Colorimetric silver detection of DNA microarrays

Development of an Innovative Colorimetric DNA Biosensor Based on Sugar Measurement

The development of biosensors for target detection plays a crucial role in advancing various fields of bioscience. This work presents the development of a genosensor that exploits the colorimetric phenol-sulfuric acid sugar reaction for the detection of DNA, and RNA as specific targets, and DNA intercalator molecules. The biosensor combines simplicity and reliability to create a novel bioassay for accurate and rapid analysis. A 96-well microplate based on a polystyrene polymer was used as the platform for an unmodified capture DNA immobilization via a silanization process and with (3-Aminopropyl) triethoxysilane (APTES). After that, a hybridization step was carried out to catch the target molecule, followed by adding phenol and sulfuric acid to quantify the amount of DNA or RNA sugar backbone. This reaction generated a yellow-orange color on the wells measured at 490 nm, which was proportional to the target concentration. Under the optimum conditions, a calibration curve was obtained for each target. The developed biosensor demonstrated high sensitivity, good selectivity, and linear response over a wide concentration range for DNA and RNA targets. Additionally, the biosensor was successfully employed for the detection of DNA intercalator agents that inhibited the hybridization of DNA complementary to the immobilized capture DNA. The developed biosensor offers a potential tool for sensitive and selective detection in various applications, including virus diagnosis, genetic analysis, pathogenic bacteria monitoring, and drug discovery.

Scanometric Detection of Tomato Leaf Curl New Delhi Viral DNA Using Mono- and Bifunctional AuNP-Conjugated Oligonucleotide Probes

Scanometric detection of tomato leaf curl New Delhi viral DNA using AuNP-conjugated mono- and bifunctional oligo probes through direct DNA hybridization assay (DDH assay) and sandwich DNA hybridization assay (SDH assay) with silver enhancement was developed. Tomato leaf curl New Delhi virus (ToLCNDV) coat protein gene-specific thiol-modified ssoligo probes were used for the preparation of mono- and bifunctional AuNP-ssoligo probe conjugates (signal probes). ssDNA arrays were prepared using polymerase chain reaction (PCR), rolling circle amplification (RCA), genomic DNAs fragments, and phosphate-modified positive control/capture probes through 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide/1-methylimidazole conjugation on the amine-modified glass slide (GS) surface. In the DDH assay, signal probes were directly hybridized with ssDNA array of positive control and ToLCNDV DNA samples and the detection signals were amplified by silver enhancement. Dark black/gray colors were developed on the GS by the result of Ag enhancement, which can be visualized and discriminated by the naked eye. The images were captured using a simple flatbed scanner, and the determined amounts of signal probes were hybridized with their target DNA. Similarly, the SDH assay also performed through two rounds of hybridization between capture probes and target DNA; target DNA and signal probes followed by silver enhancement. The detection signals were found higher in the PCR sample than the RCA and genomic DNA samples because of the presence of increased copy numbers of complementary DNAs in PCR samples. Further, bifunctional AuNP-ssoligo probe shows higher intensity of detection signal than monofunctional probes because it can be hybridized with both strands of dsDNA targets. Moreover, the DDH-based scanometric method showed higher detection sensitivity than the SDH assay-based scanometric method. Overall, bifunctional signal probes showed more detection sensitivity than monofunctional probes in scanometric methods based on both DDH and SDH assays. The limit of detection of this developed scanometric method was optimized (100 zM to 100 pM concentration). Further, DDH assay-based scanometric method shows significant advantages over the SDH assay method, such as cost-effectiveness, because it requires only single probes (signal probes), less time-consuming by the need of only single-step hybridization, and higher detection sensitivity (up to zM). To the best of our knowledge, this is the first attempt made to develop a scanometric-based nanoassay method for the detection of plant viral DNA. This approach will be a remarkable milestone for the application of nanotechnology in the development of nanobiosensor for plant pathogen detection.

Selective covalent capture of a DNA sequence corresponding to a cancer-driving C>G mutation in theKRASgene by a chemically reactive probe: optimizing a cross-linking reaction with non-canonical duplex structures

A covalent cross-linking reaction used for selective capture of a disease-relevant DNA sequence.

Sequence-Specific Covalent Capture Coupled with High-Contrast Nanopore Detection of a Disease-Derived Nucleic Acid Sequence

Hybridization-based methods for the detection of nucleic acid sequences are important in research and medicine. Short probes provide sequence specificity, but do not always provide a durable signal. Sequence-specific covalent crosslink formation can anchor probes to target DNA and might also provide an additional layer of target selectivity. Here, we developed a new crosslinking reaction for the covalent capture of specific nucleic acid sequences. This process involved reaction of an abasic (Ap) site in a probe strand with an adenine residue in the target strand and was used for the detection of a disease-relevant T→A mutation at position 1799 of the human BRAF kinase gene sequence. Ap-containing probes were easily prepared and displayed excellent specificity for the mutant sequence under isothermal assay conditions. It was further shown that nanopore technology provides a high contrast-in essence, digital-signal that enables sensitive, single-molecule sensing of the cross-linked duplexes.

