Optimisation of a silicon/silicon dioxide substrate for a fluorescence DNA microarray

This paper presents a comprehensive theory and experimental characterisation of the modulation of the fluorescence intensity by the construction of optical interferences on oxidised silicon substrates used for DNA microarrays. The model predicts a 90-fold variation of the fluorescence signal depending on the oxide thickness. For a Cy3 dye, the signal is maximal for a 90 nm oxide thickness corresponding to a 7.5-fold enhancement with respect to a standard glass substrate. For experimental validation of the model, we have prepared Si/SiO2 substrates with different parallel steps of decreasing oxide thicknesses on the same sample using a buffered oxide etch (BOE) etching process after thermal oxidation. The SiO2 surface has been functionalized by a silane monolayer before in situ synthesis of L185 oligonucleotide probes. After hybridisation with complementary targets, the variations of the fluorescence intensity versus oxide thickness are in very good accordance with the theoretical model. The experimental comparison against a glass substrate shows a 10-fold enhancement of the detection sensitivity. Our results demonstrate that a Si/SiO2 substrate is an attractive alternative to standard glass slides for the realisation of fluorescence DNA microarrays whenever detection sensitivity is an important issue.     

Silicon nanopillar substrates for enhancing signal intensity in DNA microarrays

The use of ordered, high-aspect ratio nanopillar arrays on the surface of silicon-based chips to enhance signal intensity in DNA microarrays is reported. These nanopillars consisting either of a single silicon dioxide substrate or a dual silicon/silicon dioxide substrate are fabricated using deep-UV lithography followed by reactive ion etching. These pillar type arrays provide a three-dimensional high surface-density platform that increases the immobilization capacity of captured probes, enhances target accessibility and reduces background noise interference in DNA microarrays, leading to improved signal-to-noise ratios, sensitivity and specificity. Consequently, it was found that the use of such nanopillars enhanced the hybridization signals by up to seven times as compared to silicon dioxide thin film substrates. In addition, hybridization of synthetic targets to capture probes that contained a single-base variation showed that the perfect matched duplex signals on dual-substrate nanopillars can be up to 23 times higher than the mismatched duplex signals, allowing the targets to be unambiguously identified. These results suggest that the nanopillars, particularly the dual-substrate pillars, are able to enhance the hybridization signals and discrimination power in nucleic acids-based detection, providing an alternative platform for improving the performance of DNA microarrays.     

Direct electrical detection of hybridization at DNA-modified silicon surfaces

Electrochemical impedance spectroscopy was used to investigate the changes in interfacial electrical properties that arise when DNA-modified Si(111) surfaces are exposed to solution-phase DNA oligonucleotides with complementary and non-complementary sequences. The n- and p-type silicon(111) samples were covalently linked to DNA molecules via direct Si?C linkages without any intervening oxide layer. Exposure to solutions containing DNA oligonucleotides with the complementary sequence produced significant changes in both real and imaginary components of the electrical impedance, while exposure to DNA with non-complementary sequences generated negligible responses. These changes in electrical properties were corroborated with fluorescence measurements and were reproduced in multiple hybridization-denaturation cycles. The ability to detect DNA hybridization is strongly frequency-dependent. Modeling of the response and comparison of results on different silicon bulk doping shows that the sensitivity to DNA hybridization arises from DNA-induced changes in the resistance of the silicon substrate and the resistance of the molecular layers.     

Multiple wavelength fluorescence enhancement on glass substrates for biochip and cell analyses

In microarrays experiments, a serious limitation is the unreliability of low signal intensities data and the lack of reproducibility for the resulting ratios between samples and controls. Most of the light emitted by a fluorophore at the air/glass interface of a glass slide is absorbed by the glass so just a part of the emitted fluorescence is detected. To improve the sensitivity of the fluorescence detection of both common fluorophores Cy3 and Cy5 in DNA microarrays and fluorescent cell analyses, we have designed a multi layer mirror with alternative thin layers of SiO2 and HfO2. This mirror (MOTL) prevents fluorescence absorption, allows the simultaneous enhancement of the fluorescence signals and increases the dynamic range of the slides. Using MOTL slides, Cy3 and Cy5 intensities are enhanced by 5-8-fold, consequently, the fluorescence analysis becomes easier and should allow the detection of low copy number genes or weakly fluorescent cells. With the same approach, other multiple optical thin layer slides could be designed for other series of fluorophores, extending the field of their applications.     

