Enhancement of DNA immobilization and hybridization on gold electrode modified by nanogold aggregates

Gold electrodes modified by nanogold aggregates (nanogold electrode) were obtained by the electrodeposition of gold nanoparticles onto planar gold electrode. The Electrochemical response of single-stranded DNA (ssDNA) probe immobilization and hybridization with target DNA was measured by cyclic voltammograms (CV) using methylene blue (MB) as an electroactive indicator. An improving method using long sequence target DNA, which greatly enhanced the response signal during hybridization, was studied. Nanogold electrodes could largely increase the immobilization amount of ssDNA probe. The hybridization amount of target DNA could be increased several times for the manifold nanogold electrodes. The detection limit of nanogold electrode for the complementary 16-mer oligonucleotide (target DNA1) and long sequence 55-mer oligonucleotide (target DNA2) could reach the concentration of 10(-9) mol/L and 10(-11) mol/L, respectively, which are far more sensitive than that of the planar electrode.     

Immobilization and hybridization by single sub-millisecond electric field pulses, for pixel-addressed DNA microarrays

Single square voltage pulses applied to buried electrodes result in dramatic rate increases for (1) selective covalent bonding (immobilization) of single-stranded DNA (ssDNA) probes to a functionalized thin film SiO₂ surface on a plastic substrate and (2) hybridization of ssDNA to the immobilized probe. DNA immobilization and hybridization times are 100 ns and 10 μs, respectively, about 10⁹ times faster than the corresponding passive reactions without electric field. Surface coverage is comparable. Duration, magnitude and slew rate of the voltage pulse are all key factors controlling the rates of ssDNA immobilization and hybridization. With rise times of 4.5 ns, pulses shorter than 1 ms and voltages below 1 V are effective. The ssDNA adsorbed on the surface is reoriented by the rapidly changing electric field. This reduces steric barriers and speeds the immobilization and hybridization reactions. These results open the way for pixel-addressed microarrays driven by silicon microelectronics circuits.     

Immobilization of DNA on microporous membranes using UV-irradiation]

Various techniques of DNA immobilization onto nitrocellulose and nylon microporous membranes have been compared. Despite a strong primary adsorption of DNA onto these membranes during blotting procedures, poor retention of the target DNA and low hybridization signals are obtained after hybridization and washings. Covalent cross-linking of DNA upon UV irradiation leads to a quantitative immobilization of target DNA. Quantum yield of DNA photoimmobilization estimated for a single base in DNA is about 10(-4). UV irradiation dose sufficient for immobilization of DNA fragment of a known length can be calculated by the formula Ilc = (22.3 +/- 4.8) c/l, where l is the DNA fragment length (in base pairs), c is the DNA part (%) to be immobilized. The UV irradiation dose about 0.6-0.8 kJ/m2 is optimal for most hybridization experiments. Doses higher than 0.8-1 kJ/m2 may cause a loss in the hybridization efficiency. Under optimal immobilization conditions, hybridization signals increasing five-fold for nitrocellulose membranes and fifty-fold for uncharged nylon membranes as compared with baking these membranes in vacuum.     

Ultrasensitive DNA sensor based on gold nanoparticles/reduced graphene oxide/glassy carbon electrode

We have designed a simple and novel electrochemical biosensor based on glassy carbon electrode (GCE) for DNA detection. GCE was modified with reduced graphene oxide (RGO) and gold nanoparticles (AuNPs) by the electrochemical method, which is helpful for immobilization of thiolated bioreceptors. The electrode modification processes were characterized by scanning electron microscopy (SEM) and electrochemical methods. Then a single-stranded DNA (ssDNA) probe for BRCA1 5382 insC mutation detection was immobilized on the modified electrode for a specific time. The experimental conditions, such as probe immobilization time and target DNA (complementary DNA) hybridization time and temperature with probe DNA, were optimized using electrochemical methods. The electrochemical response for DNA hybridization and synthesis was measured using electrochemical impedance spectroscopy (EIS) and cyclic voltammetry (CV) methods. The calibration graph contains two linear ranges; the first part is in the range of 3.0 × 10⁻²⁰ to 1.0 × 10⁻¹² M, and the second segment part is in the range of 1.0 × 10⁻¹² to 1.0 × 10⁻⁷ M. The biosensor showed excellent selectivity for the detection of the complementary sequences from noncomplementary sequences, so it can be used for detection of breast cancer.     