Smartphone-Enabled Colorimetric Trinitrotoluene Detection Using Amine-Trapped Polydimethylsiloxane Membranes

A smartphone-enabled platform for easy and portably colorimetric analysis of 2,4,6-trinitrotoluene (TNT) using amine-trapped PDMS is designed and implemented. The amine-trapped polydimethylsiloxane (PDMS) is simply prepared by immersing the cured PDMS in aminosilane solutions forming an amine-containing polymer. After contacting with TNT-containing solutions, the colorless PDMS showed a rapid colorimetric change which can be easily identified by the naked eye. The amine-trapped PDMS was carefully optimized to achieve visible detection of TNT at concentrations as low as 1 μM. Using an integrated camera in the smartphone, pictures of colored PDMS membranes can be analyzed by a home-developed mobile application. Thus, the TNT amount can be precisely quantified. Direct TNT detection in real samples (e.g., drinking, tap, and lake waters) is demonstrated as well. The smartphone-enabled colorimetric method using amine-trapped PDMS membranes realizes a convenient and efficient approach toward a portable system for field TNT detections.

Diagnostic microarray for 14 water and foodborne pathogens using a flatbed scanner

Parallel detection approaches are of interest to many researchers interested in identifying multiple water and foodborne pathogens simultaneously. Availability and cost-effectiveness are two key factors determining the usefulness of such approaches for laboratories with limited resources. In this study, we developed and validated a high-density microarray for simultaneous screening of 14 bacterial pathogens using an approach that employs gold labeling with silver enhancement (GLS) protocol. In total, 8887 probes (50-mer) were designed using an in-house database of virulence and marker genes (VMGs), and synthesized in quadruplicate on glass slides using an in-situ synthesis technology. Target VMG amplicons were obtained using multiplex polymerase chain reaction (PCR), labeled with biotin, and hybridized to the microarray. The signals generated after gold deposition and silver enhancement, were quantified using a flatbed scanner having 2-μm resolution. Data analysis indicated that reliable presence/absence calls could be made, if: i) over four probes were used per gene, ii) the signal-to-noise ratio (SNR) cutoff was greater than or equal to two, and iii) the positive fraction (PF), i.e., number of probes with SNR≥2 for a given VMG was greater than 0.75. Hybridization of the array with blind samples resulted in 100% correct calls, and no false positive. Because amplicons were obtained by multiplex PCR, sensitivity of this method is similar to PCR. This assay is an inexpensive and reliable technique for high throughput screening of multiple pathogens.

Evolution of High-Sensitivity Microarray Technology

Microarray technology is a multiplex analytical technique for the detection of many different analytes in a mixture of biomolecules. The detection limits for each of the analytes for which the array is designed depend on a multiplicity of reaction parameters, the array itself, and profoundly on the label and detection technology employed. Significant improvements in assay sensitivity have been achieved by optimizing all steps that affect the generation of signal and noise. Nanoparticle technology brings a new dimension to this technology by providing not only higher sensitivity but also improved specificity for hybridization-based microarray assay systems.

A scanometric antibody probe for facile and sensitive immunoassays

We have developed a novel scanometric antibody probe for rapid, sensitive, and naked-eye-visible immunoassays. Using this probe, we clearly demonstrated the successful scanometric detection and identification of influenza A viruses on a microarray. In addition, the sensitivity of the scanometric immunoassay was comparable to that of the fluorescence-based method.

Multiplex in vitro detection using SERS

This review focuses on the recent advances in SERS and its potential to detect multiple biomolecules in clinical samples.

Viral nanoparticles, noble metal decorated viruses and their nanoconjugates

Virus-based nanotechnology has generated interest in a number of applications due to the specificity of virus interaction with inorganic and organic nanoparticles. A well-defined structure of virus due to its multifunctional proteinaceous shell (capsid) surrounding genomic material is a promising approach to obtain nanostructured materials. Viruses hold great promise in assembling and interconnecting novel nanosized components, allowing to develop organized nanoparticle assemblies. Due to their size, monodispersity, and variety of chemical groups available for modification, they make a good scaffold for molecular assembly into nanoscale devices. Virus based nanocomposites are useful as an engineering material for the construction of smart nanoobjects because of their ability to associate into desired structures including a number of morphologies. Viruses exhibit the characteristics of an ideal template for the formation of nanoconjugates with noble metal nanoparticles. These bioinspired systems form monodispersed units that are highly amenable through genetic and chemical modifications. As nanoscale assemblies, viruses have sophisticated yet highly ordered structural features, which, in many cases, have been carefully characterized by modern structural biological methods. Plant viruses are increasingly being used for nanobiotechnology purposes because of their relative structural and chemical stability, ease of production, multifunctionality and lack of toxicity and pathogenicity in animals or humans. The multifunctional viruses interact with nanoparticles and other functional additives to the generation of bioconjugates with different properties – possible antiviral and antibacterial activities.

