β2 microglobulin/anti-β2 microglobulin (β2M) and human IgG/Fab fragments of anti-human IgG (hIgG), where the ligands are printed in a microarray format. Quantitative comparisons between the estimated binding affinities measured with the conventional method are β2M: KD = 1.48 ± 0.28 nM and hIgG: KD = 12.6 ± 0.2 nM and for the single injection method are β2M: KD = 1.52 ± 0.22 nM and hIgG: KD = 12.5 ± 0.6 nM, which are in good agreement in both cases.