Digital readout of target binding with attomole detection limits via enzyme amplification in femtoliter arrays

In this communication, single molecules of beta-galactosidase were captured on a 1 mm femtoliter array using biotin-streptavidin binding. The femtoliter arrays, containing 24 000 individual reaction chambers, permit digital concentration readout as the percentage of reaction vessels that successfully capture a target molecule is correlated to the bulk target concentration. This capture and readout approach should prove useful for DNA and antibody assays that utilize an enzyme label to catalyze the generation of a fluorescent signal.     

Oil-sealed femtoliter fiber-optic arrays for single molecule analysis

This paper describes a novel method for fabricating and sealing high-density arrays of femtoliter reaction chambers. We chemically etch one end of a 2.3 mm diameter glass optical fiber bundle to create an array of microwells. We then use a contact printing method to selectively modify the surface of the material between microwells with a hydrophobic silane. This modification makes it possible to fill the wells with aqueous solution and then seal them with a droplet of oil, forming an array of isolated reaction chambers. Individual β-galactosidase molecules trapped in these reaction chambers convert a substrate into a fluorescent product that can be readily detected because a high local concentration of product is achieved. This binary readout can be used for ultra-sensitive measurements of enzyme concentration. We observed that the percentage of wells showing enzyme activity was linearly dependent on the concentration of soluble β-galactosidase in the picomolar range. A similar response was also observed for streptavidin-β-galactosidase captured by biotinylated beads. These arrays are also suitable for performing single-molecule kinetics studies on hundreds to thousands of enzyme molecules simultaneously. We observed a broad distribution of catalytic rates for individual β-galactosidase molecules trapped in the microwells, in agreement with previous studies using similar arrays that were mechanically sealed. We have further demonstrated that this femtoliter fiber-optic array can be integrated into a PDMS microfluidic channel system and sealed with oil on-chip, creating an easy to use and high-throughput device for single-molecule analysis.     

A novel technology for the detection, enrichment, and separation of trace amounts of target DNA based on amino-modified fluorescent magnetic composite nanoparticles

A novel, highly sensitive technology for the detection, enrichment, and separation of trace amounts of target DNA was developed on the basis of amino-modified fluorescent magnetic composite nanoparticles (AFMN). In this study, the positively charged amino-modified composite nanoparticles conjugate with the negatively charged capture DNA through electrostatic binding. The optimal combination of AFMN and capture DNA was measured by dynamic light scattering (DLS) and UV–vis absorption spectroscopy. The highly sensitive detection of trace amounts of target DNA was achieved through enrichment by means of AFMN. The detection limit for target DNA is 0.4 pM, which could be further improved by using a more powerful magnet. Because of their different melting temperatures, single-base mismatched target DNA could be separated from perfectly complementary target DNA. In addition, the photoluminescence (PL) signals of perfectly complementary target DNA and single-base mismatched DNA as well as the hybridization kinetics of different concentrations of target DNA at different reaction times have also been studied. Most importantly, the detection, enrichment, and separation ability of AFMN was further verified with milk. Simple and satisfactory results were obtained, which show the great potential in the fields of mutation identification and clinical diagnosis.     

Immobilization of DNA onto poly(dimethylsiloxane) surfaces and application to a microelectrochemical enzyme-amplified DNA hybridization assay

This paper describes immobilization of DNA onto the interior walls of poly(dimethylsiloxane) (PDMS) microsystems and its application to an enzyme-amplified electrochemical DNA assay. DNA immobilization was carried out by silanization of the PDMS surface with 3-mercaptopropyltrimethoxysilane to yield a thiol-terminated surface. 5'-acrylamide-modified DNA reacts with the pendant thiol groups to yield DNA-modified PDMS. Surface-immobilized DNA oligos serve as capture probes for target DNA. Biotin-labeled target DNA hybridizes to the PDMS-immobilized capture DNA, and subsequent introduction of alkaline phosphatase (AP) conjugated to streptavidin results in attachment of the enzyme to hybridized DNA. Electrochemical detection of DNA hybridization benefits from enzyme amplification. Specifically, AP converts electroinactive p-aminophenyl phosphate to electroactive p-aminophenol, which is detected using an indium tin oxide interdigitated array (IDA) electrode. The IDA electrode eliminates the need for a reference electrode and provides a steady-state current that is related to the concentration of hybridized DNA. At present, the limit of detection of the DNA target is 1 nM in a volume of 20 nL, which corresponds to 20 attomoles of DNA.     