DNA molecular beacon-based plastic biochip: a versatile and sensitive scanometric detection platform

In this paper, we report a novel DNA molecular beacon (MB)-based plastic biochip platform for scanometric detection of a range of analytical targets. Hairpin DNA strands, which are dually modified with amino and biotin groups at their two ends are immobilized on a disposable plastic (polycarbonate) substrate as recognition element and gold nanoparticle-assisted silver-staining as signal reading protocol. Initially, the immobilized DNA probes are in their folded forms; upon target binding the hairpin secondary structure of the probe strand is "forced" open (i.e., converted to the unfolded state). Nanogold-streptavidin conjugates can then bind the terminal biotin groups and promote the deposition of rather large silver particles which can be either directly visualized or quantified with a standard flatbed scanner. We demonstrate that with properly designed probe sequences and optimized preparation conditions, a range of molecular targets, such as DNA strands, proteins (thrombin) and heavy metal ions (Hg(2+)), can be detected with high sensitivity and excellent selectivity. The detection can be done in both standard physiological buffers and real world samples. This constitutes a platform technology for performing rapid, sensitive, cost-effective, and point-of-care (POC) chemical analysis and medical diagnosis.

Transmissive Nanohole Arrays for Massively-Parallel Optical Biosensing

A high-throughput optical biosensing technique is proposed and demonstrated. This hybrid technique combines optical transmission of nanoholes with colorimetric silver staining. The size and spacing of the nanoholes are chosen so that individual nanoholes can be independently resolved in massive parallel using an ordinary transmission optical microscope, and, in place of determining a spectral shift, the brightness of each nanohole is recorded to greatly simplify the readout. Each nanohole then acts as an independent sensor, and the blocking of nanohole optical transmission by enzymatic silver staining defines the specific detection of a biological agent. Nearly 10000 nanoholes can be simultaneously monitored under the field of view of a typical microscope. As an initial proof of concept, biotinylated lysozyme (biotin-HEL) was used as a model analyte, giving a detection limit as low as 0.1 ng/mL.

Aptamer-functionalized silver nanoparticles for scanometric detection of platelet-derived growth factor-BB

In this work, we reported a scanometric assay system based on the aptamer-functionalized silver nanoparticles (apt-AgNPs) for detection of platelet-derived growth factor-BB (PDGF-BB) protein. The aptamer and ssDNA were bound with silver nanoparticles by self-assembly of sulfhydryl group at 5' end to form the apt-AgNPs probe. The apt-AgNPs probe can catalyze the reduction of metallic ions in color agent to generate metal deposition that can be captured both by human eyes and a flatbed scanner. Two different color agents, silver enhancer solution and color agent 1 (10 mM HAuCl4+2 mM hydroquinone) were used to develop silver and gold shell on the surface of AgNPs separately. The results demonstrated that the formation of Ag core-Au shell structure had some advantages especially in the low concentrations. The apt-AgNPs probe coupled with color agent 1 showed remarkable superiority in both sensitivity and detection limit compared to the apt-AuNPs system. The apt-AgNPs system also produced a wider linear range from 1.56 ng mL(-1) to 100 ng mL(-1) for PDGF-BB with the detection limit lower than 1.56 ng mL(-1). The present strategy was applied to the determination of PDGF-BB in 10% serum, and the results showed that it had good specificity in complex biological media.

[The second generation universal oligonucleotide microarray for subtyping of influenza virus A]

The microchip for influenza A subtyping was developed, functioning on a principle "one spot--one subtype". Each spot contains the set of oligonucleotide probes, specific for a particular subtype of hemagglutinin, neuraminidase or matrix gene. Reliability of the proposed chip version is the same as for earlier created in our group full-size microchip for separate hemagglutinin and neuraminidase subtyping. To visualize the image, analyzed DNA can be labeled by either fluorescent dye or biotin with the further fixation in system streptavidin-gold nanoparticles and image development by silver precipitation. In the second case common version of scanner can be used for the image analysis, that essentially simplifies procedure of influenza A subtyping.