Kinetics of hybridization on surface oligonucleotide microchips: theory, experiment, and comparison with hybridization on gel-based microchips

The optimal design of oligonucleotide microchips and efficient discrimination between perfect and mismatch duplexes strongly depend on the external transport of target DNA to the cells with immobilized probes as well as on respective association and dissociation rates at the duplex formation. In this paper we present the relevant theory for hybridization of DNA fragments with oligonucleotide probes immobilized in the cells on flat substrate. With minor modifications, our theory also is applicable to reaction-diffusion hybridization kinetics for the probes immobilized on the surface of microbeads immersed in hybridization solution. The main theoretical predictions are verified with control experiments. Besides that, we compared the characteristics of the surface and gel-based oligonucleotide microchips. The comparison was performed for the chips printed with the same pin robot, for the signals measured with the same devices and processed by the same technique, and for the same hybridization conditions. The sets of probe oligonucleotides and the concentrations of probes in respective solutions used for immobilization on each platform were identical as well. We found that, despite the slower hybridization kinetics, the fluorescence signals and mutation discrimination efficiency appeared to be higher for the gel-based microchips with respect to their surface counterparts even for the relatively short hybridization time about 0.5-1 hour. Both the divergence between signals for perfects and the difference in mutation discrimination efficiency for the counterpart platforms rapidly grow with incubation time. In particular, for hybridization during 3 h the signals for gel-based microchips surpassed their surface counterparts in 5-20 times, while the ratios of signals for perfect-mismatch pairs for gel microchips exceeded the corresponding ratios for surface microchips in 2-4 times. These effects may be attributed to the better immobilization efficiency and to the higher thermodynamic association constants for duplex formation within gel pads.     

A new scheme of hybridization based on the Au(nano)-DNA modified glassy carbon electrode

DNA hybridization on the Au(nano)-DNA modified glassy carbon electrode (GCE) was investigated. The thiol modified probe oligonucleotides (SH-ssDNA) at the 5' phosphate end were assembled on the Au(nano)-DNA modified GCE surface. The electrochemical response of the probe immobilization and hybridization with target DNA was measured by differential pulse voltammetry (DPV) using methylene blue (MB) as the electroactive indicator. Gold nanoparticles can be dispersed effectively on the GCE surface in the presence of calf thymus DNA. Au(nano)-DNA modified GCE could greatly increase the active sites and enhance the response signal during immobilization and hybridization. The hybridization amount of target DNA could be greatly increased. The linear detection range of Au(nano)-DNA electrode for the complementary 21-mer oligonucleotide (cDNA) was achieved from 1.52 x 10(-10) to 4.05 x 10(-8) mol L(-1). The detection limit could reach the concentration of 10(-10) mol/L.     

[Cu(phen)2] acts as electrochemical indicator and anchor to immobilize probe DNA in electrochemical DNA biosensor

We demonstrate a novel protocol for sensitive in situ label-free electrochemical detection of DNA hybridization based on copper complex ([Cu(phen)₂]²⁺, where phen = 1,10-phenanthroline) and graphene (GR) modified glassy carbon electrode. Here, [Cu(phen)₂]²⁺ acted advantageously as both the electrochemical indicator and the anchor for probe DNA immobilization via intercalative interactions between the partial double helix structure of probe DNA and the vertical aromatic groups of phen. GR provided large density of docking site for probe DNA immobilization and increased the electrical conductivity ability of the electrode. The modification procedure was monitored by electrochemical impedance spectroscopy (EIS). Square-wave voltammetry (SWV) was used to explore the hybridization events. Under the optimal conditions, the designed electrochemical DNA biosensor could effectively distinguish different mismatch degrees of complementary DNA from one-base mismatch to noncomplementary, indicating that the biosensor had high selectivity. It also exhibited a reasonable linear relationship. The oxidation peak currents of [Cu(phen)₂]²⁺ were linear with the logarithm of the concentrations of complementary target DNA ranging from 1 × 10⁻¹² to 1 × 10⁻⁶ M with a detection limit of 1.99 × 10⁻¹³ M (signal/noise = 3). Moreover, the stability of the electrochemical DNA biosensor was also studied.     

