A doubly amplified electrochemical immunoassay for carcinoembryonic antigen

An ultrasensitive electrochemical immunoassay (EIA) for the detection of carcinoembryonic antigen (CEA) is described in this report. The assay involves utilizing enzyme-catalyzed deposition of a redox polymer and electrocatalytic oxidation of ascorbic acid (AA) by the deposited redox polymer, a dual-amplification scheme to enhance analytical signals. Briefly, CEA capturing antibody and redox polymer anchoring agent were covalently immobilized on a gold electrode. After incubating with CEA, the electrode was treated in detection antibody-glucose oxidase conjugate solution. Thereafter, it was dipped into the redox polymer solution. Upon the addition of glucose, the redox polymer was enzymatically reduced and deposited on the electrode surface. The deposited redox polymer exhibits excellent electrocatalytic activity towards the oxidation of AA. Consequently, CEA could be quantified amperometrically. This electrochemical immunoassay combines the specificity of the immunological reaction with the sensitivity of the doubly amplified electrochemical detection.     

Simultaneous determination of levodopa and 3-O-methyldopa in human plasma by liquid chromatography with electrochemical detection

A simple and rapid assay is described for the simultaneous analysis of levodopa (l-DOPA) and 3-O-methyldopa (3-OMD) in human plasma samples, applying an ion-pair reversed-phase liquid chromatographic method with electrochemical detection, designed for clinical trials performed to study the effect of peripheral catechol-O-methyltransferase inhibitors on the metabolism of l-DOPA. After protein precipitation of 100 microl plasma sample aliquots with perchloric acid, the analytes are directly injected, separated within 10 min and simultaneously quantified down to 20 ng/ml by an electrochemical detector equipped with a dual-electrode system operating in redox mode eliminating effectively potential endogenous and exogenous interferences. The intra-assay precision for l-DOPA and 3-OMD was 1.34-6.54 and 3.90-5.50%, whereas the inter-assay precision was 2.09-7.69 and 4.16-9.90%, respectively. The recoveries were close to 90% for l-DOPA and almost 100% for 3-OMD. Satisfactory storage stability was achieved for up to 16 weeks at -70 degrees C by stabilizing plasma samples with antioxidants.     

An innovative spectroelectrochemical reflection cell for rapid protein electrochemistry and ultraviolet/visible/infrared spectroscopy

A novel electrochemical reflection cell combining electrochemical techniques and spectroscopy which uses a solid gold working electrode as an optical mirror is described. This cell can be used at path lengths as low as a few micrometers and thus is suitable for ultraviolet/visible (UV/Vis) and infrared spectroscopy even for aqueous solutions and suspensions. The cell was designed for small sample volumes of only a few microliters, thus reducing the effort for sample preparation. Due to the short path length of some micrometers, the entire volume is within the Nernst diffusion layer, hence resulting in fast equilibration. Evaluation of the technique is described with direct electrochemistry of horse heart cytochrome c at the gold electrode modified with 4,4'-dithiodipyridine. Cyclic voltammograms indicate rapid and reversible electrochemistry with the correct midpoint potential (52 mV vs Ag/AgCl/3 M KCl). Chronoamperometry and coulometry confirm rapid and complete oxidation and reduction; the cell volume can be entirely fully reduced within less than 10-20 s. Spectroscopy in the UV/Vis region, with potentials at the working electrode stepped between -390 and 390 mV, show perfect titration of the cytochrome c heme bands. A Nernst fit of the alpha band absorption, with redox potential Em and number of electrons n left as parameters, yields a midpoint potential of 49 mV and n=0.9. The potential of this cell in the investigation of biological electron transfer reactions and in the study of bioenergetic systems is discussed.     