Dynamic pH mapping in microfluidic devices by integrating adaptive coatings based on polyaniline with colorimetric imaging techniques

In this paper we present a microfluidic device that has integrated pH optical sensing capabilities based on polyaniline. The optical properties of polyaniline coatings change in response to the pH of the solution that is flushed inside the microchannel offering the possibility of monitoring pH in continuous flow over a wide pH range throughout the entire channel length. This work also features an innovative detection system for spatial localisation of chemical pH gradients along microfluidic channels through the use of a low cost optical device. Specifically, the use of a microfluidic channel coated with polyaniline is shown to respond colorimetrically to pH and that effect is detected by the detection system, even when pH gradients are induced within the channel. This study explores the capability of detecting this gradient by means of imaging techniques and the mapping of the camera's response to its corresponding pH after a successful calibration process. The provision of an inherently responsive channel means that changes in the pH of a sample moving through the system can be detected dynamically using digital imaging along the entire channel length in real time, without the need to add reagents to the sample. This approach is generic and can be applied to other chemically responsive coatings immobilised on microchannels.

Reading disc-based bioassays with standard computer drives

Traditional methods of disease diagnosis are both time-consuming and labor-intensive, and many tests require expensive instrumentation and trained professionals, which restricts their use to biomedical laboratories. Because patients can wait several days (even weeks) for the results, the consequences of delayed treatment could be disastrous. Therefore, affordable and simple point-of-care (POC) biosensor devices could fill a diagnostic niche in the clinic or even at home, as personal glucose meters do for diabetics. These devices would allow patients to check their own health conditions and enable physicians to make prompt treatment decisions, which could improve the chances for rapid recovery and cure. Compact discs (CDs) provide inexpensive substrate materials for the preparation of microarray biochips, and conventional computer drives/disc players can be adapted as precise optical reading devices for signal processing. Researchers can employ the polycarbonate (PC) base of a CD as an alternative substrate to glass slides or silicon wafers for the preparation of microanalytical devices. Using the characteristic optical phenomena occurring on the metal layer of a CD, researchers can develop biosensors based on advanced spectroscopic readout (interferometry or surface plasmon resonance). If researchers integrate microfluidic functions with CD mechanics, they can control fluid transfer through the spinning motion of the disc, leading to "lab-on-a-CD" devices. Over the last decade, our laboratory has focused on the construction of POC biosensor devices from off-the-shelf CDs or DVDs and standard computer drives. Besides the initial studies of the suitability of CDs for surface and materials chemistry research (fabrication of self-assembled monolayers and oxide nanostructures), we have demonstrated that an ordinary optical drive, without modification of either the hardware or the software driver, can function as the signal transducing element for reading disc-based bioassays quantitatively. In this Account, we first provide a brief introduction to CD-related materials chemistry and microfluidics research. Then we describe the mild chemistry developed in our laboratory for the preparation of computer-readable biomolecular screening assays: photochemical activation of the polycarbonate (PC) disc surface and immobilization and delivery of probe and target biomolecules. We thoroughly discuss the analysis of the molecular recognition events: researchers can "read" these devices quantitatively with an unmodified optical drive of any personal computer. Finally, and critically, we illustrate our digitized molecular diagnosis approach with three trial systems: DNA hybridization, antibody-antigen binding, and ultrasensitive lead detection with a DNAzyme assay. These examples demonstrate the broad potential of this new analytical/diagnostic tool for medical screening, on-site food/water safety testing, and remote environmental monitoring.

Microfluidic systems for diagnostic applications: a review

Because of intensive developments in recent years, the microfluidic system has become a powerful tool for biological analysis. Entire analytic protocols including sample pretreatment, sample/reagent manipulation, separation, reaction, and detection can be integrated into a single chip platform. A lot of demonstrations on the diagnostic applications related to genes, proteins, and cells have been reported because of their advantages associated with miniaturization, automation, sensitivity, and specificity. The aim of this article is to review recent developments in microfluidic systems for diagnostic applications. Based on the categories of various fluid-manipulating mechanisms and biological detection approaches, in-depth discussion of the microfluidic-based diagnostic systems is provided. Moreover, a brief discussion on materials and manufacturing techniques will be included. The current excellent integration of microfluidic systems and diagnostic applications suggests a solid foundation for the development of practical point-of-care devices.

Options available for labelling nucleic acid samples in DNA microarray-based detection methods

DNA microarrays are considered by many researchers to be the platform of choice for the high-throughput analysis of nucleic acids. Since the past two decades, they have been used constantly as powerful tools in differential gene expression, SNP genotyping, DNA sequencing, gene discovery, disease diagnostic and pathways reconstruction. Several methods have been developed to enable samples of limited amounts of RNA to be quantified. Here we evaluate classical and up-to-date assays made available for labelling those samples. This review also sheds light on the recently developed strategies that ensure high sensitivity such as sample and signal amplification, quantum dot, surface plasmom resonance, nanoparticles and cationinc polythiophenes.

