Kristien Bonroy

Stability of mixed PEO-thiol SAMs for biosensing applications.

The secret of a successful affinity biosensor partially hides in the chemical interface layer between the transducer system and the biological receptor molecules. Over the past decade, several methodologies for the construction of such interface layers have been developed on the basis of the deposition of self-assembled monolayers (SAMs) of alkanethiols on gold. Moreover, mixed SAMs of polyethylene oxide (PEO) containing thiols have been applied for the immobilization of biological receptors. Despite the intense research in the field of thiol SAMs, relatively little is known about their biosensing properties in correlation with their long-term stability. Especially the impact of the storage conditions on their biosensing characteristics has not been reported before to our knowledge. To address these issues, we prepared mixed PEO SAMs and tested their stability and biosensing performance in several storage conditions, i.e., air, N2, ethanol, phosphate buffer, and H2O. The quality of the SAMs was monitored as a function of time using various characterization techniques such as cyclic voltammetry, contact angle, grazing angle Fourier-transform infrared spectroscopy, and X-ray photoelectron spectroscopy. In addition, the impact of the different storage conditions on the biosensor properties was investigated using surface plasmon resonance. Via the latter technique, the receptor immobilization, the analyte recognition, and the nonspecific binding were extensively studied using the prostate specific antigen as a model system. Our experiments showed that very small structural differences in the SAM can have a great impact in their final biosensing properties. In addition it was shown that the mixed SAMs stored in air or N2 are very stable and retain their biosensor properties for at least 30 days, while ethanol appeared to be the worst storage medium due to partial oxidation of the thiol headgroup. In conclusion, care must be taken to avoid SAM degradation during storage to retain typical SAM characteristics, which is very important for their general use in many proposed applications.

Nanopatterning of gold colloids for label-free biosensing

We present an approach for the controlled positioning of single gold colloids onto dot and line nanoarrays which have the potential to serve as label-free biosensor platforms. The separation between the high-resolution nanolithography step, extreme ultraviolet interference lithography, and the subsequent functionalization has many advantages, among them the independence of the linkage chemistry. The activation of the pre-patterned substrates is performed by transforming them into a surface of biotinylated nanopatches in a protein-resistant background. Complexes of streptavidin and single-stranded DNAs can then be selectively immobilized onto the biotinylated patches, which are embedded in an inert background. This approach enables the creation of single gold colloid dot and line arrays by directed self-assembly using the specificity of DNA hybridization.

A label-free potentiometric sensor principle for the detection of antibody-antigen interactions.

We report here on a new potentiometric biosensing principle for the detection of antibody-antigen interactions at the sensing membrane surface without the need to add a label or a reporter ion to the sample solution. This is accomplished by establishing a steady-state outward flux of a marker ion from the membrane into the contacting solution. The immunobinding event at the sensing surface retards the marker ion, which results in its accumulation at the membrane surface and hence in a potential response. The ion-selective membranes were surface-modified with an antibody against respiratory syncytial virus using click chemistry between biotin molecules functionalized with a triple bond and an azide group on the modified poly (vinyl chloride) group of the membrane. The bioassay sensor was then built up with streptavidin and subsequent biotinylated antibody. A quaternary ammonium ion served as the marker ion. The observed potential was found to be modulated by the presence of respiratory syncytial virus bound on the membrane surface. The sensing architecture was confirmed with quartz crystal microbalance studies, and stir effects confirmed the kinetic nature of the marker release from the membrane. The sensitivity of the model sensor was compared to that of a commercially available point-of-care test, with promising results.

Increased stability of mercapto alkane functionalized Au nanoparticles towards DNA sensing

The use of gold nanoparticles (GNPs) in bioassays is often hampered by their colloidal stability. In this study, gold nanoparticles coated with different mercapto alkanes were investigated towards their stability. Hereto, the effects of the alkane chain length (5-11 methylene groups), the type of functional end-group (-OH or -COOH) and the amount of incorporated poly-ethylene oxide units (none, 3 or 6) on the GNP stabilization was evaluated. Based on these results, an optimal mercapto alkane (HS(CH(2))(11)PEO(6)COOH) was selected to increase the colloidal stability up to 2 M NaCl. Furthermore, it was proved that this mercapto alkane is ideally suited to enhance the stability of DNA functionalized GNPs in high electrolytic hybridization buffers. The effectiveness of these DNA functionalized GNPs was demonstrated in a sandwich assay using a surface plasmon resonance biosensor. The superior stability of these nanoparticles during hybridization may lead to enhanced biosensor technologies.

Penicillin-specific antibodies: Monoclonals versus polyclonals in ELISA and in an optical biosensor

Abstract Two penicillin-specific monoclonal antibodies mAb 19C9 and mAb 9H3 and the penicillin-specific polyclonal antibodies pAb K2 were evaluated for their use in a competitive ELISA and in the BIAcore™ optical biosensor. In the ELISA, an ampicillin-protein conjugate was used as a coating molecule. For the biosensor assay, ampicillin was immobilized on a CM5 chip. With both monoclonal antibodies and in both test systems, ampicillin, amoxicillin and benzylpenicillin were better recognized than oxacillin, cloxacillin and dicloxacillin. Because the reproducibility was better in the biosensor (CV = 1.6%) than in the ELISA (CV = 8.9%), the limit of detection for ampicillin in buffer solution using mAb 19C9 was lower in the biosensor (46 ng ml−1) as compared to the ELISA (356 ng ml−1). Ampicillin can thus be detected below the MRL (50 ng ml−1) in the biosensor assay but not in the ELISA. Both the ELISA and biosensor assay using the polyclonal antibodies pAb K2 were more sensitive as compared to the assays with the monoclonals. The ELISA using pAb K2 allowed the detection of all tested penicillins below the MRL. In the biosensor assay, ampicillin was also detected below the MRL (IC50 = 10 ng ml−1). In contrast to the binding of the monoclonals, no spontaneous dissociation was observed after injection of the polyclonal antibodies in the biosensor. Whereas the monoclonals were completely removed from the sensor surface using ampicillin in the buffer solution as regeneration solution, stronger conditions were necessary for the pAb binding.

Development of microelectronic based biosensors

Biosensors offer the opportunity to sense the biological world providing valuable information for medical diagnostics, analytical chemistry, environmental monitoring and fundamental research. Convergence of engineered (bio)chemical surfaces with micro- and nano- systems promises tremendous advances and potential cost reductions in biotechnology. This paper introduces some key challenges facing biosensor development, focussing on opportunities that arise from microsystem platforms utilising novel materials and processes. Examples from our work are presented illustrating the implementation of acoustic wave sensors and novel FET-type sensors.

Surface Chemistry to Bridge Inorganic Biosensor Surfaces and Biological Materials

The increasing miniaturization of biochips based on microelectronics and the demand for higher biosensor sensitivities and specificities put severe demands on the process and methodology of coupling biomolecules to surfaces. More specifically, controlled thin film structures have to be created which allow the bio-affinity elements to be arranged and addressed in a reproducible and controlled manner. In this chapter, we describe how to create functional oxide and gold surfaces using Self-Assembled Monolayers (SAMs) and how they can be applied to construct immunosensor interfaces. Furthermore, we report on the direct self-assembly of low-molecular weight compounds and single stranded DNA onto gold surfaces. We conclude that immobilization approaches inspired by self-assembly are extremely versatile and are of the utmost importance for the development of highly sensitive and specific biosensors.