Polymerization-assisted signal amplification for electrochemical detection of biomarkers

We present a novel immunosensor by using polymerization-assisted signal amplification strategy coupled with electrochemical detection. A sandwich immunoassay process was used to immobilize a polymerization reaction center, the initiator-conjugated polyclonal prostate specific antigen (PSA) or polyclonal carcinoembryonic antigen (CEA) antibodies on the surface of the electrode. Activator generated electron transfer for atom transfer radical polymerization (AGET ATRP) subsequently triggered the local accumulation of glycidyl methacrylate (GMA) monomers. Growth of long chain polymers provided excess epoxy groups for electrochemical tags aminoferrocene (FcNH(2)) coupling, which in turn significantly increased the loading of the signal molecules and enhanced the electrochemical readouts. The detection limit was ～0.14 pg mL(-1) for PSA and ～0.10 pg mL(-1) for CEA in PBS buffers. The proposed immunosensor was highly sensitive, selective and has a good match to the clinical electrochemiluminescent method. This suggested that the polymerization-assisted immunosensing strategy could be used as an effective method to significantly enhance signal output of the sandwich immunoassays and acted as a promising platform for the clinical screening of cancer biomarkers.     

Enzyme-catalyzed signal amplification for electrochemical DNA detection with a PNA-modified electrode

The signal amplification technique of peptide nucleic acid (PNA)-based electrochemical DNA sensor was developed in a label-free and one-step method utilizing enzymatic catalysis. Electrochemical detection of DNA hybridization on a PNA-modified electrode is based on the change of surface charge caused by the hybridization of negatively charged DNA molecules. The negatively charged mediator, ferrocenedicarboxylic acid, cannot diffuse to the DNA hybridized electrode surface due to the charge repulsion with the hybridized DNA molecule while it can easily approach the neutral PNA-modified electrode surface without the hybridization. By employing glucose oxidase catalysis on this PNA-based electrochemical system, the oxidized mediator could be immediately reduced leading to greatly increased electrochemical signals. Using the enzymatic strategy, we successfully demonstrated its clinical utility by detecting one of the mutation sequences of the breast cancer susceptibility gene BRCA1 at a sample concentration lower than 10(-9) M. Furthermore, a single base-mismatched sample could be also discriminated from a perfectly matched sample.     

Review: Carbon nanotube based electrochemical sensors for biomolecules

Carbon nanotubes (CNTs) have been incorporated in electrochemical sensors to decrease overpotential and improve sensitivity. In this review, we focus on recent literature that describes how CNT-based electrochemical sensors are being developed to detect neurotransmitters, proteins, small molecules such as glucose, and DNA. Different types of electrochemical methods are used in these sensors including direct electrochemical detection with amperometry or voltammetry, indirect detection of an oxidation product using enzyme sensors, and detection of conductivity changes using CNT-field effect transistors (FETs). Future challenges for the field include miniaturizing sensors, developing methods to use only a specific nanotube allotrope, and simplifying manufacturing.     

Advances in signal amplification strategies for electrochemical biosensing

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A sensitive electrochemical aptasensor for ATP detection based on exonuclease III-assisted signal amplification strategy

A target-induced structure-switching electrochemical aptasensor for sensitive detection of ATP was successfully constructed which was based on exonuclease III-catalyzed target recycling for signal amplification. With the existence of ATP, methylene blue (MB) labeled hairpin DNA formed G-quadruplex with ATP, which led to conformational changes of the hairpin DNA and created catalytic cleavage sites for exonuclease III (Exo III). Then the structure-switching DNA hybridized with capture DNA which made MB close to electrode surface. Meanwhile, Exo III selectively digested aptamer from its 3′-end, thus G-quadruplex structure was destroyed and ATP was released for target recycling. The Exo III-assisted target recycling amplified electrochemical signal significantly. Fluorescence experiment was performed to confirm the structure-switching process of the hairpin DNA. In fluorescence experiment, AuNPs–aptamer conjugates were synthesized, AuNPs quenched fluorescence of MB, the target-induced structure-switching made Exo III digested aptamer, which restored fluorescence. Under optimized conditions, the proposed aptasensor showed a linear range of 0.1–20 nM with a detection limit of 34 pM. In addition, the proposed aptasensor had good stability and selectivity, offered promising choice for the detection of other small molecules.     

