Electrochemical Detection of dsDNA-Specific Antibodies.

Electrochemical biosensors have shown great promise as useful point-of-care tests since they operate on electronic circuits which can be miniaturized and whose readout process can be easily automated. Here, we describe a method for the electrochemical sensing of antibodies directed against double-stranded DNA (α-dsDNA), which are often present at higher-than-normal levels in the sera of autoimmune disease patients. The method can be easily implemented in any lab and requires little investment in equipment, namely a potentiostat. An artificial reference serum sample containing known amounts of spiked-in α-dsDNA antibodies enables reporting results in absolute scale rather than titer. Once electrodes are modified with DNA and the calibration curves are made (i.e., after the biosensor construction phase), individual measurements in test samples can be obtained in as low as 35 min.

An electrochemical biosensor for rapid detection of anti-dsDNA antibodies in absolute scale.

Autoimmune diseases are chronic inflammatory pathologies that are characterized by the presence of antibodies against the body's own epitopes in serum (autoantibodies). Systemic lupus erythematosus (SLE) is a common autoimmune pathology characterized by the presence of antinuclear antibodies (ANAs). These include anti-dsDNA (α-dsDNA) antibodies, which are widely used for diagnosis and disease monitoring. Their determination is carried out using traditional techniques such as Indirect Immunofluorescence (IFI) or Enzyme-Linked Immunosorbent Assay (ELISA), which are time consuming, require qualified technicians, and are not compatible with decentralized analysis outside a laboratory facility. Here, we show a sandwich-format electrochemical biosensor-based method for α-dsDNA determination in a rapid and simple manner. The total assay time is only 30 minutes, and the sensor is capable of detecting 16 ng (8 µg mL-1) of α-dsDNA antibodies. Using the current derived from the detection limit of the method as a cut-off, we could discriminate positive from negative serum samples with 90% sensitivity and 100% specificity. Using monoclonal antibodies for calibration curves, our results are presented in absolute scale (i.e., concentration instead of serum titer) which will help us to perform comparisons between methods and carry out further improvements of this protocol. In an effort to render the sensor compatible with automation, we minimized the manipulation steps without compromising the analytical performance, even in complex samples such as serum.

Electrochemical Sandwich Immunosensor for Determination of Exosomes Based on Surface Marker-Mediated Signal Amplification.

Extracellular vesicles (EVs), namely, exosomes and microvesicles, are important mediators of intercellular communication pathways. Since EVs can be detected in a variety of biofluids and contain a specific set of biomarkers which are reminiscent of their parental cells, they show great promise in clinical diagnostics as EV analysis can be performed in minimally invasive liquid biopsies. However, reliable, fast and cost-effective methods for their determination are still needed, especially if decentralized analysis is intended. In this study, we developed an electrochemical biosensor which works with 1.5 µL sample volume and can detect as low as 200 exosomes per microliter, with a linear range spanning almost 4 orders of magnitude. The sensor is specific and readily differentiates exosomes from microvesicles in samples containing 1000-fold excess of the latter. Capability of detecting exosomes in real samples (diluted serum) was shown. This was achieved by immobilizing rabbit antihuman CD9 antibodies on gold substrates and using monoclonal antibodies against CD9 for detection of captured exosomes. Signal amplification is presumably obtained from the fact that multiple detector antibodies bind to the surface of each captured vesicle. Detection is performed based on electrochemical reduction of 3,3',5,5'-tetramethyl benzidine (TMB) after addition of horseradish peroxidase (HRP)-conjugated anti-IgG antibodies. This amperometric biosensor can be easily incorporated into future miniaturized and semiautomatic devices for EV determination.

Template and catalytic effects of DNA in the construction of polypyrrole/DNA composite macro and microelectrodes.

Electrochemical DNA hybridization-based sensors show great promise as portable and automated analytical devices for routine screening of pathogenic or foreign nucleic acid sequences in biological samples. However, current sensor technologies still exhibit some unresolved issues which hampers their direct application into everyday life. Conducting polymers, such as polypyrrole (PPy), are increasingly being adopted as suitable platforms for DNA probe immobilization and signal transduction. Immobilization of DNA probes during pyrrole electropolymerization is a simple and efficient strategy to build composite electrodes suitable for DNA sensing. However, the effects of the probe state and sequence on PPy growth kinetics have not been studied yet. Here, we show that growth of PPy is drastically affected by the presence of guanine in the DNA probes and whether DNA is present in its single-stranded or double-stranded form. We show that some immobilization protocols may provoke irreversible oxidation of guanine moieties in the probe and that this issue deserves careful investigation as it may interfere with hybridization processes. We have also explored new procedures to build microelectrode arrays bearing immobilized DNA molecules, which are known to show beneficial properties in stirred samples. Overall, we present new techniques and concerns regarding the development of DNA-containing PPy-based composite electrodes, which may be taken into consideration for increasing genosensor reproducibility, response and performance.

Two independent label-free detection methods in one electrochemical DNA sensor.

Two direct reagent-free detection methods were tested with Au/polypyrrole/oligonucleotide modified electrodes. Detection by monitoring guanine oxidation was realized amperometrically using an experimental setup which does not require any expensive electrochemical equipment and is therefore suitable for in situ detection. Target detection was also realized by monitoring the decrease in the amplitude of polypyrrole oxidation and reduction peaks in cyclic voltammetry experiments after incubation or injection of target into the electrochemical cell. Detection of 53 pM target within a 2000x excess of non-complementary sequences was possible. The possibility of a dual detection scheme in the same biosensor, with both detection schemes being totally independent from one another is very promising for genosensor design since it would result in a significant decrease in the number of false positive and false negative samples.