Nanogold hollow balls with dendritic surface for hybridization of DNA

Au hollow balls are fabricated by adsorption of gold 3.5 nm in diameter onto a mixed vesicle composed of mixed polymerized diacetylene which made of negative charged 10,12-pentacosadiynoic acid (PCDA) and positive charged 10,12-pentacosadiynoic acid 2'-aminoethylamide (PCDA-NH(2)). The morphology of these hollow spheres could be controlled by changing the ratio of PCDA and PCDA-NH(2) and the immobilization and hybridization ability of the gold hollow ball have been investigated using a quartz crystal microbalance (QCM). It was found that a dendritic surface in an appropriate ratio existed. The hybridization amount of target DNA is about three to five times for the Au-mixed hollow ball at an optimal ratio (PCDA/PCDA-NH(2)=1/3) as compared with that for pure Au-PCDA-NH(2), though the immobilization amount of ssDNA on these two samples are almost the same, and the detected limitation of target DNA is extend from 10(-9) to 10(-12) M. The stability against breakage by transportation, combined with the simplicity and efficiency of detection, would offer an important advantage over unpolymerized one. This result shows the possibility to control the morphology and surface of nanogold hollow spheres by changing the ratio of PCDA and PCDA-NH(2) for the develop of a better DNA detection assay, further proving the idea that low surface coverage and higher DNA probe to target DNA ratios lead to optimal hybridization.     

Sex determination based on amelogenin DNA by modified electrode with gold nanoparticle

We have developed a simple and renewable electrochemical biosensor based on carbon paste electrode (CPE) for the detection of DNA synthesis and hybridization. CPE was modified with gold nanoparticles (AuNPs), which are helpful for immobilization of thiolated bioreceptors. AuNPs were characterized by scanning electron microscopy (SEM). Self-assembled monolayers (SAMs) of thiolated single-stranded DNA (SH–ssDNA) of the amelogenin gene was formed on CPE. The immobilization of the probe and its hybridization with the target DNA was optimized using different experimental conditions. The modified electrode was characterized by electrochemical impedance spectroscopy (EIS) and cyclic voltammetry (CV). The electrochemical response of ssDNA hybridization and DNA synthesis was measured using differential pulse voltammetry (DPV) with methylene blue (MB) as an electroactive indicator. The new biosensor can distinguish between complementary and non-complementary strands of amelogenin ssDNA. Genomic DNA was extracted from blood and was detected based on changes in the MB reduction signal. These results demonstrated that the new biosensor could be used for sex determination. The proposed biosensor in this study could be used for detection and discrimination of polymerase chain reaction (PCR) products of amelogenin DNA.     

Directed covalent immobilization of aminated DNA probes on aminated plates

A new protocol that enables the immobilization of DNA probes on aminated micro-titer plates activated with aldehyde-dextran via an amino group artificially introduced in the 3' end of the oligonucleotide probe is reported in this work. The method is based on the use of hetero-functional-dextran as a long and multifunctional spacer arm covalently attached to an aminated surface capable of immobilizing DNA oligonucleotides. The immobilization occurred only via the amino introduced in the 3' end of the probe, with no implication of the DNA bases in the immobilization, ensuring that the full length of the probe is available for hybridization. These plates having immobilized oligonucleotide probes are able to hybridize complementary DNA target molecules. The tailor-made hetero-functional aldehyde-aspartic-dextran together with the chemical blocking of the remaining primary amino groups on the support using acetic anhydride avoid the nonspecific adsorption of DNA on the surface of the plates. Using these activated plates, (studying the effect of the probe concentration, temperature, and time of the plate activation on the achieved signal), thus, the covalent immobilization of the aminated DNA probe was optimized, and the sensitivity obtained was similar to that achieved using commercial biotin-streptavidin systems. The new DNA plates are stable under very drastic experimental conditions (90% formamide, at 100 degrees C for 30 min or in 100 mM NaOH).     