Carbon nanotube arrays supported manganese oxide and its application in electrochemical capacitors

Manganese oxide (MnO_x) has been coated on carbon nanotubes (CNTs) and fabricated as the electrodes for electrochemical capacitors (ECs) by cathodic electrodeposition. In the process, randomly oriented CNT arrays are grown directly onto the Ti/Si substrates by chemical vapor deposition method. Potentiostatic method has been utilized for cathodic electrodeposition of MnO_x onto the surface of CNTs while immersed in KMnO₄ solution. The highly porosity and fibrous microstructure of the as-prepared MnO_x/CNT electrode is beneficial for the electrolyte access to the active material, whereas CNTs provide improved electronic conductivity. Electrochemical investigations show that the increase in the loading mass of MnO_x results in a significant reduction in the specific capacitances (SCs) of the MnO_x/CNT electrodes. The MnO_x/CNT electrode with MnO_x loading mass of 50 μg shows a high SC of 400 F g⁻¹ with good long cycle stability at a current density of 10 A g⁻¹, suggesting its potential application in ECs.     

Carbon nanotube amplification strategies for highly sensitive immunodetection of cancer biomarkers

We describe herein the combination of electrochemical immunosensors using single-wall carbon nanotube (SWNT) forest platforms with multi-label secondary antibody-nanotube bioconjugates for highly sensitive detection of a cancer biomarker in serum and tissue lysates. Greatly amplified sensitivity was attained by using bioconjugates featuring horseradish peroxidase (HRP) labels and secondary antibodies (Ab(2)) linked to carbon nanotubes (CNT) at high HRP/Ab(2) ratio. This approach provided a detection limit of 4 pg mL(-)(1) (100 amol mL(-)(1)), for prostate specific antigen (PSA) in 10 microL of undiluted calf serum, a mass detection limit of 40 fg. Accurate detection of PSA in human serum samples was demonstrated by comparison to standard ELISA assays. PSA was quantitatively measured in prostate tissue samples for which PSA could not be differentiated by the gold standard immunohistochemical staining method. These easily fabricated SWNT immunosensors show excellent promise for clinical screening of cancer biomarkers and point-of-care diagnostics.     

Glucose oxidase as a blocking agent-based signal amplification strategy for the fabrication of label-free amperometric immunosensors

An effective electrochemical signal amplification strategy based on enzyme membrane modification and redox probe immobilization was proposed to construct an amperometric immunosensor.L-cysteine@ferrocene functionalized chitosan,which possessed not only efficient redox-activity but also excellent film-forming ability,was coated on the bare glass carbon electrode. Moreover,the thiol groups(SH)in the ferrocenyl compound were used for gold nanoparticles immobilization via the strong bonding interaction,which co...     

Understanding signal amplification strategies of nanostructured electrochemical sensors for environmental pollutants

Nanomaterials used in electrochemical sensors can significantly improve the analytical performance to environmental pollutants. This review mainly discusses the strategies for signal amplification by the rational design of nanoelectrode materials from the perspective of mass and electron transfer processes of electrode/solution interface. First, the advantages and features of nanostructured electrochemical sensors for environmental pollutants are summarized. Then, the detailed discussions are focused on the signal amplification strategies by regulating dimensionality, atomic arrangement, and composition of electrode materials. This review gives a unique insight about the influences of electrode material design on mass and electron transfer processes of electrochemical sensors. Finally, on the basis of the current achievements in the field of nanomaterials, the perspectives on the challenges and opportunities for the exploration of nanostructured electrochemical sensors are put forward.     

Current signal amplification strategies in aptamer-based electrochemical biosensor:A review

Due to their high specificity and affinity towards various targets,along with other unique advantages such as stability and low cost,aptamers are widely applied in analytical techniques.A typical aptamerbased electrochemical biosensor is composed of a aptamer as the biological recognition element and transducer conve rting the biologic interaction into electrical signals for the quantitative measure ment of targets.Improvement of the sensitivity of a biosensor is significantly important in order to achieve the detection of biomolecules with low abundance,and different amplification strategies have been explored.The strategies either employ nanomaterials such as gold nanoparticles to construct electrodes which can trans fer the biological reactions more efficiently,or attempt to obtain enha nced signal through multi-labeled carriers or utilize enzyme mimics to catalyze redox cycling.This review discusses recent advances in signal amplification methods and their applications.Critical assessment of each method is also considered.     

A two-component small molecule system for activity-based detection and signal amplification: application to the visual detection of threshold levels of Pd(II)

A detection and signal amplification strategy aimed toward threshold diagnostic assays for use in resource-limited settings is described. The strategy employs two small molecule reagents that work in tandem. One reagent detects a specific analyte, while the second amplifies a colorimetric readout autocatalytically. The strategy is demonstrated using palladium(II) as a model analyte.     

