A Sandwich‐Type Electrochemical Biosensor for Detection of BCR/ABL Fusion Gene Using Locked Nucleic Acids on Gold Electrode

In this study, a sandwich‐type electrochemical enzyme‐based LNA‐modified DNA biosensor was developed to detect relative gene in chronic Myelogenous Leukemia first. This biosensor is based on a ‘sandwich’ detection strategy, which involves a pair of probes (a capture probe immobilized at the electrode surface and a reporter probe labeled biotin as an affinity tag for avidin‐HRP) modified LNA. Since biotin can be connected with avidin‐HRP, this biosensor offers an enzymatically amplified electrochemical current signal for the detection of target DNA. This new pattern exhibits high sensitivity and selectivity, and this biosensor has been used for an assay of PCR real sample with satisfactory result.     

Catalytic Hairpin Assembly‐Programmed DNA Three‐Way Junction for Enzyme‐Free and Amplified Electrochemical Detection of Target DNA

DNA three‐way junctions (DNA 3WJ) have been widely used as important building blocks for the construction of DNA architectures and dynamic assemblies. Herein, we describe for the first time a catalytic hairpin assembly‐programmed DNA three‐way junction (CHA‐3WJ) strategy for the enzyme‐free and amplified electrochemical detection of target DNA. It takes full advantage of the target‐catalyzed hairpin assembly‐induced proximity effect of toehold and branch‐migration domains for the ingenious execution of the strand displacement reaction to form the DNA 3WJ on the electrode surface. A low detection limit of 0.5 pM with an excellent selectivity was achieved for target DNA detection. The developed CHA‐3WJ strategy also offers distinct advantages of simplicity in probe design and biosensor fabrication, as well as enzyme‐free operation. Thus, it opens a promising avenue for applications in bioanalysis, design of DNA‐responsive devices, and dynamic DNA assemblies.     

Ultrasensitive Electrochemiluminescence Biosensor for mRNA Based on Polymerase Assisted Signal Amplification

A novel biosensor for ultra‐trace mRNA sensing was constructed based on isothermal circular strand‐replacement polymerization (CSRP) to amplify the electrochmeiluminescence (ECL) signal by combining quantum dots (CdTe) as luminophore. After the hairpin‐like capture DNA was opened by hybridization with target mRNA, the additive primer (DNA1) was able to get access to its complementary sequence which is partially belong to the stem part and triggered a polymerization of DNA strand, leading to the release of target mRNA and another polymerization cycle. The remaining sequence of the stem part continued to hybridize with QDs labeled DNA, accomplishing ECL signal amplification. Target mRNA could be specifically assayed with a linear relationship between the signal intensity and the logarithm of concentrations of target DNA in the range of 1.0×10⁻¹⁴∼5.0×10⁻¹⁰ M, with a low detection limit of 1.4×10⁻¹⁵ M. The signal could discriminate perfect matched target mRNA from 1‐base mismatch sequence. This proposed ECL biosensor exhibited an efficient performance in serum sample, opening new opportunities for genetic target analysis in diagnostic and clinic biomedical fields.     

Ultrasensitive electrochemical supersandwich DNA biosensor using a glassy carbon electrode modified with gold particle-decorated sheets of graphene oxide

We describe a supersandwich type of electrochemical DNA biosensor based on the use of a glassy carbon electrode (GCE) modified with reduced graphene oxide (rGO) sheets that are decorated with gold nanoparticles (Au NPs). Thiolated capture DNA (probe DNA) was covalently linked to the Au NPs on the surface of the modified GCE via formation of Au-S bonds. In presence of target DNA, its 3′ terminus hybridizes with capture probe and the 5′ terminus hybridizes with signal probe labeled with Methylene Blue (MB). On increasing the concentration of target DNA, hybridization between signal probe and target DNA results in the formation of three different DNA sequences that form a supersandwich structure. The signal intensity of MB improves distinctly with increasing concentrations of target DNA in the sample solution. The assembling process on the surface of the electrode was studied by scanning electron microscopy (SEM) and electrochemical impedance spectroscopy (EIS). Differential pulse voltammetry (DPV) was used to monitor the hybridization event by measuring the changes in the peak current for MB. Under optimal conditions, the peak currents in DPV for MB linearly increase with the logarithm of target DNA concentration in the range from 0.1 μM to1.0 fM, with a detection limit of 0.35 fM (at an signal/noise ratio of 3). This biosensor exhibits good selectivity, even over single-base mismatched target DNA.