Development of a PCR/ligase detection reaction/nanogold-based universal array approach for the detection of low-abundant DNA point mutations

The aim of this study was to investigate the feasibility of combining PCR and ligase detection reaction (LDR) with a novel nano-gold-based universal array for the detection of low abundance point mutations from fetal DNA in maternal plasma samples. The sequence with the target point mutation was first amplified by PCR and then used as a template for LDR in which the upstream specific primer contains a tag sequence at the 5'-end. After hybridization to the probes of a universal array containing anti-tag sequences, the ligated products were bound to streptavidin-labeled nano-gold particles and the hybridization signals were amplified by silver staining. The PCR/LDR/universal array was first tested for sensitivity with nano-gold-based detection, and then this system was applied to detect the low abundance specific mutation IVS2 654(C→T) of the β-globin gene in a model using maternal plasma samples. The nano-gold-based method unambiguously identified a single mutation at a sensitivity of 1:1000. This approach was applied to detect the paternally inherited IVS2 654(C→T) mutation from thirty maternal plasma samples. The results were consistent with those obtained by PCR/reverse dot blot of amniotic fluid cell DNA. The PCR/LDR/nano-gold-based universal array is able to detect low-abundance point mutations with high sensitivity.

A simple method based on the application of a CCD camera as a sensor to detect low concentrations of barium sulfate in suspension

The development of a simple, rapid and low cost method based on video image analysis and aimed at the detection of low concentrations of precipitated barium sulfate is described. The proposed system is basically composed of a webcam with a CCD sensor and a conventional dichroic lamp. For this purpose, software for processing and analyzing the digital images based on the RGB (Red, Green and Blue) color system was developed. The proposed method had shown very good repeatability and linearity and also presented higher sensitivity than the standard turbidimetric method. The developed method is presented as a simple alternative for future applications in the study of precipitations of inorganic salts and also for detecting the crystallization of organic compounds.

A visible light-induced photocatalytic silver enhancement reaction for gravimetric biosensors

We have developed a novel microgravimetric immunosensor using a WO(3) nanoparticle-modified immunoassay and a silver enhancement reaction. When the nanoparticles in silver ion solution (i.e.  AgNO(3)) are exposed to visible light, the silver ions are photocatalytically reduced and form a metallic silver coating on the nanoparticles. This silver coating consequently induces changes in the mass and light absorption spectrum. Although photocatalytic reduction reactions can be achieved using ultraviolet (UV) light and TiO(2) nanoparticles as described in our previous publication (Seo et al 2010 Nanotechnology 21 505502), the use of UV light in biosensing applications has drawbacks in that UV light can damage proteins. In addition, conventional quartz crystal substrates must be passivated to prevent undesirable silver ion reduction on their gold-coated sensing surfaces. We addressed these problems by adopting a visible light-induced photocatalytic silver enhancement method using WO(3) nanoparticles and lateral field excited (LFE) quartz crystals. As a proof-of-concept demonstration of the technique, streptavidin was adsorbed onto an LFE quartz crystal, and its mass was enhanced with biotinylated WO(3) nanoparticles, this being followed by a photocatalytic silver enhancement reaction. The mass change due to the enhancement was found to be > 30 times greater than the mass change obtained with the streptavidin alone.

Validation of a mobile phone-assisted microarray decoding platform for signal-enhanced mutation detection

We have established a mobile phone-assisted microarray decoding platform for signal-enhanced mutation detection. A large amount of single-stranded DNA (ssDNA) was obtained by combining symmetric PCR and magnetic isolation, and ssDNA prepared with magnetic bead as label was further allowed to hybridize against the tag-array for decoding purpose. High sensitivity and specificity was achieved with the detection of genomic DNA. When simultaneously genotyping nine common mutations associated with hereditary hearing loss, the detection limit of 1 ng genomic DNA was achieved. Significantly, a mobile phone was also used to record and decode the genotyping results through a custom-designed imaging adaptor and a dedicated mobile phone software. A total of 51 buccal swabs from patients probably with deafness-related mutations were collected and analyzed. The genotyping results were all confirmed by fluorescence-based laser confocal scanning and direct DNA sequencing. This mobile phone-assisted decoding platform provides an effective but economic mutation detection alternative for the future quicker and sensitive detection of virtually any mutation-related diseases in developing and underdeveloped countries.