Utilization of nanoparticle labels for signal amplification in ultrasensitive electrochemical affinity biosensors: A review

Nanoparticles with desirable properties not exhibited by the bulk material can be readily synthesized because of rapid technological developments in the fields of materials science and nanotechnology. In particular their highly attractive electrochemical properties and electrocatalytic activity have facilitated achievement of the high level of signal amplification needed for the development of ultrasensitive electrochemical affinity biosensors for the detection of proteins and DNA. This review article explains the basic principles of nanoparticle based electrochemical biosensors, highlights the recent advances in the development of nanoparticle based signal amplification strategies, and provides a critical assessment of the likely drawbacks associated with each strategy. Finally, future perspectives for achieving advanced signal simplification in nanoparticles based biosensors are considered.     

Ultrasensitive electrochemical immunosensor for zeranol detection based on signal amplification strategy of nanoporous gold films and nano-montmorillonite as labels

Nano-montmorillonites belong to aluminosilicate clay minerals with innocuity, high specific surface area, ion exchange, and favorable adsorption property. Due to the excellent properties, montmorillonites can be used as labels for the electrochemical immunosensors. In this study, nano-montmorillonites were converted to sodium montmorillonites (Na-Mont) and further utilized for the immobilization of thionine (TH), horseradish peroxidase (HRP) and the secondary anti-zeranol antibody (Ab₂). The modified particles, Na-Mont-TH-HRP-Ab₂ were used as labels for immunosensors to detect zeranol. This protocol was used to prepare the immunosensor with the primary antibody (Ab₁) immobilized onto the nanoporous gold films (NPG) modified glassy carbon electrode (GCE) surface. Within zeranol concentration range (0.01–12 ng mL⁻¹), a linear calibration plot (Y = 0.4326 + 8.713 X, r = 0.9996) was obtained with a detection limit of 3 pg mL⁻¹ under optimal conditions. The proposed immunosensor showed good reproducibility, selectivity, and stability. This new type of immunosensors with montmorillonites and NPG as labels may provide potential applications for the detection of zeranol.     

An electrochemical signal 'off-on' sensing platform for microRNA detection

The abnormal expression of microRNAs (miRNAs) in many solid tumors makes miRNAs potential biomarkers for disease diagnosis and highlights the need for the sensitive and selective detection of miRNAs. In the present work, an 'off-on' signaling genosensor platform for miRNA-21 detection was well developed. This tactic was based on a locked nucleic acid-integrated nucleic acid hairpin probe, a biotin-labeled bridge DNA-AuNPs-bio-barcode signal amplification unit and enzymatic signal amplification. The test is simple, fast and ultrasensitive with a linear range of 0.01-700 pM. The detection limit was estimated to be 6 fM. The overexpression of miRNA-21 was confirmed in total RNA extracted from human hepatocarcinoma cells BEL-7402 and human HeLa cells compared with the control sample extracted from normal human hepatic L02 cells. This method does not need miRNA-21 labeling, isolation, enrichment or PCR amplification. The performance of the assay developed here could satisfy the need for rapid, easy, sensitive and specific early cancer diagnosis in clinical diagnostics.     

Autoinductive exponential signal amplification: a diagnostic probe for direct detection of fluoride

A new example of an exponential signal amplification strategy for the direct detection of fluoride is demonstrated. The amplification occurred through reaction of fluoride with a responsive chromogenic probe. The probe activity is based on a unique dendritic chain reaction that generates a fluoride anion, which is the analyte of interest, during the disassembly pathway of the dendritic probe. This autoinductive amplification mechanism may be applied for detection of other analytes by coupling activity of a modified probe with that of the fluoride amplifier.     

Entropy-driven molecular switch and signal amplification for homogeneous SNPs detection

An approach was developed to rapidly and sensitively detect SNP in homogeneous solution based on an entropy-driven molecular switch and isothermal polymerase amplification reaction without addition of exogenous primers.     

Gold nanoparticles integrated in a nanotube array for electrochemical detection of glucose

An enzyme-free amperometric glucose sensor of gold nanoparticle-constituted nanotube array electrode is presented. The resulted gold nanotube array electrode with significantly enhanced surface roughness shows prominent catalytic activity toward the electrooxidation of glucose in a pH 7.4 phosphate buffer (PBS) solution and thus can be used to individually or simultaneously determine glucose and the common interfering molecule of ascorbic acid (AA). In the case of glucose detection, the amperometric responses show a linear relationship to glucose concentration in the range of 1 mM–42.5 mM with a detection limit down to 10 μM. The present non-enzymatic glucose electrochemical biosensor shows a good stability and reproducibility.