Electrochemical Determination of Aflatoxin B1 (AFB1) Using a Copper-Based Metal-Organic Framework (Cu-MOF) and Gold Nanoparticles (AuNPs) with Exonuclease III (Exo III) Assisted Recycling by Differential Pulse Voltammetry (DPV)

Abstract

A sensitive electrochemical biosensor was designed for determination of aflatoxin B1 (AFB1) using a copper-based metal-organic framework (Cu-MOF), which has strong electrochemical activity and exonuclease III (Exo III)-assisted recycling for dual signal amplification. Hairpin DNA (S1) was immobilized on the electrode. The AFB1 was recognized by aptamer DNA (S2) and complementary DNA (S3) was released. The S3 hybridized with the hairpin S1 to form the Exo III hydrolyzed double-stranded DNA, leaving a partial sequence of hairpin DNA (S1′) on the electrode and releasing S3 for the next cycle of the opening and digestion of hairpin S1. The amplified S1′ then was able to combine with more signal probes. Cu-MOF bond gold nanoparticles (AuNPs) by -NH₂ were immobilized to capture DNA (S4) to obtain Cu-MOF/AuNPs/S4. This signal probe Cu-MOF/AuNPs/S4 was able to hybridize with the electrode and generate an amplified electrochemical signal. Under the optimized conditions, this electrochemical biosensor for AFB1 exhibited a low detection limit of 6.7?×?10^?7?ng/mL at a signal-to-noise equal to 3 and a wide linear range from 10^?6 to 1?ng/mL. The biosensor was also used to analyze AFB1-spiked beer sample with recovery values between 96% and 103%. This method has the potential to become a valuable technology for detecting various toxins by the selection of the appropriate aptamer DNA.     

Dual Signal Amplification Electrochemical Biosensor for Lead Cation

Herein, a sensitive electrochemical Pb²⁺ sensor was developed which based on DNA‐functionalized Au nanoparticles(AuNPs) and nanocomposite modified electrode. The DNA‐functionalized AuNPs includes two types of DNA, namely a Pb²⁺‐mediated DNAzyme comprising a biotin labeled‐enzyme DNA and a substrate strand DNA with a typical stem‐loop structure, and a ferrocene‐labeled linear signal DNA. Without Pb²⁺, the hairpin loop impeded biotin binding to avidin on the electrode. However,when the goal Pb²⁺ exists, the substratum strand was divided into two fragments that lead to the enzyme strand was substratumed on the electrode and biotin was admited by avidin, bringing about DNA‐functionalized AuNP(AuNPs) deposition on the electrode surface.The differential pulse voltammetry (DPV) was used to measure electrochemical response signals connect to signal DNA.For the amplification characters of the DNA‐functionalized AuNPs and nanocomposite, the electrochemical detection signal of Pb²⁺ was greatly improved and revealed high specificity. Under optimum conditions, the resultant biosensor bringed out a high sensitivity and selectivity for the determination of Pb²⁺. The proposed method was able to detect as low as picomolar Pb²⁺ concentrations.     

Target-driven self-assembly of stacking deoxyribonucleic acids for highly sensitive assay of proteins

In this paper, we report a new signal amplification strategy for highly sensitive and enzyme-free method to assay proteins based on the target-driven self-assembly of stacking deoxyribonucleic acids (DNA) on an electrode surface. In the sensing procedure, binding of target protein with the aptamer probe is used as a starting point for a scheduled cycle of DNA hairpin assembly, which consists of hybridization, displacement and target regeneration. Following numbers of the assembly repeats, a great deal of DNA duplexes can accordingly be formed on the electrode surface, and then switch on a succeeding propagation of self-assembled DNA concatemers that provide further signal enhancement. In this way, each target binding event can bring out two cascaded DNA self-assembly processes, namely, stacking DNA self-assembly, and therefore can be converted into remarkably intensified electrochemical signals by associating with silver nanoparticle-based readout. Consequently, highly sensitive detection of target proteins can be achieved. Using interferon-gamma as a model, the assay method displays a linear range from 1 to 500 pM with a detection limit of 0.57 pM, which is comparable or even superior to other reported amplified assays. Moreover, the proposed method eliminates the involvement of any enzymes, thereby enhancing the feasibility in clinical diagnosis.     