Nanoparticle probes and mid-infrared chemical imaging for DNA microarray detection

To date most mid-infrared spectroscopic studies have been limited, due to lack of sensitivity, to the structural characterization of a single oligonucleotide probe immobilized over the entire surface of a gold-coated slide or other infrared substrate. By contrast, widely used and commercially available glass slides and a microarray spotter that prints approximately 120-μm-diameter DNA spots were employed in the present work. To our knowledge, mid-infrared chemical imaging (IRCI) in the external reflection mode has been applied in the present study for the first time to the detection of nanostructure-based DNA microarrays spotted on glass slides. Alkyl amine-modified oligonucleotide probes were immobilized on glass slides that had been prefunctionalized with succinimidyl ester groups. This molecular fluorophore-free method entailed the binding of gold-nanoparticle-streptavidin conjugates to biotinylated DNA targets. Hybridization was visualized by the silver enhancement of gold nanoparticles. The adlayer of silver, selectively bound only to hybridized spots in a microarray, formed the external reflective infrared substrate that was necessary for the detection of DNA hybridization by IRCI in the present proof-of-concept study. IRCI made it possible to discriminate between diffuse and specular external reflection modes. The promising qualitative results are presented herein, and the implications for quantitative determination of DNA microarrays are discussed.

Label-free and naked eye detection of PNA/DNA hybridization using enhancement of gold nanoparticles

Utilizing a gold enhancement process after inducing electrostatic interaction between positively charged gold nanoparticles and negatively charged target DNA hybridized to neutral PNA capture probes, a new method for label-free detection of DNA was developed and successfully applied to detect H5-type DNA.

Rapid and simultaneous detection of Ureaplasma parvum and Chlamydia trachomatis antibodies based on visual protein microarray using gold nanoparticles and silver enhancement

Based on gold-labeled silver stain (GLSS) method, we developed the visual protein microarray for simultaneous, sensitive, and specific detection of Ureaplasma parvum and Chlamydia trachomatis using N-terminus multiple-banded antigen (NMBA) of U. parvum and major outer membrane protein of C. trachomatis. The specific antigens were immobilized on glass surface that was treated with 3-glycidoxypropyltrimethoxysilane, and they were used as the capturing probes to recognize the complementary target antibodies binding to the detecting probes of Nano-gold-Staphylococcal protein A (SPA). In the "sandwich" format, Nano-gold-SPA probe was used as an indicator and GLSS was applied to amplify the detection signals and produce black image on array spots, which were visible with naked eyes. In our model arrays, the detection limit of protein microarray was as low as 2 ng/mL, and the lowest titer of detectable antibody was 1:128; thus, this sensitivity was comparable to the fluorescent detection method. The visual simultaneous protein microarrays were used to detect total 186 clinical samples, which had been determined by enzyme-linked immunosorbent assay (ELISA) and fluorescence quantitative real-time polymerase chain reaction; the results were identical and no distinct difference (P > 0.05) existed between them. Our results demonstrate that we have developed the visual protein microarray technique, which is of high sensitivity and high specificity, and it may have potential in clinical applications.

Peptide microarrays on coated silicon slides for highly sensitive antibody detection

Peptides, with their well-established chemistry and fully automated synthesis, provide an invaluable tool for the screening of protein ligands, for epitope mapping, and for antibody diagnostics on the microarray format.The method described in this chapter shows that the sensitivity of a peptide-based microimmunoassay is greatly improved by using a new, specifically developed substrate made of silicon coated by an optimized layer of silicon oxide. A set of six peptides corresponding to the sequences of human and rat acetylcholine receptor subunits was immobilized on glass and silicon slides coated by a copolymer of N,N-dimethylacrylamide, N-acryloyloxysuccinimide, and 3-(trimethoxysilyl) propyl methacrylate, copoly(DMA-NAS-MAPS). The spotted probes were incubated with rabbit anti-sera and with purified antibodies raised against the corresponding peptides. The coated silicon slides, in comparison against the glass substrates, showed a five- to tenfold enhancement of the fluorescence signals, leading to the specific detection of the full set of antibodies down to a concentration of 0.5-1 ng/mL in serum. The sensitivity provided by the test allows its use for the diagnosis of antibodies in clinical samples.

High sensitivity protein assays on microarray silicon slides

In this work, we report on the improvement of microarray sensitivity provided by a crystalline silicon substrate coated with thermal silicon oxide functionalized by a polymeric coating. The improvement is intended for experimental procedures and instrumentations typically involved in microarray technology, such as fluorescence labeling and a confocal laser scanning apparatus. The optimized layer of thermally grown silicon oxide (SiO(2)) of a highly reproducible thickness, low roughness, and fluorescence background provides fluorescence intensification due to the constructive interference between the incident and reflected waves of the fluorescence radiation. The oxide surface is coated by a copolymer of N,N-dimethylacrylamide, N-acryloyloxysuccinimide, and 3-(trimethoxysilyl)propyl methacrylate, copoly(DMA-NAS-MAPS), which forms, by a simple and robust procedure, a functional nanometric film. The polymeric coating with a thickness that does not appreciably alter the optical properties of the silicon oxide confers to the slides optimal binding specificity leading to a high signal-to-noise ratio. The present work aims to demonstrate the great potential that exists by combining an optimized reflective substrate with a high performance surface chemistry. Moreover, the techniques chosen for both the substrate and surface chemistry are simple, inexpensive, and amenable to mass production. The present application highlights their potential use for diagnostic applications of real clinical relevance. The coated silicon slides, tested in protein and peptide microarrays for detection of specific antibodies, lead to a 5-10-fold enhancement of the fluorescence signals in comparison to glass slides.

