Your search keyword '"van IJzendoorn, L.J."' showing total 4 results

1. Molecular interference in antibody–antigen interaction studied with magnetic force immunoassay.

Author

Dorokhin, D., van IJzendoorn, L.J., de Jong, A.M., Nieto, L., Brunsveld, L., Orsel, J.G., and Prins, M.W.J.

Subjects

*ANTIGEN-antibody reactions, *MAGNETISM, *IMMUNOASSAY, *MAGNETIC particles, *SURFACE active agents, *MOLECULAR probes, *PROTEIN-protein interactions

Abstract

Molecular interferences are an important challenge in biotechnologies based on antibody–antigen interactions, such as sandwich immunoassays. We report how a sandwich immunoassay with magnetic particles as label can be used to probe interference by surfactants. Surfactants are often used to improve the performance of immunoassays, however the surfactants can affect the involved proteins and the mechanism of action of surfactant molecules on the antibody–antigen system is mostly unknown. As an example, we investigated molecular interference by a nonionic surfactant (Pluronic F-127) in a cardiac troponin (cTn) sandwich immunoassay with two monoclonal antibodies. The influence of the surfactant below the critical micelle concentration (0.00–0.04%) on dissociation properties was quantified in a magnetic tweezers setup, where a force is applied to the molecules via magnetic particle labels. The force-dependent dissociation curves revealed the existence of two distinct cTn-dependent bond types, namely a weak bond attributable to non-specific binding of cTn, and a strong bond attributable to the specific binding of cTn. The dissociation rate constant of the strong bonds increased with the surfactant concentration by about a factor of two. Circular dichroism spectroscopy data showed that the nonionic surfactant influences the conformation of cTn while not noticeably affecting the two monoclonal antibodies. This suggests that the surfactant-induced increase of the dissociation rate of the specific sandwich-type cTn binding may be related to a conformational change of the antigen molecule. The described methodology is an effective tool to study the influence of surfactants and other interferences on assays based on protein interactions. [ABSTRACT FROM AUTHOR]

Published

2015

2. Editorial.

Author

van IJzendoorn, L.J.

Subjects

*POINT-of-care testing, *COST effectiveness, *NANOTECHNOLOGY, *WESTERN society, *IN vitro studies, *MEDICAL care, *MAGNETIC particles, *BIOLOGICAL assay

Published

2015

3. The rotating particles probe: A new technique to measure interactions between particles and a substrate

Author

Janssen, X.J.A., van Reenen, A., van IJzendoorn, L.J., de Jong, A.M., and Prins, M.W.J.

Subjects

*SURFACES (Technology), *STREPTAVIDIN, *PARTICLES, *ELECTROSTATICS, *MAGNETIC materials, *ALBUMINS, *METALLIC glasses, *CHEMICAL processes

Abstract

Abstract: We demonstrate a new probing technique to measure physicochemical interactions between particles and a substrate in a fluid. The technique is based on the measurement of field-induced rotation of individual magnetic particles in contact with the substrate. The parallel measurement of many particles with single-particle resolution gives reliable statistics in a short time. Using this technique, the interaction between streptavidin-coated magnetic particles and a glass substrate is measured for various buffer conditions. Increased binding is quantified for increasing ionic strength and decreasing pH. The results are found to be in agreement with calculations of electrostatic interactions. We also apply the technique to study how binding is reduced by blocking the substrate with albumin. [ABSTRACT FROM AUTHOR]

Published

2011

4. Ara h 1 protein–antibody dissociation study: evidence for binding inhomogeneities on a molecular scale.

Author

Pérez-Ruiz, E., Spasic, D., Gils, A., van IJzendoorn, L.J., Prins, M.W.J., and Lammertyn, J.

Subjects

*MOLECULAR interactions, *BIOSENSORS, *MACHINE design, *MOLECULAR shapes, *RECEPTOR-ligand complexes, *MONOCLONAL antibodies, *MAGNETIC particles, *CHEMICAL reactions, *PHYSISORPTION

Abstract

The characterization of biomolecular interactions is essential when designing novel biosensors, since the interaction between the bioreceptor and the ligand determines important biosensing parameters such as sensitivity and selectivity. In this paper we study the interaction of the trimeric Ara h 1 protein with a monoclonal anti-Ara h 1 antibody by means of magnetic force-induced dissociation. The proteins were bound to magnetic particles and polystyrene surfaces by EDC/NHS reaction chemistry and by physisorption, respectively. Two different molecular configurations have been investigated, with either the Ara h 1 protein on the particles or the Ara h 1 protein on the polystyrene surface. A model with a Gaussian distribution of energy barriers for dissociation gives an adequate description for the measured multi-exponential decays. We hypothesize that distributions of molecular orientations as well as experimentally induced variations may underlay the observed distributions. The two molecular configurations show a different peak value of the energy distribution. Similarly, SPR experiments for two distinct configurations (either Ara h 1 protein on the surface, or anti-Ara h 1 antibody on the surface) also show clear differences in dissociation behavior. We hypothesize that the multivalency of the involved molecules leads to different modes of binding. The results of this work highlight the importance of molecular inhomogeneities when studying the interaction processes of biomolecular complexes. [ABSTRACT FROM AUTHOR]

Published

2015