CE combined with rolling circle amplification for sensitive DNA detection

Here we describe an assay which combines CE with rolling circle amplification (RCA) for sensitive DNA detection and quantification. RCA is an isothermal DNA replication technique that generates a long ssDNA with tandem repeats. It requires simpler temperature control in reaction and offers higher sequence specificity and greater quantitation capability compared to other amplification technologies. In this study, RCA amplified the DNA target via a circular template, and the product was digested into monomers for CE analysis. Less than 2 fmol of the DNA target could easily be detected using this RCA-CE assay and the assay has a dynamic range of two orders of magnitudes. Moreover, simultaneous detection of both the target DNA and the internal standard was achieved by designing two padlock probes with different sizes, which could significantly improve the quantification accuracy. The RCA-CE assay is easy to perform, readily adaptable for detection of multiple targets because of the high resolution power of CE, and is compatible with other applications employing RCA as a signal amplification tool. Additionally, this assay can be used with a capillary array system to perform sensitive, high-throughput genetic screening.     

A Simple and Highly Sensitive Electrochemical Biosensor for microRNA Detection Using Target‐Assisted Isothermal Exponential Amplification Reaction

A simple and highly sensitive electrochemical biosensor for microRNA (miRNA) detection was successfully developed by integrating a target‐assisted isothermal exponential amplification reaction (EXPAR) with enzyme‐amplified electrochemical readout. The binding of target miRNA with the immobilized linear DNA template generated a part duplex and triggered primer extension reaction to form a double‐stranded DNA. Then one of the DNA strands was cleaved by nicking endonuclease and extended again. The short fragments with the same sequence as the target miRNA except for the replacement of uridines and ribonucleotides with thymines and deoxyribonucleotides could be displaced and released. Hybridization of these released DNA fragments with other amplification templates and their extension on the templates led to target exponential amplification. Integrating with enzyme‐amplified electrochemical readout, the electrochemical signal decreases with the increasing target microRNA concentration. The method could detect miRNA down to 98.9 fM with a linear range from 100 fM to 10 nM. The fabrication and binding processes were characterized with cyclic voltammetry and electrochemical impedance spectroscopy. The specificity of the method allowed single‐nucleotide difference between miRNA family members to be discriminated. The established biosensor displayed excellent analytical performance toward miRNA detection and might present a powerful and convenient tool for biomedical research and clinic diagnostic application.     

Simultaneous and multiplex detection of exosomal microRNAs based on the asymmetric Au@Au@Ag probes with enhanced Raman signal

Simultaneous and quantitative detection of multiple exosomal micro RNAs(miRNAs) was successfully performed by a surface-enhanced Raman scattering(SERS) assay consisting of Raman probes and capture probes. In this design, the asymmetric core-shell structured Au@Au@Ag nanoparticles were first synthesized by layer-by-layer self-assembly method and modified with different Raman molecules and recognition sequences(poly A-DNA) to prepare the surface-enhanced Raman probes. Then, the streptavidinmodifie...     

Sensitive fluorescent detection of Staphylococcus aureus using nanogold linked CdTe nanocrystals as signal amplification labels

A sensitive fluorescent assay was developed for the detection of DNA specifically for Staphylococcus aureus. A sandwich-type detection system was fabricated by first immobilizing biotinylated capture DNA on avidin-modified wells of microplates, then hybridizing the capture DNA with one end of the target DNA, and then recognizing the other end of the target DNA with a signal probe labeled with CdTe nanocrystals and gold nanoparticles (Au-NPs) at the 3′- and 5′-terminus, respectively. Hybridization was monitored by measuring the fluorescent intensity of the assembly. The experimental results demonstrated that the incorporation of Au-NPs in this detection system can significantly enhance the sensitivity and the selectivity because a single Au-NP can be loaded with hundreds of signal DNA probe strands modified with CdTe nanocrystals. Under the optimized conditions, a detection limit of 10 fmol of DNA per L can be achieved and at least 50 colony forming units of Staph. aureus per mL of sample can be detected. The method was assessed by analyzing real samples, and it was validated by comparing it to an official standard method.

Quantitative detection of well-based DNA array using switchable lanthanide luminescence

In this report a novel wash-free method for multiplexed DNA detection is demonstrated employing target specific probe pairs and switchable lanthanide luminescence technology on a solid-phase array. Four oligonucleotide capture probes, conjugated at 3′ to non-luminescent lanthanide ion carrier chelate, were immobilized as a small array on the bottom of a microtiter plate well onto which a mix of corresponding detection probes, conjugated at 5′ to a light absorbing antenna ligand, were added. In the presence of complementary target nucleic acid both the spotted capture probe and the liquid-phase detection probe hybridize adjacently on the target. Consequently the two non-luminescent label molecules self-assemble and form a luminescent mixed lanthanide chelate complex. Lanthanide luminescence is thereafter measured without a wash step from the spots by scanning in time-resolved mode. The homogeneous solid-phase array-based method resulted in quantitative detection of synthetic target oligonucleotides with 0.32 nM and 0.60 nM detection limits in a single target and multiplexed assay, respectively, corresponding to 3× SD of the background. Also qualitative detection of PCR-amplified target from Escherichia coli is described.     

