Lasse Välimaa

Detection of HLA-B27 alleles by group-specific amplification and time-resolved fluorometry

This newly developed HLA-B27 assay combines a polymerase chain reaction (PCR) from blood spot samples with solution hybridisation in microtitration plate and with time-resolved fluorometry (TRF) as the detection system. In a multiplex amplification reaction, the 144 base pair region of HLA-B27 alleles is amplified with allele-specific primers simultaneously with the region of beta-actin gene as an internal control. Amplified products are collected onto streptavidin (SA)-coated microtitration wells, denatured and hybridised with a europium (Eu)-labelled HLA-B27 specific probe and a samarium (Sm)-labelled beta-actin specific probe. Finally, Eu and Sm fluorescence is enhanced and detected in a time-resolved fluorometer. The typing results obtained with 110 blood spot samples showed an exact match with serological class I HLA-typing. When this technique was further evaluated, 348 blood spot samples were clearly categorised into two populations, HLA-B27 positives and negatives. This new PCR-TRF method permits the automation of HLA-B27 assays and saves time and labour in routine diagnostics.

Improved surface stability and biotin binding properties of streptavidin coating on polystyrene.

The ultimate nature of streptavidin to bind biotin tightly is widely utilized in many solid-phase based applications to provide a universal binding surface for biotinylated molecules. However, the preparation of the streptavidin coatings by passive adsorption may heavily alter the binding properties of native streptavidin and may not result in the best possible capture surface for demanding solid-phase assays. By introducing sulphydryl groups through primary amines in the protein, we have activated and conjugated native streptavidin into larger protein polymers resulting in high local binding density when coated on polystyrene. This thiolated streptavidin formed through chemical modification has improved adsorption properties and biotin binding capability, compared to the native streptavidin. When this thiolated streptavidin is coated on polystyrene, a dense surface is formed, which provides up to 3-fold increase in the biotin binding efficiency and improves the surface stability by minimizing the desorption of the adsorbed protein from the surface during incubation. Furthermore, this high-capacity surface is resistant to harsh chemical treatments, such as denaturing conditions or mild reducing conditions. The improved adsorption properties of the thiolated streptavidin allow the coating process to be performed with shorter incubation times (15min), still providing enhanced solid-phase properties, compared to a reference streptavidin surface.

The effects of laser welding on heterogeneous immunoassay performance in a microfluidic cartridge

Sealing of a microfluidic cartridge is a challenge, because the cartridge commonly contains heat-sensitive biomolecules that must also be protected from contamination. In addition, the objective is usually to obtain a sealing method suitable for mass production. Laser welding is a rapid technique that can be accomplished with low unit costs. Even though the technique has been widely adopted in industry, the literature on its use in microfluidic applications is not large. This paper is the first to report the effects of laser welding on the performance of the heterogeneous immunoassay in a polystyrene microfluidic cartridge in which biomolecules are immobilized into the reaction surface of the cartridge before sealing. The paper compares the immunoassay performance of microfluidic cartridges that are sealed either with an adhesive tape or by use of laser transmission welding. The model analyte used is thyroid stimulating hormone (TSH). The results show that the concentration curves in the laser-welded cartridges are very close to the curves in the taped cartridges. This indicates, first, that laser welding does not cause any significant reduction in immunoassay performance, and second, that the polystyrene cover does not have significant effect on the signal levels. Interestingly, the coefficients of variance between parallel samples were lower in the laser-welded cartridges than in the taped cartridges.

Dried nanoparticle label reagents for microfluidic immunoassays

In this paper, we demonstrate and analyze the solubility and distribution of dried europium(III)-chelate dyed nanoparticles in mini channels of milled polystyrene (PS) cartridges. The particular objective for the study is to measure quantitatively the efficiency of the resuspension of dried nanoparticles from the surface of PS channels and to determine the homogeneity of the solute particles in a reaction chamber considering also the incubation time.

Automated modular bacterial filtering system with embeddable microfluidic chips

This paper introduces an automated bacterial filtering system which has three unique advantages comparing to current available systems. Firstly, it is an automatic system which minimizes the human interaction with potentially hazardous bacterial samples, eliminates human errors and makes it suitable for frequent bacterial filtering procedures. Secondly, it provides an interface between milliliter volumes of sample and microfluidic chips requiring samples in microliter volumes. Thirdly, both bacteria collected on the filter and filtrate passed through the filter can be collected for analysis. The modular design of the system provides a large variety of filters for different applications.