Controlled electrophoretic deposition of multifunctional nanomodules for bioelectrochemical applications

The design of an electrochemical glucose sensing device formed by the electrodeposition of multifunctional Au nanoparticles is reported here as a novel concept for an enhanced generic sensing platform. Initially gold nanoparticles (Au) were alternatively coated with a layer of positively charged redox polymer (ORP) and a negatively charged glucose oxidase (GOX) layer alternatively using layer-by-layer methodology to form multifunctional Au/ORP/GOX/ORP particles. The modification and stability of the Au nanoparticles was monitored by using UV-vis spectroscopy and zeta-potential measurements. The modified Au nanoparticles were electrophoretically deposited onto an electrode to produce an electrochemical glucose sensing device. A considerable influence of electrophoretic deposition time and potential was found on the sensing platform response. Preliminary responses to glucose addition showed an enhanced performance by applying an electrophoretic deposition potential of +1.2V vs. Ag/AgCl for 30min. The observed response in the case of microelectrode geometry was in the range of mAcm(2). This work also shows that the presence of a second outer ORP layer on the functionalised Au nanoparticles improved the response.     

DNA biosensor based on hybridization refractory mutation system approach for single mismatch detection

We report on a simple approach to enhance solid-phase hybridization-based single base mismatch discrimination at high ionic strength based on the deliberate insertion of a natural DNA base mismatch in the surface-tethered probe. A large drop in hybridization signal of single base mismatched alleles using the designed probe as compared with the conventional probe, from 80% to less than 25% of the signal obtained with the fully complementary, non-mutation-containing sequence, when using colorimetric detection was further improved to 20% when using electrochemical detection, attributable to a difference of spacing of immobilized probes. Finally, the designed probe was used for the electrochemical detection of the DQA1*05:05 allele amplified from real human blood samples.     

Aptamers as elements of bioelectronic devices

A ferrocene labelled aptamer is used as a redox partner of co-immobilised microperoxidase demonstrating a reversible amperometric biomolecular device that could respond to external stimuli in real time.     

A multianalyte flow electrochemical cell: application to the simultaneous determination of carbohydrates based on bioelectrocatalytic detection

A multianalyte flow electrochemical cell (MAFEC) for bioanalysis is constructed, characterised and used for simultaneous carbohydrate analysis incorporating mediated amperometric enzyme electrodes. Although multidetection schemes can be addressed with microfabricated systems, it is demonstrated that a "meso" analytical device of low cost can give answers to traditional simultaneous multianalysis problems, being robust, and easy to construct and operate. The cell operates as a radial flow thin-layer device and can achieve mass transport controlled response for fast electrochemical reactions. When appropriate enzymatic electrodes are used the response becomes kinetically limited, but still shows a better than 5% R.S.D. for response to different sugars analysed. All the enzymatic sensors are mediated with different osmium compounds appropriate for each enzyme's mechanism (NAD or PQQ dehydrogenases) in some cases combining multienzyme sensors. All sensors were optimised so that different sugars do not produce interferences to other sensors. Matrix interferences were kept low by operating all sensors at or below 150 mV versus Ag/AgCl. The integrated system was used for the simultaneous detection of fructose, sucrose, glucose, galactose, and lactose, fully characterising the system for these analytes (sensitivity, dynamic range). Cross referenced calibration curves were used for signal treatment and interpretation and it was possible to analyse real juice and milk samples with results agreeing with the standard enzymatic methods for the same analyses with a sampling frequency of more than 100 h(-1).     

Extracellular location of a β-lactamase produced by Acinetobacter calcoaceticus

Summary Acinetobacter calcoaceticus strains 69 V and CCM 5593 formed a -lactamase that was predominantly found extracellularly in the culture medium. The enzyme has the characteristics of an inducible chromosomally mediated cephalosporinase. Neither cell lysis nor periplasmic leakage are responsible for the extracellular location. The mechanism of secretion is not known.Offprint requests to: P. Borneleit     

Amperometric immunosensor for the determination of IgA deficiency in human serum samples

An electrochemical immunosensor for the detection of human IgA deficiency in real human blood serum has been developed. The performance of the immunosensor presents a large but sensitive dynamic range that allows the determination of non-deficient IgA levels (>70 μg/mL) as well as of severe IgA deficiencies (0.5-5.0 μg/mL). The assay architecture involves the immobilisation of a coating antibody on an electrode surface using carboxylic-ended bipodal alkane-thiol self-assembled monolayers (SAMs). The long chain bipodal SAM presents intercalated poly(ethylenglycol) groups that confer the immunosensor the ability to retain its optimum performance in very complex matrices and serum with negligible non-specific adsorption phenomena. Amperometric optimisation of the assay resulted in limits of detection of 142 ng/mL in just 30 min total assay time. Real patients' serum samples were analysed using the developed electrochemical immunosensor demonstrating an excellent correlation in terms of sensitivity and reproducibility compared with standard enzyme linked immunosorbent assays (ELISA).     

Amperometric mediated carbon paste biosensor based on D-fructose dehydrogenase for the determination of fructose in food analysis

A new mediated amperometric biosensor for fructose is described. The sensor is based on a commercially available D-fructose dehydrogenase. The enzyme is incorporated in a carbon paste matrix containing Os(bpy)₂Cl₂ as redox mediator that achieves electron transfer at 0·1 V (versus Ag/AgCl) with maximum apparent current densities of 1·2 mA/cm². The dependence of the steady-state current on the loading of the mediator and the enzyme, other electrode construction parameters, the operating potential, the pH and the temperature was studied. In the steady-state mode the response current was directly proportional to D-fructose concentration from 0·2 to 20mM with a detection limit of 35 μM (signal-to-noise ratio, S/N, 3). In the flow injection analysis mode the response current was directly proportional to D-fructose concentration from 0·5 to 15 M with a detection limit of 115 μM (S/N 3). The sensor was used for the determination of fructose in food samples in a flow injection system and validated with a commercial enzyme kit.