Simultaneous Determination of Oxidized and Reduced Forms of Plastoquinone A in Spinach Chloroplasts by High-Performance Liquid Chromatography with an Electrochemical Detector

A method for determination of the redox level of plastoquinoneA in spinach chloroplasts is described. Plastoquinone A andits reduced form plastoquinol A were extracted from chloroplastson a sample-preparation cartridge (SEP-PAK C₁₈ Cartridge, WatersAssoc. Inc.) with a mixture of ethanol and diethyl ether ( 1: 1, vv). Extracts were separated by reversed-phase high-performanceliquid chromatography and examined with an electrochemical detectorequipped with dual electrodes. Plastoquinone A was determinedby its reductive current on one electrode, and plastoquinolA by its oxidative current on the other electrode. This method was applied to the determination of the redox potentialof plastoquinone A in chloroplasts. The midpoint potential atpH 7.8 of plastoquinone A was +20 mV with an n number of 2. (Received March 30, 1987; Accepted August 3, 1987)     

Electrochemical probe for on-chip type flow immunoassay: immunoglobulin G labeled with ferrocenecarboaldehyde

Labeling of ferrocenecarboaldehyde (Fc-CHO) to immunoglobulin G (IgG) via formation of Schiff-base and its reduction was investigated for construction of an electrochemical probe for miniaturized amperometric flow immunoassay. Approximately eight molecules of Fc-CHO were labeled to IgG and the reversible redox property of ferrocene was observed. Labeling efficiency improved by over three times as compared to the conventional method using ferrocenemonocarboxylic acid (Fc-COOH). Also, binding affinity of IgG labeled with Fc-CHO to its antigen, IgE, was investigated by enzyme-linked immunosorbent assay (ELISA) and surface plasmon resonance assay. IgG labeled with Fc-CHO that retained eight ferrocene moiety showed sufficient binding affinity to its antigen and the current response obtained in the flow electrochemical detection system increased by 14-fold as compared with IgG labeled with Fc-COOH when applying the potential of 390 mV vs. Ag/AgCl. The minimum detectable concentration of IgG labeled with Fc-CHO was 0.06 microM. IgG labeled with Fc-CHO demonstrate biochemical and electrochemical properties that are useful for electrochemical immunosensors.     

Electrochemical Behaviour of Copper-Containing Nitrite Reductase from Alcaligenes Faecalis Strain-6

Indirect and direct electrochemical reactions of copper containing nitrite reductase (NIR) from Alcaligenes faecalis strain-6 are described. The reactivity of mediators, including blue protein from the same organism (the native redox partner of NIR, AfBP), in electrocatalytic reactions (EC') involving a mediator, NIR and nitrite was investigated. Several types of EC were observed and AfBP was found to be an effective mediator in spite of its high redox potential. Direct electrochemistry was observed at an Indium Tin Oxide electrode (ITO) and an edge plane oriented pyrolytic graphite electrode (PGE). Observation of the redox activity of NIR at an ITO in an optically transparent thin layer electrode cell (OTTLE) showed that it underwent reversible changes in absorbance that corresponded to the applied potential. The electrochemically adsorbed NIR at PGE showed fast electrochemical kinetics in cyclic voltammetry. It is suggested that the weak affinity of NIR to the PGE electrode may prevent complete denaturation of NIR in the adsorbed state.     

THe proton-per-electron stoicheiometry of ''site 1'' of oxidative phosphorylation at high protonmotive force is close to 1.5.

The maximum redox potential difference between the NAD+/NADH couple and the succinate/fumarate couple generated during ATP-energized reduction of NAD+ by succinate in submitochondrial particles was measured, together with the electrochemical potential difference for protons (delta mu approximately H+). The presence of cyanide, the time-independence of the redox potential difference and the irrelevance of the initial redox state of the NAD+/NADH couple ensured that the experimental situation corresponded to a 'static-head condition' with delta mu approximately H+ as the input force and the redox potential difference as the output force, the flow of electrons having reached dynamic equilibrium. Consequently, the observed value of 1.6 for the ratio delta Ge/delta mu approximately H+ is interpreted as indicating that the leads to H+/e- stoicheiometry at 'site 1' is 1.5 and that therefore the mechanism of the proton pump at 'site 1' is not of the group-translocation type (no direct leads to e - leads to H+ coupling).     