Controlled three-dimensional immobilization of biomolecules on chemically patterned surfaces

We used electron-beam lithography to fabricate chemical nanostructures, i.e. amino groups in aromatic self-assembled monolayers (SAMs) on gold surfaces. The amino groups are utilized as reactive species for mild covalent attachment of fluorescently labeled proteins. Since non-radiative energy transfer results in strong quenching of fluorescent dyes in the vicinity of the metal surfaces, different labeling strategies were investigated. Spacers of varying length were introduced between the gold surface and the fluorescently labeled proteins. First, streptavidin was directly coupled to the amino groups of the SAMs via a glutaraldehyde linker and fluorescently labeled biotin (X-Biotin) was added, resulting in a distance of approximately 2 nm between the dyes and the surface. Scanning confocal fluorescence images show that efficient energy transfer from the dye to the surface occurs, which is reflected in poor signal-to-background (S/B) ratios of approximately 1. Coupling of a second streptavidin layer increases the S/B-ratio only slightly to approximately 2. The S/B-ratio of the fluorescence signals could be further increased to approximately 4 by coupling of an additional fluorescently labeled antibody layer. Finally, we introduced tetraethylenepentamine as functional spacer molecule to diminish fluorescence quenching by the surface. We demonstrate that the use of this spacer in combination with multiple antibody layers enables the controlled fabrication of highly fluorescent three-dimensional nanostructures with S/B-ratios of >20. The presented technique might be used advantageously for the controlled three-dimensional immobilization of single protein or DNA molecules and the well-defined assembly of protein complexes.     

Innovative metal oxide-based substrates for DNA microarrays

In the present report, we propose a novel approach to synthesize DNA microarrays that employs immobilization of the nucleic acid molecules onto zinc and iron oxide surfaces through their phosphate backbone. Oxide films were prepared by the sol–gel technique and the resulting surfaces were characterized especially with respect to surface chemistry and morphological features by both X-ray photoelectron spectroscopy (XPS) and atomic force microscopy (AFM). ZnO films annealed at T ? 300 °C show the most promising surface features to be employed for DNA microarray preparation, i.e. high density of binding sites (hydroxyl groups), smooth and homogeneous surfaces, high optical transmittance in the visible spectral range suitable for detection using fluorescence, and easy handling during preparation procedures. The analysis of nucleic acid retention on the oxide layers was performed by the scanning of dye-labelled DNA previously printed on the substrate using the DNA microarray robotic arm. Clearly visible spots with regular shape were revealed above the background noise indicating that anchoring of the DNA on the treated surface is efficient and does not interfere with hybridization processes. The use of suitably engineered zinc oxide film makes the immobilization strategy ideal for facile, efficient, and cost-effective manufacturing of DNA microarrays.     

Assessment of porous silicon substrate for well-characterised sensitive DNA chip implement

A biochip approach based on porous silicon as substrate is presented. The goal is to enhance the sensitivity of the biochip by increasing the specific surface area on the support. The elaboration of porous silicon layers has been optimized to guarantee good accessibility for large bio-molecule targets. Oligonucleotide probes are synthesised directly on the surface using phosphoramidite chemistry. The high specific surface area of porous silicon allows the direct characterisation, by infrared spectroscopy, of the porous layer formation and the functionalisation steps. The monolayer grafting and derivatisation protocol is additionally characterized by wettability and fluorescence microscopy. The surface modification of porous layers (i.e. thermal oxidation and chemical derivatisation) ensures the stability of the structure against strong chemical reagents used during the direct oligonucleotide synthesis. Finally the protocol is successfully transferred to a flat Si/SiO(2) substrate, and validated by biological target specific recognition during hybridisation tests. In particular, radioactive measurements show a 10-fold enhancement of the oligonucleotide surface density on the porous silicon substrate compared to the flat thermal silica.     