An ultra-sensitive DNA assay based on single-molecule detection coupled with hybridization accumulation and its application

An ultra-sensitive assay for quantification of DNA based on single-molecule detection coupled with hybridization accumulation was developed. In this assay, target DNA (tDNA) in solution was accumulated on a silanized substrate blocked with ethanolamine and bovine serum albumin (BSA) through a hybridization reaction between tDNA and capture DNA immobilized on the substrate. The tDNA on the substrate was labeled with quantum dots which had been modified with detection DNA and blocked with BSA. The fluorescence image of single QD-labeled tDNA molecules on the substrate was acquired using total internal reflection fluorescence microscopy. The tDNA was quantified by counting the bright dots on the image from the QDs. The limit of detection of the DNA assay was as low as 6.4 × 10(-18) mol L(-1). Due to the ultra-high sensitivity, the DNA assay was applied to measure the beta-2-microglobulin messenger RNA level in single human breast cancer cells without a need for PCR amplification.     

Amplified electrochemiluminescence detection of nucleic acids by hairpin probe-based isothermal amplification

Here, we present a straightforward method for isothermal amplified detection of nucleic acids. In this proof-of-concept study, a specific DNA sequence is amplified through hairpin probe-based isothermal strand-displacement polymerization reaction and then detected via a sensitive and commercially available ECL detection platform. Results show that the DNA sequence derived from the Listeria monocytogenes hly gene can be detected down to 10 pM in solution, together with correlation of the detected signal with the initial concentration of target DNA. Moreover, the designed stem-loop structured hairpin probe shows single-base variation differentiating ability. Considering the superior sensitivity and specificity, as well as the simple-to-implement features, the developed assay demonstrates a great potential of becoming a first-line tool for quantitative analysis of nucleic acids for biomedical research.     

基于G-四链体-血红素和链式放大反应的基因检测传感器的构建

该文以特殊设计的DNA序列为捕获探针,以G-四链体-血红素复合物作为信号分子,利用链式反应实现目标DNA的灵敏检测。在目标DNA存在时,捕获探针与目标DNA相互识别,同时目标DNA能与辅助探针发生连续的链式反应,从而在电极表面引入大量G-四链体结构。血红素存在下,G-四链体可与血红素结合形成具有很强电化学信号的G-四链体-血红素复合物。用差分脉冲伏安法(DPV)扫描得到的电化学信号与体系中的目标DNA浓度存在对应关系,从而实现对目标DNA的检测。在各组分浓度最适的情况下,电流响应值与目标DNA浓度在0.01～10 pmol/L内具有良好的线性关系,检出限可达8 fmol/L。该传感器灵敏度高、特异性好,具有良好的应用前景。     

新型超支状液晶核酸传感器用于p53突变基因的检测

基于核酸杂交链式反应影响液晶取向的原理, 构建了一种新型的超支状液晶核酸传感器用于检测p53突变基因. 本文突破传统构建超支状分子的方式, 采用杂交链式反应方法, 以目标序列p53突变基因作为引发剂, 3种不同的发卡探针Hairpin A, Hairpin B和Hairpin C为单体, 在温和的条件下, 通过改变单体的浓度和反应时间自发杂交组装形成尺寸和分子量可控的超支状DNA(branched-like DNA, bDNA). 借助捕获探针将该超支状DNA连接到液晶传感基底表面, 观察液晶分子取向改变前后的光学信号, 实现了p53基因含249密码子突变序列的快速检测. 本方法有望为核酸诊断的发展提供一种新的方法和思路.     

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.     

Highly sensitive detection of microRNA by chemiluminescence based on enzymatic polymerization

We have developed a new methodology for miRNA assay using chemiluminescence imaging by poly(U) polymerase catalyzed miRNA polymerization. This method is very sensitive with a 50 fM limit of detection, which is comparable to or better than current assay methods. Multiplex detection for miRNA can be easily realized by introducing different capture probes onto the biosensor array, which will make it highly versatile for various research purposes.     

DNA analysis by application of Pt nanoparticle electrochemical amplification with single label response

This study demonstrates a highly sensitive sensing scheme for the detection of low concentrations of DNA, in principle down to the single biomolecule level. The previously developed technique of electrochemical current amplification for detection of single nanoparticle (NP) collisions at an ultramicroelectrode (UME) has been employed to determine DNA. The Pt NP/Au UME/hydrazine oxidation reaction was employed, and individual NP collision events were monitored. The Pt NP was modified with a 20-base oligonucleotide with a C6 spacer thiol (detection probe), and the Au UME was modified with a 16-base oligonucleotide with a C6 spacer thiol (capture probe). The presence of a target oligonucleotide (31 base) that hybridized with both capture and detection probes brought a Pt NP on the electrode surface, where the resulting electrochemical oxidation of hydrazine resulted in a current response.     