基于杂交链式反应辅助多重信号放大的端粒酶灵敏检测

端粒酶是真核细胞维持端粒长度的关键逆转录酶,其生物活性的高低可以为多种癌症的临床诊断和预后治疗提供有价值的信息.本研究以人宫颈癌细胞(HeLa细胞)裂解液中的端粒酶为研究对象,通过借助杂交链式反应辅助多重信号放大策略,提出了一种新颖、灵敏的检测端粒酶电化学方法.首先将端粒酶的延伸引物自组装在金电极表面,当端粒酶存在时,端粒酶能够催化引物的延伸,产生与发卡环探针H1部分互补的序列,进而引发杂交链式反应,形成由两个发卡环探针(H1和H2)交替杂交而形成的DNA长链.由于H1和H2末端均修饰有生物素,加入链霉亲和素修饰辣根过氧化物酶后,辣根过氧化物酶被被连接到电极表面,催化邻苯二胺氧化生成2,3-二氨基吩嗪,产生显著的电化学信号.实验结果表明,本研究建立的端粒酶电化学检测方法高效、可行,线性范围宽,灵敏度高,可以检测每毫升10个HeLa细胞裂解液中的端粒酶.本方法具有较好的选择性,能有效区分端粒酶和对照蛋白.     

A Novel Electrochemical DNA Biosensor Fabricated with Layer‐by‐Layer Covalent Attachment of Multiwalled Carbon Nanotubes and Gold Nanoparticles

A novel DNA biosensor has been fabricated for the detection of DNA hybridization based on layer‐by‐layer (LBL) covalent assembly of gold nanoparticles (GNPs) and multiwalled carbon nanotubes (MWCNTs). The stepwise LBL assembly process was characterized by cyclic voltammetry (CV) and electrochemical impedance spectroscopy (EIS). The hybridization events were monitored by differential pulse voltammetry (DPV) measurement of the intercalated doxorubicin, and the factors influencing the performance of the DNA hybridization was investigated in detail. The signal was linearly changed with target DNA concentration increased from 0.5 to 0.01 nM, and had a detection limit of 7.5 pM (signal/noise ratio of 3). In addition, the DNA biosensor showed an excellent reproducibility and stability under the DNA‐hybridization conditions.     

Enzyme spheres as novel tracing tags coupled with target-induced DNAzyme assembly for ultrasensitive electrochemical microRNA assay

In this work, an ultrasensitive electrochemical microRNA detection strategy was developed based on porous palladium-modified horseradish peroxidase sphere (Pd@HRP) and target-induced assembly of DNAzyme. A highly loaded HRP sphere was prepared by covalent layer-by-layer assembly with CaCO₃ as sacrificial template for the first time, and was further modified with porous Pd. Notably, Pd@HRP composite showed a good redox activity of HRP and electrocatalytic activity toward H₂O₂. The utilization of Pd@HRP as electrochemical signal indicator and enhancer to fabricate biosensor could avoid the need for additional redox mediator and amplify the detection sensitivity. Moreover, target recycling amplification was achieved by Pb²⁺-induced cleavage of ternary “Y” structure, circumventing the use of labile nuclease. Subsequent DNA concatamer synthesized through rolling circle amplification (RCA) reaction with cleaved hairpin probe as primer, hybridized with plentiful Pd@HRP-DNA probes, which led to the increased loading of redox-active and electrocatalytic Pd@HRP for sensitivity improvement. So the proposed electrochemical biosensor detected miRNA-24 down to 0.2 fM (S/N = 3) with a wide linear range from 3 fM to 1 nM. With bifunctional Pd@HRP tag, DNAzyme-aided target recycle and programmable junction probe, this strategy possessed the advantages of high efficiency, high sensitivity, low cost and versatility, and thus held great promise for other low-abundance nucleic acids determination.     

Fabricating a reversible and regenerable electrochemical biosensor for quantitative detection of antibody by using “triplex-stem” DNA molecular switch

A reversible and regenerable electrochemical biosensor is fabricated for quantitative detection of antibody based on “triplex-stem” molecular switches. A hairpin-shaped oligonucleotide (hairpin DNA) labeled with ferrocene (Fc) at the 3′-end is fixed on the gold electrode serving as a signal transduction probe. Its hairpin structure leads Fc close to the surface of gold electrode and produces a strong current signal (on-state). A single-strand oligonucleotide modified with two digoxin molecules on the two arm segments (capture DNA) interact with hairpin DNA with the help of Ag⁺ ions. The “triplex-stem” DNA forms, which separates Fc from the electrode and reduces the electrochemical signal (off-state). Binding of digoxin antibody to digoxin releases capture DNA from the hairpin DNA, creating an effective “off-on” current signal switch. The stability of the “triplex-stem” structure of hairpin/capture DNA is critical to the signal switch and the sensitivity of the method, which can be adjusted conveniently and efficiently by changing Ag⁺ concentrations. Based on the “off-on” current signal switch, this biosensor is used to detect digoxin antibody sensitively in blood serum. The linear range is 1.0–500 pg with a correlation coefficient of 0.996, and the detection limit is 0.4 pg. Also, this biosensor shows excellent reversibility and reproducibility, which are significant requirements for practical biosensor applications.     