Improvement of yeast biochip sensitivity using multilayer inorganic sol-gel substrates

Today, microarray fluorescence detection is still limited because a great proportion of hybrids remain undetectable. In this paper we describe sol-gel optical multilayers (stacks of low- and high-index layers) deposited on glass slides which increase the fluorescence of DNA microarrays and favour the detection of fluorescent targets. An alternative to the expensive and time-consuming physical vapour deposition technology is proposed. It is a low-cost sol-gel coating of glass slides, each layer being made by "dipping" (alternatively in SiO2 or TiO2 solutions), "draining and drying". After the selection of the best surface layer of the substrates, the multilayer mirrors modelled for one (Cy3) or two (Cy3 and Cy5) fluorophores are spotted with a series of Yeast probes and compared to similar microarrays on standard glass slides through hybridisation experiments. The fluorescence images of the mirrors show increased signals for all the probes. The enhancement factors determined for Cy3 and for Cy3/Cy5 mirrors (10-12 and 4-5, respectively) are consistent with the initial modelling. This allows the assessment of the basal expression levels of Yeast low-expressed genes. Moreover, these substrates show a noticeable increase in sensitivity for induction/repression ratio measurements in differential gene expression experiments. So, they could be considered as promising tools for the analysis of small biological samples.     

Opto-electronic DNA chip: high performance chip reading with an all-electric interface

Reading of DNA chips is usually based on fluorescence labeling of hybridised target molecules. Combined with the use of confocal fluorescence scanners, this approach shows very high performances in terms of accuracy and sensitivity. However, fluorescence readers remain costly and cumbersome. This prevents the use of DNA chips as a decentralised testing tool. Electrical monitoring of hybridisation is one way to reduce the cost and size of the reader. However, the multiplexing of electric detection-based systems in a miniaturised form remains challenging. Here, we present a system based on the use of a low cost CMOS photodetector array as a solid support for a DNA chip, coupled with revelation by enzyme-catalysed chemiluminescence. This system is shown to allow the detection of low pM target concentrations with a 3 logs dynamic range on dense DNA microarrays, with excellent inter-spot reproducibility. Combining electric interface and high analytical performances, this opto-electronic DNA chip is one attractive solution for nucleic acids detection and analysis in disposable, fully automatised, total analysis systems developed for decentralised testing.     

Monitoring DNA hybridization on alkyl modified silicon surface through capacitance measurement

Single strand oligodeoxynucleotide is attached to the alkyl modified silicon surface through a peptide bond. The oligodeoxynucleotide-modified silicon substrate is used as a working electrode in an electrochemical cell system. After the electrode is treated by a solution containing strands of complementary oligodeoxynucleotide the Mott-Schottky measurements exhibit obvious negative shift in the flat band potential of the electrode, while in a control experiment treated with a solution of non-complementary oligodeoxynucleotide such a shift does not occur. The DNA hybridization is also manifested in a real time capacitance measurement. A DNA sensor based on the capacitance measurement could be more convenient than that based on a fluorescence detection.     

Antibody microarray profiling of human prostate cancer sera: antibody screening and identification of potential biomarkers

We developed a practical strategy for serum protein profiling using antibody microarrays and applied the method to the identification of potential biomarkers in prostate cancer serum. Protein abundances from 33 prostate cancer and 20 control serum samples were compared to abundances from a common reference pool using a two-color fluorescence assay. Robotically spotted microarrays containing 184 unique antibodies were prepared on two different substrates: polyacrylamide based hydrogels on glass and poly-1-lysine coated glass with a photoreactive cross-linking layer. The hydrogel substrate yielded an average six-fold higher signal-to-noise ratio than the other substrate, and detection of protein binding was possible from a greater number of antibodies using the hydrogels. A statistical filter based on the correlation of data from "reverse-labeled" experiment sets accurately predicted the agreement between the microarray measurements and enzyme-linked immunosorbent assay measurements, showing that this parameter can serve to screen for antibodies that are functional on microarrays. Having defined a set of reliable microarray measurements, we identified five proteins (von Willebrand Factor, immunoglobulinM, Alpha1-antichymotrypsin, Villin and immunoglobulinG) that had significantly different levels between the prostate cancer samples and the controls. These developments enable the immediate use of high-density antibody and protein microarrays in biomarker discovery studies.     

Enhanced sensitivity detection of protein immobilization by fluorescent interference on oxidized silicon

We present a silicon chip-based approach for the enhanced sensitivity detection of surface-immobilized fluorescent molecules. Green fluorescent protein (GFP) is bound to the silicon substrate by a disuccinimidyl terephtalate-aminosilane immobilization procedure. The immobilized organic layers are characterized by surface analysis techniques, like ellipsometry, atomic force microscopy (AFM) and X-ray induced photoelectron spectroscopy. We obtain a 20-fold enhancement of the fluorescent signal, using constructive interference effects in a fused silica dielectric layer, deposited before immobilization onto the silicon. Our method opens perspectives to increase by an order of magnitude the fluorescent response of surface immobilized DNA- or protein-based layers for a variety of biosensor applications.     