Electrochemical biosensors for detection of point mutation based on surface ligation reaction and oligonucleotides modified gold nanoparticles

An electrochemical method for point mutation detection based on surface ligation reaction and oligonucleotides (ODNs) modified gold nanoparticles (AuNPs) was demonstrated. Point mutation identification was achieved using Escherichia coli DNA ligase. This system for point mutation detection relied on a sandwich assay comprising capture ODN immobilized on Au electrodes, target ODN and ligation ODN. Because of the sequence-specific surface reactions of E. coli DNA ligase, the ligation ODN covalently linked to the capture ODN only in the presence of a perfectly complementary target ODN. The presence of ligation products on Au electrode was detected using chronocoulometry through hybridization with reporter ODN modified AuNPs. The use of AuNPs improved the sensitivity of chronocoulometry in this approach, a detection limit of 0.9 pM complementary ODN was obtained. For single base mismatched ODN (smODN), a negligible signal was observed. Even if the concentration ratio of complementary ODN to smODN was decreased to 1:1000, a detectable signal was observed. This work may provide a specific, sensitive and cost-efficient approach for point mutant detection.     

Structure-specific DNA cleavage on surfaces

The structure-specific invasive cleavage reaction is a useful means for sensitive and specific detection of single nucleotide polymorphisms, or SNPs, directly from genomic DNA without a need for prior target amplification. A new approach integrating this invasive cleavage assay and surface DNA array technology has been developed for potentially large-scale SNP scoring in a parallel format. Two surface invasive cleavage reaction strategies were designed and implemented for a model SNP system in codon 158 of the human ApoE gene. The upstream oligonucleotide, which is required for the invasive cleavage reaction, is either co-immobilized on the surface along with the probe oligonucleotide or alternatively added in solution. The ability of this approach to unambiguously discriminate a single base difference was demonstrated using PCR-amplified human genomic DNA. A theoretical model relating the surface fluorescence intensity to the progress of the invasive cleavage reaction was developed and agreed well with experimental results.     

Aptamer-based homogeneous protein detection using cucurbit[7]uril functionalized electrode

A new strategy for homogeneous protein detection is developed based on a cucurbit[7]uril (CB[7]) functionalized electrode. The analytical procedure consists of the binding of target protein to its aptamer in the test solution, followed by an exonuclease-catalyzed digestion of methylene blue (MB) tag labeled DNA oligonucleotides. Since CB[7] molecules immobilized on the electrode may efficiently capture the released MB-labeled nucleotides, the MB tags are concentrated to the electrode surface and subsequently yield highly sensitive electrochemical signal, which is related to the concentration of the target protein. The method combines the host–guest properties of CB[7] with the immobilization-free homogeneous assay, providing a powerful tool for protein detection. Taking the detection of osteopontin as an example, the proposed method can have a linear response to the target protein in a range from 50 to 500 ng mL⁻¹ with a detection limit of 10.7 ng mL⁻¹. It can also show high specificity and good reproducibility, and can be used directly for the assay of osteopontin in serum samples.     

DNA-arrays with electrical detection: a label-free low cost technology for routine use in life sciences and diagnostics

Fast and highly parallel DNA analysis are essential for improved biomedical research and development. Currently fluorescence-based methods are state of the art in DNA microarray analysis. The necessity to modify the target DNA with labels is costly, laborious and requires skilled personnel. Moreover, false positive calls from unspecific adsorption are possible and it is difficult to discriminate perfect matching target sequences from those with a single mismatch. In this paper a new and simple electrochemical approach for hybridisation detection without the need of labelling the target DNA is described. The EDDA (Electrically Detected Displacement Assay) method uses a solution of short redox-labelled signalling oligonucleotides (oligonucleotides carrying a covalently attached redox active compound like ferrocene) to characterize the hybridisation state of label-free capture probe DNA immobilised on gold electrodes. The number of capture probes associated with signalling oligonucleotides is determined by chronocoulometry. This technique allows to separate the electrochemical response of capture probe associated signal probes from the response of freely diffusing signalling probes. In the absence of the complementary target sequences the redox-labelled signalling probes at the surface give rise to an instantaneous increase of the detection signal, while freely diffusing signalling probes show a significantly delayed response. Hybridisation with targets complementary to the capture probe displace the loosely associated signalling probes thereby decreasing the instantaneous signal. Besides an introduction to the EDDA technology, data validating the method for biological material will be presented and an outlook to the detection of single nucleotide polymorphisms (SNPs) is given.