Fabrication of comb interdigitated electrodes array (IDA) for a microbead-based electrochemical assay system

This research is directed towards developing a more sensitive and rapid electrochemical sensor for enzyme labeled immunoassays by coupling redox cycling at interdigitated electrode arrays (IDA) with the enzyme label beta-galactosidase. Coplanar and comb IDA electrodes with a 2.4 microm gap were fabricated and their redox cycling currents were measured. ANSYS was used to model steady state currents for electrodes with different geometries. Comb IDA electrodes enhanced the signal about three times more than the coplanar IDAs, which agreed with the results of the simulation. Magnetic microbead-based enzyme assay, as a typical example of biochemical detection, was done using the comb and coplanar IDAs. The enzymes could be placed close to the sensing electrodes (approximately 10 microm for the comb IDAs) and detection took less than 1 min with a limit of detection of 70 amol of beta-galactosidase. We conclude that faster and more sensitive assays can be achieved with the comb IDA.     

Redox environment of the cell as viewed through the redox state of the glutathione disulfide/glutathione couple

Redox state is a term used widely in the research field of free radicals and oxidative stress. Unfortunately, it is used as a general term referring to relative changes that are not well defined or quantitated. In this review we provide a definition for the redox environment of biological fluids, cell organelles, cells, or tissue. We illustrate how the reduction potential of various redox couples can be estimated with the Nernst equation and show how pH and the concentrations of the species comprising different redox couples influence the reduction potential. We discuss how the redox state of the glutathione disulfide-glutathione couple (GSSG/2GSH) can serve as an important indicator of redox environment. There are many redox couples in a cell that work together to maintain the redox environment; the GSSG/2GSH couple is the most abundant redox couple in a cell. Changes of the half-cell reduction potential (E(hc)) of the GSSG/2GSH couple appear to correlate with the biological status of the cell: proliferation E(hc) approximately -240 mV; differentiation E(hc) approximately -200 mV; or apoptosis E(hc) approximately -170 mV. These estimates can be used to more fully understand the redox biochemistry that results from oxidative stress. These are the first steps toward a new quantitative biology, which hopefully will provide a rationale and understanding of the cellular mechanisms associated with cell growth and development, signaling, and reductive or oxidative stress.     

Microfluidic electrochemical assay for rapid detection and quantification of Escherichia coli

Microfluidic electrochemical biosensor for performing Loop-mediated isothermal amplification (LAMP) was developed for the detection and quantification of Escherichia coli. The electrochemical detection for detecting the DNA amplification was achieved using Hoechst 33258 redox molecule and linear sweep voltametry (LSV). The DNA aggregation and minor groove binding with redox molecule cause a significant drop in the anodic oxidation of LSV. Unlike other electrochemical techniques, this method does not require the probe immobilization and the detection of the bacteria can be accomplished in a single chamber without DNA extraction and purification steps. The isothermal amplification time has a major role in the quantification of the bacteria. We have shown that we could detect and quantify 24 CFU/ml of bacteria and 8.6 fg/μl DNA in 60 min and 48 CFU/ml of bacteria in 35 min in LB media and urine samples. We believe that this microfluidic chip has great potential to be used as a point of care diagnostic (POC) device in the clinical/hospital application.     