3D Profile Simulation of Metal Nanostructures Obtained by Closely Packed Nanosphere Lithography

Closely packed lithography is a versatile technology to fabricate different kinds of periodically arranged nanostructures on substrate or in solution. Due to its large diversities and versatilities, it is necessary to predict the shape of the nanostructures under various fabrication conditions. This paper gives a full simulation for the profile of metal nanostructures fabricated by closely packed nanosphere lithography. The simulation applies to both hexagonal and quadrangular nanosphere arrangements, and the nanospheres can be in one layer or stacked in two layers, with each layer having a different size. For metal evaporated at any angle onto the nanosphere mask, three-dimensional metal nanostructures on each layer of the nanosphere as well as the substrate are given. The simulation helps to obtain the desired metal nanostructures by predicting the profiles and facilitating the process design in closely packed lithography, and it is especially beneficial for finding out the profiles of the nanostructures hidden under the nanospheres, which are undetectable without removing the nanosphere layers.     

Colorimetric silver detection of DNA microarrays

Development of microarrays has revolutionized gene expression analysis and molecular diagnosis through miniaturization and the multiparametric features. Critical factors affecting detection efficiency of targets hybridization on microarray are the design of capture probes, the way they are attached to the support, and the sensitivity of the detection method. Microarrays are currently detected in fluorescence using a sophisticated confocal laser-based scanner. In this work, we present a new colorimetric detection method which is intented to make the use of microarray a powerful procedure and a low-cost tool in research and clinical settings. The signal generated with this method results from the precipitation of silver onto nanogold particles bound to streptavidin, the latter being used for detecting biotinylated DNA. This colorimetric method has been compared to the Cy-3 fluorescence method. The detection limit of both methods was equivalent and corresponds to 1 amol of biotinylated DNA attached on an array. Scanning and data analysis of the array were obtained with a colorimetric-based workstation.     

Optical Biochip with Multichannels for Detecting Biotin–Streptavidin Based on Localized Surface Plasmon Resonance

A rapid and accurate detection of molecular binding of antigen-antibody signaling in high throughput is of great importance for biosensing technology. We proposed a novel optical biochip with multichannels for the purpose of detection of biotin–streptavidin on the basis of localized surface plasmon resonance. The optical biochip was fabricated using photolithography to form the microarrays functioning with multichannels on glass substrate. There are different nanostructures in each microarray. Dry etching and nanosphere lithography techniques were applied to fabricate Ag nanostructures such as hemispheres, nanocylindricals, triangular, and rhombic nanostructures. We demonstrated that 100-nM target molecule (streptavidin) on these optical biochips can be easily detected by a UV-visible spectrometer. It indicated that period and shape of the nanostructures significantly affect the optical performance of the nanostructures with different shapes and geometrical parameters. Our experimental results demonstrated that the optical biochips with the multichannels can detect the target molecule using the microarrays structured with different shapes and periods simultaneously. Batch processing of immunoassay for different biomolecular through the different channels embedded on the same chip can be realized accordingly.     

Locally Addressable Electrochemical Patterning Technique (LAEPT) applied to poly(L-lysine)-graft-poly(ethylene glycol) adlayers on titanium and silicon oxide surfaces

