A hybrid poly(dimethylsiloxane) microsystem for on-chip whole blood filtration optimized for steroid screening.

Miniaturized biochemical devices in glass, silicon and polymer materials are starting to find their way from the academic laboratories to real-life applications. However, most attention has been given to miniaturize the downstream functions of various microfluidic systems, leaving the sample introduction and preparation steps to more conventional, bulkier solutions. For point-of-care diagnostics in particular, it becomes crucial to be able to handle complex human samples in a miniaturized format.In this work, we report on a microsystem for on-chip sample preparation that is able to remove blood cells from whole blood. The hybrid system consists of a commercially available membrane filter incorporated into a poly(dimethylsiloxane) (PDMS) casted device. Membrane materials were evaluated on the bases of low nonspecific adsorption of free and protein-bound testosterone as analyte substance. The hybrid system including a hydrophilic polypropylene filter successfully removed blood cells from diluted human whole blood. Surface oxidation was sufficient to make the plasma filtrate flow through the membrane filter and the channel system by capillary force alone and thus no external pumping source was needed.

Gold-coated fused-silica sheathless electrospray emitters based on vapor-deposited titanium adhesion layers.

Gold-coated fused-silica electrospray (ES) emitters based on vapor-deposited adhesion layers of titanium have been manufactured to investigate the possibilities of producing durable ES emitters applicable in chip-based analytical devices. The stabilities of the emitters were studied by both electrospray and electrochemical experiments and a marked increase in the emitter lifetime, compared to that for Cr/Au coated emitters, was found for the Ti/Au emitters in the ES durability tests. This indicates that Ti (rather than Cr) adhesion layers should be used in association with large-scale fabrication of ES emitters by vapor-deposition techniques. The lifetime of about 500-700 hours also allowed the Ti/Au-coated emitter to be used as an integrated part of a capillary liquid chromatography column coupled to a mass spectrometer in a series of LC/MS experiments. The Ti/Au coating was further studied by electrochemical techniques and scanning electron microscopy in conjunction with X-ray spectroscopy. It is shown that the eventual failure of the Ti/Au emitters in ES experiments was due to an almost complete detachment of the gold layer. Experimental evidence suggests that the detachment of the gold coating was due to a reduced adhesion to the titanium layer during oxidation in positive electrospray. Most likely, this was caused by the formation of an oxide layer on the titanium film. It is thus shown that unlimited emitter stabilities are not automatically obtained even if the metallic adhesion layer is stabilized by an oxide formation under positive electrospray conditions.

A comparison of the electrochemical stabilities of metal, polymer and graphite coated nanospray emitters.

Chronoamperometry (CA) and cyclic voltammetry (CV) were used to compare the electrochemical behavior of metal, polymer and graphite coated nanospray emitters. It is shown that electrochemical reactions occurring at the emitter surface limit the lifetime of the noble metal coated nanospray emitters while the graphite coated nanospray emitters show good electrochemical stabilities. Although the surface of the graphite coated emitters may be passivated at positive potentials, the conductive coating is not lost as for the noble metal coated nanospray emitters. The graphite coated nanospray emitters still produced a stable nanospray signal despite the presence of a passivated surface. The polymer (i.e. polyaniline) coated nanospray emitters showed very low electrochemical activity and could not be thoroughly tested by CA. The relative short lifetimes seen in the electrochemical tests are qualitatively comparable with those obtained in nanospray experiments, in which only the outmost tip of the emitter is electrochemically active. However, the electrochemical stress during CA far exceeds the stress during ESI, which implies that CA can be used to perform quick and simple estimates of emitter stabilities. To our knowledge, this is the first time the electrochemical behavior of metal, polymer and graphite coated nanospray emitters has been compared.

On-column polymer-imbedded graphite inlet electrode for capillary electrophoresis coupled on-line with flow injection analysis in a poly(dimethylsiloxane) interface.

A method for coupling an electrophoretic driven separation to a liquid flow, using conventional fused-silica capillaries and a soft polymeric interface is presented. A novel design of the electrode providing high voltage to the electrophoretic separation was also developed. The electrode consisted of a conductive polyimide/graphite imbedded coating immobilized onto the capillary electrophoresis (CE) column inlet. This integrated electrode gave the same separation performance as a commonly used platinum electrode. The on-column electrode also showed good electrochemical stability in chronoamperometric experiments. In addition, with this electrode design, the electrode position relative to the inlet end of the CE column will always be constant and well defined. The on-line flow injection analysis (FIA)-CE system was used with electrospray ionization (ESI)-time of flight (TOF)-mass spectrometry detection. The preparation of the PDMS (poly(dimethylsiloxane)) interface for FIA-CE is described in detail and used for initial tests of the on-column polymer-imbedded graphite inlet electrode. In this interface, a pressure-driven liquid flow, a make up CE electrolyte and a CE column inlet meet in a two-level cross (95 microm ID) in the PDMS structure, enabling independent flow characterization.

Separation high voltage field driven on-chip amperometric detection in capillary electrophoresis.

A new potentiostatless detection scheme for amperometric detection in capillary electrophoresis is presented based on the use of microband array electrodes positioned in the capillary electrophoresis electric field. In the present study, the spatial potential difference in the CE separation high-voltage field was measured using two gold microband electrodes positioned in the proximity of the capillary outlet. The induced potential difference between the two electrodes was recorded as a function of the applied separation high voltage and the dependence of the electrochemically generated current on the high-voltage field, and the concentration of a redox couple (Fe(CN)6(4-)/Fe(CN)6(3-)) was investigated. The results show that plots of the generated current versus the CE separation voltage have the same shape as cyclic voltammograms obtained with the same electrodes in a traditional potentiostatic setup and that the current is proportional to the concentration of the redox couple. As a decoupling device is not needed, the described potentiostatless approach significantly simplifies the instrumental setup for amperometric detection. This approach consequently holds great promise for application in inexpensive portable chip-based CE devices.

Deviceless decoupled electrochemical detection of catecholamines in capillary electrophoresis using gold microband array electrodes.

Samples containing microM concentrations of dopamine, (+/-)-isoproterenol, para-aminophenol and chlorogenic acid have been separated by capillary electrophoresis (CE) and detected using end-column amperometric detection based on a novel decoupling method. The present decoupling approach involves the use of an electrochemical detector chip containing an array of microband electrodes where the working and reference electrodes are positioned only 10 microm from each other. The short distance between the working and reference electrodes ensures that both electrodes are very similarly affected by the presence of the CE electric field. With this method, no shift in the detection potential was seen when the CE high voltage was applied. This eliminated the need for a reoptimization of the detection potential to compensate for the influence of the separation voltage on the detection. It is also demonstrated that catecholamines can be detected using gold microband electrodes by careful adjustment of the detection potential to avoid the formation of gold oxide. Such careful adjustments of the detection potential are straightforward using the present decoupling method.