Multiplexed Immunosensing Platform Coupled to Hybridization Chain Reaction for Electrochemical Determination of MicroRNAs in Clinical Samples

There is an urgent need for development of rapid and inexpensive techniques for detection of microRNAs (miRNAs), which are potential biomarkers of various types of cancer. In this paper, we describe a multiplexed electrochemical platform for determination of three cancer‐relevant miRNAs: miR‐21, let‐7a and miR‐31. The strategy combines the use of magnetic beads (MBs) modified with a commercial antibody for the efficient capture of the heteroduplexes formed by hybridization of the target miRNA with DNA probe. Free non‐hybridized region of the DNA probe was thereafter hybridized with two biotin‐labeled auxiliary DNA probes in a process of hybridization chain reaction (HCR), resulting in a long hybrid bearing a large number of biotin molecules. Labeling of these multiple biotin units with streptavidin‐peroxidase conjugates allowed an amplification of the amperometric signal measured after capturing the modified MBs at a screen‐printed carbon electrode array of eight electrodes. The combined strategy demonstrated in a similar assay time significantly higher sensitivity than those previously described using modified MBs with the same capture antibody (without amplification by HCR) or a HCR strategy implemented on the surface of MBs, respectively. The methodology exhibits a good selectivity for discriminating single mismatches and was applied to the determination of the three target miRNAs in total RNA (RNA_t) extracted from various cancer cell lines and from cervical precancerous lesions.     

A Peptide Nucleic Acid (PNA)‐DNA Ferrocenyl Intercalator for Electrochemical Sensing

A ferrocenyl intercalator was investigated to develop an electrochemical DNA biosensor employing a peptide nucleic acid (PNA) sequence as capture probe. After hybridization with single strand DNA sequence, a naphthalene diimide intercalator bearing ferrocene moieties (FND) was introduced to bind with the PNA‐DNA duplex and the electrochemical signal of the ferrocene molecules was used to monitor the DNA recognition. Electrochemical impedance spectroscopy was used to characterize the different modification steps. Differential pulse voltammetry was employed to evaluate the electrochemical signal of the FND intercalator related to its interaction with the complementary PNA‐DNA hybrid. The ferrocene oxidation peaks were utilised for the target DNA quantification. The developed biosensor demonstrated a good linear dependence of FND oxidation peak on DNA concentration in the range 1 fM to 100 nM of target DNA, with a low detection limit of 11.68 fM. Selectivity tests were also investigated with a non‐complementary DNA sequence, indicating that the FND intercalator exhibits a selective response to the target PNA‐DNA duplex.     

Microfluidic nanoplasmonic-enabled device for multiplex DNA detection

We describe a rapid, quantitative, multiplex, self-labelled, and real-time DNA biosensor employing Ag nanoparticle-bound DNA hairpin probes immobilized in a microfluidic channel. Capture of complementary target DNAs by the microarrayed DNA hairpin probes results in a positive fluorescence signal via a conformational change of the probe molecules, signalling the presence of target DNAs. The device's capability for quantitative analyses was evaluated and a detection time as low as 6 min (with a target flow rate of 0.5 μl min(-1)) was sufficient to generate significant detection signals. This detection time translates to merely 3 μl of target solution consumption. An unoptimized sensitivity of 500 pM was demonstrated for this device.     

A sensitive and label-free impedimetric biosensor based on an adjunct probe

A highly sensitive and label-free impedimetric biosensor is achieved based on an adjunct probe attached nearby the capture probe. In this work, the adjunct probe was co-assembled on the surface of gold electrode with the capture probe hybridized with the reporter probe, and then 6-mercapto-1-hexanol was employed to block the nonspecific binding sites. When target DNA was added, the adjunct probe functioned as a fixer to immobilize the element of reporter probe displaced by the target DNA sequences and made the reporter probe approach the electrode surface, leading to effective inhibition of charge transfer. The increase in charge transfer resistance is related to the quantity of the target DNA in a wide range. The linear range for target DNA with specific sequences was from 0.1 nM to 0.5 μM with a good linearity (R = 0.9988) and a low detection limit of 6.3 pM. This impedimetric biosensor has the advantages of simplicity, sensitivity, good selectivity, and large dynamic range.     