The protein-resistant polycationic graft polymer, poly(L-lysine)-g-poly(ethylene glycol) (PLL-g-PEG), was uniformly adsorbed onto a homogenous titanium surface and subsequently subjected to a direct current (dc) voltage. Under the influence of an ascending cathodic and anodic potential, there was a steady and gradual loss of PLL-g-PEG from the conductive titanium surface while no desorption was observed on the insulating silicon oxide substrates. We have implemented this difference in the electrochemical response of PLL-g-PEG on conductive titanium and insulating silicon oxide regions as a biosensing platform for the controlled surface functionalization of the titanium areas while maintaining a protein-resistant background on the silicon oxide regions. A silicon-based substrate was micropatterned into alternating stripes of conductive titanium and insulating silicon oxide with subsequent PLL-g-PEG adsorption onto its surfaces. The surface modified substrate was then subjected to +1800 mV (referenced to the silver electrode). It was observed that the potentiostatic action removed the PLL-g-PEG from the titanium stripes without inducing any polyelectrolyte loss from the silicon oxide regions. Time-of-flight secondary ions mass spectroscopy and fluorescence microscopy qualitatively confirmed the PLL-g-PEG retention on the silicon oxide stripes and its absence on the titanium region. This method, known as "Locally Addressable Electrochemical Patterning Technique" (LAEPT), offers great prospects for biomedical and biosensing applications. In an attempt to elucidate the desorption mechanism of PLL-g-PEG in the presence of an electric field on titanium surface, we have conducted electrochemical impedance spectroscopy experiments on bare titanium substrates. The results showed that electrochemical transformations occurred within the titanium oxide layer; its impedance and polarization resistance were found to decrease steadily upon both cathodic and anodic polarization resulting in the polyelectrolyte desorption from the titanium surface.     

DNA microarrays on a dendron-modified surface improve significantly the detection of single nucleotide variations in the p53 gene

Selectivity and sensitivity in the detection of single nucleotide polymorphisms (SNPs) are among most important attributes to determine the performance of DNA microarrays. We previously reported the generation of a novel mesospaced surface prepared by applying dendron molecules on the solid surface. DNA microarrays that were fabricated on the dendron-modified surface exhibited outstanding performance for the detection of single nucleotide variation in the synthetic oligonucleotide DNA. DNA microarrays on the dendron-modified surface were subjected to the detection of single nucleotide variations in the exons 5–8 of the p53 gene in genomic DNAs from cancer cell lines. DNA microarrays on the dendron-modified surface clearly discriminated single nucleotide variations in hotspot codons with high selectivity and sensitivity. The ratio between the fluorescence intensity of perfectly matched duplexes and that of single nucleotide mismatched duplexes was >5–100 without sacrificing signal intensity. Our results showed that the outstanding performance of DNA microarrays fabricated on the dendron-modified surface is strongly related to novel properties of the dendron molecule, which has the conical structure allowing mesospacing between the capture probes. Our microarrays on the dendron-modified surface can reduce the steric hindrance not only between the solid surface and target DNA, but also among immobilized capture probes enabling the hybridization process on the surface to be very effective. Our DNA microarrays on the dendron-modified surface could be applied to various analyses that require accurate detection of SNPs.     

Reduction of autofluorescence on DNA microarrays and slide surfaces by treatment with sodium borohydride

Microarray technology is currently being used extensively in functional genomics research and modern drug discovery and development. Henceforward, tremendous application potential for this technology exists in the fields of clinical diagnostics and prognostics, pathology, and toxicology for high-throughput analysis of "disease" gene expression. However, the major hurdle now in this technology is not the performance of the arrays but rather the efficient reproducibility of the hybridization signal intensity in a fluorescence-based analysis. The sensitivity of fluorescence detection on an array is to a large extent limited by the amount of background signal arising due to nonspecifically bound probes and fluorescence that is intrinsically associated with the chip substrate and/or the attached target DNA, the so-called autofluorescence. Here, we describe a simple and efficient method to reduce autofluorescence from undetermined sources on coated glass slides with and without DNA arrays. This sodium borohydride-mediated reduction process resulted in significantly lower and more even background fluorescence. This in turn extended the dynamic range of detection and reduced the average coefficient of variation of fluorescent signal ratios on DNA microarrays in addition to improving the detection of genes that are expressed at a low level.     

Alpha-oxo semicarbazone peptide or oligodeoxynucleotide microarrays

We describe in this paper the preparation and characterization of semicarbazide glass slides and their use for the fabrication of microarrays using site-specific alpha-oxo semicarbazone ligation. The functional density and homogeneity of the semicarbazide glass slides were optimized by analyzing the reactivity of the layer toward a synthetic glyoxylyl fluorescent probe. Oligonucleotide microarrays were prepared by site-specific immobilization of glyoxylyl oligodeoxynucleotides. The slides were directly used in the hybridization assays using fluorescence detection and displayed a significant gain in sensibility as compared to the aldehyde glass slide/amino oligodeoxynucleotide chemistry. Semicarbazide slides were also used for the immobilization of a biotinylated peptide alpha-oxo aldehyde. The peptide microarrays allowed model interaction studies with streptavidin or an anti-biotin antibody.     

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.