Visual DNA microarrays for simultaneous detection of human immunodeficiency virus type-1 and Treponema pallidum coupled with multiplex asymmetric polymerase chain reaction

Based on gold label silver stain and coupled with multiplex asymmetric polymerase chain reaction (PCR) analysis, we developed the visual DNA microarray for simultaneous, sensitive, and specific detection of human immunodeficiency virus type-1 (HIV-1) and Treponema pallidum. The 5'-end amino-modified oligonucleotides were immobilized on glass surface, which were used as the capturing probes to bind the complement biotinylated target DNA. The gold-conjugated streptavidins were introduced to the microarray for specific binding to biotin. The black image of microarray spots, which were the result from the precipitation of silver onto nanogold particles and bound to streptavidins, was visualized and accounted as the detection of biotinylated target DNA. Multiplex asymmetric PCR products of HIV-1 and T. pallidum and Bacillus subtilis (used as positive control) were performed for preparing the abundant biotinylated single-stranded target DNA of which could affect detection efficiency and sensitivity of hybridization on microarray. One hundred sixty-nine clinical samples of HIV-1 and T. pallidum from infected patients were tested using the homemade DNA microarrays. The results were identical to those shown in the assays of ELISA and fluorescence quantitative real-time PCR. Our results demonstrate that we have developed the visual gene detection technique, which is of high sensitivity and specificity; it may have potential in clinical applications.

Efficiency and specificity of microRNA-primed nucleotide analog incorporation by various DNA polymerases

MicroRNAs (miRNAs) as endogenous regulators of gene expression have spurred a surge of interest for their quantification and expression analysis. High-sensitivity and high-specificity miRNA detection techniques, such as real-time polymerase chain reaction and recently introduced bioluminescent miRNA detection, require systematic study of DNA polymerases for use with miRNAs. In this study, a variety of DNA polymerases were studied to assess their capabilities of using miRNA as a primer and incorporating 2'-deoxyadenosine-5'-O-(1-thiotriphosphate) as a dATP alternative during DNA strand extension. Five DNA polymerases were investigated: mesophilic DNA polymerase I large (Klenow) fragment, 3'-->5' exo(-) Klenow DNA polymerase, thermophilic Bst DNA polymerase large fragment, Therminator DNA polymerase, and Taq DNA polymerase. The experimental results show that, except for Taq DNA polymerase, the polymerases can use miRNA as a primer and have both common and divergent properties of the nucleotide analog incorporation and miRNA discrimination. DNA polymerase I large (Klenow) fragment showed no detectable polymerization product with the thio-modified dATP as a substrate. Thermophilic Bst DNA polymerase had the highest specificity for miRNA recognition on a DNA template. The study provides a novel method for miRNA detection without reverse transcription to complementary DNA that is faster, simpler, and less prone to biases and errors.

Nanoscale labels: nanoparticles and liposomes in the development of high-performance biosensors

Technology for the detection of biological species has generated considerable interest in a variety of fields including healthcare, defense, food and environmental monitoring. In a biosensor, labeled specific binding partners are used to emit a detectable signal. Owing to their unique properties, nanomaterials have been proposed as a novel label category and have led to the development of new assays and new transduction mechanisms. In this article, the role of three major types of nanoscale labels (metallic, semiconductor and liposome nanoparticles) in the development of a new generation of optical, electrochemical or gravimetric biosensors will be presented. The underlying transduction principles will be briefly explained and assay strategies relying on the use of these ‘nanolabels’ will be described. The contribution to increased assay performance and sensitivity will be highlighted. Approaches towards simple, cost efficient and sensitive assays are essential to meet the demands of a growing number of applications.

Stepwise silver-staining-based immunosorbent assay for amyloid-beta autoantibody detection

AIMS

To detect amyloid-beta (Abeta) autoantibodies in a reliable and high-throughput fashion, we developed a stepwise silver-staining-based immunosorbent assay in a 96-well-plate platform.