Chemiluminescent detection of DNA hybridization and single-nucleotide polymorphisms on a solid surface using target-primed rolling circle amplification

A new chemiluminescent (CL) method has been developed for the sensitive detection of DNA hybridization and single-nucleotide polymorphisms (SNPs) with target-primed rolling circle amplification (RCA). The capture oligonucleotide probe is firstly immobilized on a polystyrene well plate and then hybridized with the wild DNA target. A designed padlock probe is circularized after perfect hybridization to the DNA target. Then the RCA reaction can be initiated from the DNA target that acts as a primer and generates a long tandem single-strand of DNA with repeat sequences. In contrast, the mutant DNA target, which contains a mismatched base with the padlock probe, cannot initiate the RCA reaction and primes only a limited extension with the unligated padlock probe. Afterwards, a biotinylated oligonucleotide is used to hybridize with the RCA product in each repeat sequence and streptavidin-alkaline phosphatase (STV-AP) is employed to combine the anchored biotin. The DNA target is detected with the CL reaction of STV-AP and 3-(2'-spiroadamantane)-4-methoxy-4-(3'-phosphoryloxy)phenyl-1,2-dioxetane (AMPPD). With the RCA-based method, the sensitivity of DNA detection can be increased by about two orders of magnitude compared with that of direct DNA hybridization. A DNA target as low as 3.6 pM can be detected. Wild-type DNA and the one-base mutant DNA can be differentiated with high selectivity through this RCA reaction.     

An Electropolymerized Membrane Biosensor for Speciffic DNA Recognition

A sensitive electrochemical biosensor for detecting the sequence of short DNA oligomers is represented. The biosensor is based on a platinum electrode covered a polymerized membrane of conductive monomer N‐[6‐(thien‐3‐yl)acetoxy]‐pyrrolidine‐2, 5‐dione (TAPD). The membrane of TAPD immobilizes a probe DNA on the electrode. The hybridization of the probe with a sequence‐specific DNA in sample solutions is monitored by a self‐synthesized electroactive indicator, which specifically intercalates in the hybrids on the electrode surface. The current signal of the biosensor is proportional to the concentration of the target DNA in samples, and a very low detection limit of 5 × 10^?10 mol/L is found. The biosensor has been used to detect the short oligomers containing of HTV‐1 and mycobacterrium nucleotide sequences.     

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.     

新型"三明治"结构DNA电化学传感器对急性早幼粒细胞白血病相关融合基因的检测

基于急性早幼粒细胞白血病(APL)中PML/RARα融合基因的碱基序列,设计了新型的锁核酸(LNA)修饰寡核苷酸作为捕获探针和信号探针,研究出一种基于"三明治"传感模式的电化学生物传感器对PML/RARα融合相关基因进行检测.靶序列分别与捕获探针和信号探针杂交后形成"三明治"结构.将修饰电极置于含有底物3,3′,5,5′-四甲基联苯胺(TMB)和过氧化氢的测定溶液中,用计时电流法检测靶序列.结果表明,该传感器可定量识别和检测溶液中人工合成的短链APL PML/RARα融合基因片段.经过条件优化,杂交前后电流值与靶标链浓度在1.0×10~(-12) ～2.5×10~(-11) mol/L范围内呈良好的线性关系,检出限为8.5×10~(-13) mol/L.该方法简单、特异性好,有望用于实际样品的检测.     

Identification of glutathione by voltammetric analysis with rolling circle amplification

Glutathione (GSH), a common tripeptide, plays an essential role in a variety of cellular functions. GSH level is reported to be closely related to human health. In this study, we fabricate an ultrasensitive electrochemical biosensor for GSH quantification. DNA probes are firstly modified on the electrode surface and thymine-Hg²⁺-thymine is formed. Since GSH is able to chelate Hg²⁺ from the DNA mismatched sites effectively, which leads to DNA structural switching from hairpin to linear strand, rolling circle amplification (RCA) could be initiated with the released linear primer probe. The RCA product with multiple repeating sequences further captures numerous DNA modified silver nanoparticles (AgNPs) by the hybridization of complementary sequences. Stripping voltammetric responses of AgNPs are then detected to reveal GSH concentration. The linear detection range is from 0.1 pM to 10 nM and the limit of detection is 0.1 pM, which is lower than most current analytical methods. This method is also highly selective and functions well against a series of interferents. Additionally, the proposed method has been successfully utilized in human serum samples, which shows fairly good potential in clinical applications.