Inlaid Nd-substituted bismuth titanate nanoplates for protein immobilization and Nd-controlled electrochemical properties

Neodymium (Nd) substituted bismuth titanate (Bi(4-x)Nd(x)Ti(3)O(12), BNTO-x) nanoplates inlaid one another were prepared by sol-gel hydrothermal method, which was explored for protein immobilization and biosensor fabrication. Comparative experiments witnessed that Bi(3+) ions in bismuth titanate (Bi(4)Ti(3)O(12), BTO) were successfully substituted with Nd(3+) ions, and the electrochemical properties of the Hb-Chi-BNTO biosensors closely depended on the Nd(3+) ion content. With increasing the Nd(3+) doping content, the electrochemical performance of the Hb-Chi-BNTO-x biosensors showed regularly variable. Moreover, compared with the Hb-Chi-BTO and other Hb-Chi-BNTO-x biosensors, the Hb-Chi-BNTO-0.85 biosensor had more excellent electrochemical and electrocatalytic properties such as stronger redox peak currents (approximately three-fold), smaller peak-to-peak separation (50 mV), larger heterogeneous electron transfer rate (14.1 ± 3.8s(-1)), higher surface concentration of electroactive redox protein (about 8.16 × 10(-11)mol/cm(2)), and better reproducibility and stability. The Nd-depended electrochemical properties of the Hb-Chi-BNTO biosensors may open up a new idea for designing third-generation electrochemical biosensors, and the BNTO-0.85-based biosensor is also expected to find potential applications in many areas such as biomedical, food, and environmental detection.     

2'-anthraquinone-conjugated oligonucleotide as an electrochemical probe for DNA mismatch

We previously prepared the oligonucleotides (ODNs) conjugated to an anthraquinone (AQ) group via one carbon linker at the 2'-sugar position. When these modified ODNs bind to cDNA sequences, the AQ moiety can be intercalated into the predetermined base-pair pocket of a duplex DNA. In this paper, 2'-AQ-modified ODNs are shown to be an excellent electrochemical probe to clarify the effect of a mismatch base on the charge transfer (CT) though DNA. Two types of DNA-modified electrodes were constructed by assembly of disulfide-terminated 2'-AQ-ODN duplexes onto gold electrodes. One type of electrodes (system I) contains fully matched base pairs or a single-base mismatch in duplex DNA between the redox center and the electrode. The other (system II) consists of the mismatch but at the outside of the redox center. The modified electrodes were analyzed by cyclic voltammetry to estimate the CT rate through duplex DNA. In system I, the CT rate was found to be approximately 50 s (-1) for the fully matched AQ-ODN duplexes, while the CT rates of the mismatched DNA were considerably slower than that of the fully matched DNA. In system II, the AQ-ODN duplexes showed almost similar CT rates ( approximately 50 s (-1)) for the fully matched DNA and for the mismatched DNAs. The detection of a single-base mismatch was then performed by chronocoulometry (CC). All the DNA duplexes containing a mismatch base in system I gave the reduced electrochemical responses when compared to the fully matched DNA. In particular, the mismatched DNAs including G--A mismatch can be differentiated from fully matched DNA without using any electrochemical catalyst. We further tested the usefulness of single-stranded (ss) AQ-ODN immobilized on a gold electrode in the electrochemical detection of a single-base mismatch through hybridization assay. The ss-AQ-ODN electrodes were immersed in target-containing buffer at room temperature, and the CC measurements were carried out to see the changes in the integrated charge. Within 60 min, the mismatched DNA was clearly distinguishable by the CC differences from the fully matched target. Thus, the electrochemical hybridization assay provides an easy and convenient detection for DNA mutation that does not require any extra reagents, catalyst, target labeling, and washing steps.     