MATERIALS & METHODS

Abeta autoantibodies were incubated in an Abeta-immobilized 96-well microplate. Antihuman IgG-modified gold nanoparticle probes were then used to bind to the autoantibodies and signal enhancement was carried out with stepwise silver-staining on immobilized gold nanoparticle probes. A microplate reader was used to quantify silver-stained gold nanoparticles on a well-plate surface.

RESULTS & DISCUSSION

Stepwise silver-staining at low temperature enables long-term silver-staining with minimal increase of background signal. This stepwise staining method helps solve the problems of one-step staining, such as nonspecific binding or nonuniformity in silver precipitation after prolonged silver-staining for signal enhancement.

CONCLUSION

A stepwise silver-staining strategy could be useful in minimizing nonspecific background signals. This 96-well-plate-based Abeta antibody detection assay could be useful in studying and diagnosing Alzheimer's disease.

Introduction to microarray technology

DNA microarrays can be used for large number of application where high-throughput is needed. The ability to probe a sample for hundred to million different molecules at once has made DNA microarray one of the fastest growing techniques since its introduction about 15 years ago. Microarray technology can be used for large scale genotyping, gene expression profiling, comparative genomic hybridization and resequencing among other applications. Microarray technology is a complex mixture of numerous technology and research fields such as mechanics, microfabrication, chemistry, DNA behaviour, microfluidics, enzymology, optics and bioinformatics. This chapter will give an introduction to each five basic steps in microarray technology that includes fabrication, target preparation, hybridization, detection and data analysis. Basic concepts and nomenclature used in the field of microarray technology and their relationships will also be explained.

Ultra-sensitive detection of mutated papillary thyroid carcinoma DNA using square wave stripping voltammetry method and amplified gold nanoparticle biomarkers

This study presents an ultra-sensitive technique for the electrochemical detection of the mutated BRAF gene associated with papillary thyroid carcinomas (PTC). In the proposed approach, a biotinylated 30-nucleotides probe DNA was immobilized in a streptavidin-modified 96-well microtiter plate and the free active sites of the streptavidin were blocked using biotinylated bovine serum albumin (BSA). The biotinylated target DNA was then added and allowed to hybridize with the immobilized probe DNA for 30min. Subsequently, streptavidin-labeled gold nanoparticles were added, and a nanoparticle enlargement process was performed using gold ion solution and formaldehyde reductant. The gold particles were then dissolved in bromide and DNA hybridization detection process was performed using a square wave stripping voltammetry (SWSV) technique. The results indicated a stable SWSV response in differential detection between blank solution and target DNA solution with a concentration of 130aM. Moreover, the coefficient of determination (R(2)) of the semi-log plot of the SWSV response current against the target DNA concentration (0.52-1300aM) was found to be 0.9982. The detection limit was estimated to be 0.35aM (based on a signal-to-noise ratio of 3:1). This value was approximately three orders of magnitude lower than that obtained using the same method but without gold amplification process. Finally, the proposed approach is successful in differentiating between the mutant and wildtype BRAF sequences that are present in genuine 224-nucleotides DNA.

Photopolymerization as an innovative detection technique for low-density microarrays

One limitation that accounts in part for the scarcity of commercially available diagnostic microarrays is the expense associated with fluorescence detection. Here we present a colorimetric method based on photopolymerization as an "on-chip" signal amplification technique. Proof of principle experiments are detailed and followed by the use of a simple influenza microarray to demonstrate the technique for the first time with clinical samples. The advantages of this new technique include rapid (<5 min) signal amplification ( approximately 105) in ambient conditions for both DNA and protein microarrays, low reagent cost (<$1 per assay), visual or inexpensive detection, and signal preservation for at least two years under ambient conditions.

The use of gold nanoparticles in diagnostics and detection

The widespread use of gold nanoparticles (GNPs) as labels in diagnostics and detection is due to a unique combination of chemical and physical properties that allow biological molecules to be detected at low concentrations. In this critical review detection methods based on GNPs are divided up and discussed based on the way in which signals are generated in response to specific target molecules. Particular attention is devoted to methods that allow target molecules to be detected with the unaided eye because these, more than any other, harness the full range of properties that make GNPs unique. Methods that are discussed include those in which specific target molecules induce a visible colour change, chromatographic methods that allow non-specialized users to perform sophisticated tests without additional equipment and methods in which trace amounts of GNPs are rendered visible to the unaided eye by catalytic deposition of a metal such as silver. The use of metal deposition as a means of enhancing the signal for optical and electrical detection is also reviewed. The other detection methods included in this review are based on interactions between GNPs and molecules located in close proximity to their surface. These include methods in which light emission from such molecules is enhanced (surface enhanced Raman scattering) or quenched (fluorescence), and methods in which the accumulation of specific target molecules induce subtle changes in the extinction spectra of GNPs that can be followed in real time with inexpensive equipment (166 references).