Redox properties of the calcium chelator Fura-2 in mimetic biomembranes

Fura-2 is one of the most commonly used fluorescent dyes to analyze the cytosolic Ca(2+) concentration ([Ca(2+)](i)) of living cells. Fura-2-dependent measurements of [Ca(2+)](i) are susceptible to changes of pH, reactive oxygen species concentration and membrane potential. Fura-2 is often loaded over the lipophilic cell membrane into the cytosol of a cell in its esterified form (Fura-2/AM) which is then cleaved by endogenous esterases. We have analyzed the electrochemical properties of Fura-2/AM and Fura-2 salt by cyclic voltammetry ("three-phase" and "thin-film" electrode methods). Using Fura-2/AM as a redox facilitator, we were able to mimic the transport of various ions across a lipophilic barrier. We show that Fura-2/AM in this biomimetic set-up can be reversibly oxidized in a single electrochemical step. Its redox reaction was highly proton sensitive in buffers with pH< or =6. At physiological pH of around 7.0, the oxidation of Fura-2/AM was coupled to an uptake of mono-anions across the liquid-liquid interface. The voltage-dependence of the redox cycle was sensitive to the free Ca(2+) concentration, either after de-esterification of Fura-2/AM, or when Fura-2 salt was used. The complex between Fura-2 and Ca(2+) ions is ionic (complexation occurs via the dissociated negative groups of Fura forms), while the redox transformations in Fura-2 occurs at the nitrogen atoms of the amino groups. Our results suggest that redox transformations of the Fura-2 forms do not affect the binding ability toward Ca(2+) ions and thus do not interfere with [Ca(2+)](i) measurements.     

Graphene-promoted 3,4,9,10-perylenetetracarboxylic acid nanocomposite as redox probe in label-free electrochemical aptasensor

Graphene/3,4,9,10-perylenetetracarboxylic acid (GPD) with three-dimensional porous structure has been successfully synthesized and served as redox probe to construct ultrasensitive electrochemical aptasensor. The GPD nanocomposite shows promoted electrochemical redox-activity of 3,4,9,10-perylenetetracarboxylic acid (PTCA) with an obvious well-defined cathodic peak from -0.7 to 0 V that never been seen from graphene or PTCA, which avoids miscellaneous redox peaks of PTCA in electrochemical characterization, offering a novel redox probe for electrochemical sensors with highly electrochemical active area and conductivity. To the best of our knowledge, this is the first study that utilizes PTCA self-derived redox-activity as redox probe in electrochemical sensors. Moreover, the interesting GPD possesses the advantages of membrane-forming property, providing a direct immobilization of redox probes on electrode surface. This simple process not only diminishes the conventional fussy immobilization of redox probes on the electrode surface, but also reduces the participation of the membrane materials that acted as a barrier of the electron propagation in redox probe immobilization. With thrombin as a model target, the redox probe-GPD based label-free electrochemical aptasensor shows a much higher sensitivity (a detection range from 0.001 nM to 40 nM with a detection limit of 200 fM) to that of analogous aptasensors produced from other redox probes.     

A cell for bioelectrochemical studies with parallel spectrophotometric monitoring of the studied substance

An electrochemical cell for simultaneous potentiometric and spectrophotometric measurements of solutions of various substances is described. A schematic diagram of the cell, its advantages, method of use, and possible areas of application are discussed. The cell is suggested to be used for electrochemical potentiometric redox titration of leghemoglobin and electrochemical reduction of organic reductants commonly used in biochemical research.     

Nucleic acid hybridization assays employing dA-tailed capture probes. I. Multiple capture methods

A quantitative hybridization assay termed "reversible target capture" is described. The technique is designed to extensively purify the target nucleic acid from crude cell lysates in about 1 h without phenol extraction. Simple, rapid methods are described that explain how each process in the assay is optimized. The procedure involves hybridizing the target nucleic acid in solution with a dA-tailed capture probe and a labeled probe. The capture probe-target-labeled probe "ternary complex" is then captured on magnetic beads containing oligo(dT). After the excess unhybridized labeled probe, cell debris, and other sample impurities are washed away, the intact ternary complex is further purified by chemical elution from the beads and recapture on fresh beads. The ternary complex is then eluted thermally and recaptured on a third set of beads or on poly(dT) filters. This triple capture method results in a detection limit of approximately 0.2 amol (100 fg) of target with 32P-labeled riboprobes. This is approximately 1000 times more sensitive than sandwich assays employing only a single capture step. The method is illustrated by detecting Listeria cells in the presence of heterologous bacteria. With three rounds of target capture, as few as six Listeria cells have been detected in the presence of 1.25 x 10(7) control cells.     

High-sensitivity electrochemical enzyme-linked assay on a microfluidic interdigitated microelectrode

A novel enzyme-linked DNA hybridization assay on an interdigitated array (IDA) microelectrode integrated into a microfluidic channel is demonstrated with sub-nM detection limit. To improve the detection limit as compared to conventional electrochemical biosensors, a recyclable redox product, 4-aminophenol (PAP) is used with an IDA microelectrode. The IDA has a modest and easily fabricated inter-digit spacing of 10 μm, yet we were able to demonstrate 97% recycling efficiency of PAP due to the integration in a microfluidic channel. With a 70 nL sample volume, the characterized detection limit for PAP of 1.0 × 10?1? M is achieved, with a linear dynamic range that extends from 1.0 × 10?? to 1.0 × 10?? M. This detection limit, which is the lowest reported detection limit for PAP, is due to the increased sensitivity provided by the sample confinement in the microfluidic channel, as well as the increased repeatability due to perfectly static flow in the microchannel and an additional anti-fouling step in the protocol. DNA sequence detection is achieved through a hybridization sandwich of an immobilized complementary probe, the target DNA sequence, and a second complementary probe labeled with β-galactosidase (β-GAL); the β-GAL converts its substrate, 4-aminophenyl-d-galactopyranoside (PAPG), into PAP. In this report we present the lowest reported observed detection limit (1.0 × 10?1? M) for an enzyme-linked DNA hybridization assay using an IDA microelectrode and a redox signaling paradigm. Thus, we have demonstrated highly sensitive detection of a targeted DNA sequence using a low-cost easily fabricated electrochemical biosensor integrated into a microfluidic channel.     

An EQCM study on the interaction of heparin with the charge-transfer complex generated during o-tolidine electrooxidation: a biosensing mode with a dynamically renewed surface

The electrooxidation of o-tolidine (oTD) was investigated via the electrochemical quartz crystal microbalance (EQCM) technique. The formation and breakage of the poorly soluble charge-transfer complex (CTC) occurred during the redox switching of oTD, and the CTC precipitation on and its removal from the electrode surface led to a V-shaped frequency response to the cyclic voltammetric switching of oTD. The V-shaped frequency response to the redox switching of the CTC/oTD "couple" and the electrode-collection efficiency of the CTC precipitate were notably enhanced by the introduction of sodium heparin due to the formation of the CTC-heparin adduct as reported here for the first time. FTIR and UV-Vis characterizations also supported the interaction between the CTC and heparin. The molar ratio of the positively charged CTC to negatively charged heparin of the adduct was estimated here to be between 31.5 and 36.5, being close to the anticipated value, 37.5, for the full electrical neutralization in the adduct. An EQCM-based biosensor featured by a dynamically renewed surface of the detection electrode was proposed for heparin assay, with a limit of detection of 18.5 nM (S/N=3) in pH 6.0 Britton-Robinson buffer solution containing a 10-fold diluted blood serum. This method is convenient in operation and highly free from the interference from coexisting substances including proteins. The new and intriguing biosensing concept based on the labile CTC-"target" adduct is featured by a dynamically renewable and regenerable surface of the detection electrode, and it is highly recommended for wide biosensing and electroanalytical applications.     

A bioelectrochemical cell allowing simultaneous spectrophotometric control of the analyte

An electrochemical cell for simultaneous potentiometric and spectrophotometric measurements of solutions of various substances is described. A schematic diagram of the cell, its advantages, method of use, and possible areas of application are discussed. The cell is suggested for use in electrochemical potentiometric redox titration of leghemoglobin and electrochemical reduction of organic reductants commonly used in biochemical research.