An Activated GOPS‐poly‐L‐Lysine‐ Coated Glass Surface for the Immobilization of 60mer Oligonucleotides

To explore a method for enhancing the immobilization and hybridization efficiency of oligonucleotides on DNA microarrays, conventional protocols of poly‐L‐lysine coating were modified by means of surface chemistry, namely, the slides were prepared by the covalently coupling of poly‐L‐lysine to a glycidoxy‐modified glass surface. The modified slides were then used to print microarrays for the detection of the SARS coronavirus by means of 60mer oligonucleotide probes. The characteristics of the modified slides concerning immobilization efficiency, hybridization dynamics, and probe stripping cycles were determined. The improved surface exhibited high immobilization efficiency, a good quality uniformity, and satisfactory hybridization dynamics. The spotting concentration of 10 μmol/L can meet the requirements of detection; the spots were approximately 170 nm in diameter; the mean fluorescence intensity of the SARS spots were between 3.2 × 10⁴ and 5.0 × 10⁴ after hybridization. Furthermore, the microarrays prepared by this method demonstrated more resistance to consecutive probe stripping cycles. The activated GOPS‐PLL slide could undergo hybridization stripping cycles for at least three cycles, and the highest loss in fluorescence intensity was found to be only 11.9 % after the third hybridization. The modified slides using the above‐mentioned method were superior to those slides treated with conventional approaches, which theoretically agrees with the fact that modification by surface chemistry attaches the DNA covalently firmly to the slides. This protocol may have great promise in the future for application in large‐scale manufacture.     

Influence of liquid medium and surface morphology on the response of QCM during immobilization and hybridization of short oligonucleotides

With the goal of developing a quartz crystal microbalance (QCM)-based DNA sensor, we have conducted an in situ QCM study along with fluorescence measurements using oligonucleotides (15-mer) as a model single-stranded DNA (ss-DNA) in two different aqueous buffer solutions; the sequence of 15-mer is a part of iduronate-2-sulphate exon whose mutation is known to cause Hunter syndrome, and the 15-mer is thiolated to be immobilized on the Au-coated quartz substrate. The fluorescence data indicate that the initial immobilization as well as the subsequent hybridization with a complementary strand is hardly dependent on the kind of buffer solution. In contrast, the mass increases deducible from the decrease of QCM frequency via the Sauerbrey equation are 2.7-6.2 and 3.0-4.4 times larger than the actual mass increases, as reflected in the fluorescence measurements, for the immobilization and the subsequent hybridization processes, respectively. Such an overestimation is attributed to the trapping of solvent as well as the formation of quite a rigid hydration layer associated with the higher viscosities and/or densities of the buffer solutions. Another noteworthy observation is the excessively large frequency change that occurs when the gold electrode is deposited in advance with Au nanoparticles. This clearly illustrates that the QCM detection of DNA hybridization is also affected greatly by the surface morphology of the electrode. These enlarged signals are altogether presumed to be advantageous when using a QCM system as an in situ probing device in DNA sensors.     

Optimisation of one-tube PCR-ELISA to detect femtogram amounts of genomic DNA

A simple, high-throughput, low-cost polymerase chain reaction-enzyme linked immunosorbent assay (PCR-ELISA) protocol that detects the presence of 4 fg of DNA from four bacterial fish pathogens Yersinia ruckeri, Tenacibaculum maritimum (formerly Flexibacter maritimus), Lactococcus garvieae and Aeromonas salmonicida was developed. DNA amplification was undertaken in a biphasic system with free and bound PCR that are achieved in the one NucleoLink tube. Solid-phase amplicons were detected using biotin labelled hybridization probes and visualised colourimetrically with streptavidin-alkaline phosphatase and p-nitrophenylphosphate as substrate. PCR and hybridization took less than 8 h to perform with maximum signal output for femtogram amounts of template DNA achieved within 24 h. Implementation and optimization of the protocol is discussed.     

Impact of spacers on the hybridization efficiency of mixed self-assembled DNA/alkanethiol films

The immobilization of DNA strands is an essential step in the development of any DNA biosensor. Self-assembled mixed DNA/alkanethiol films are often used for coupling DNA probes covalently to the sensor surface. Although this strategy is well accepted, the effect of introducing a spacer molecule to increase the distance between the specific DNA sequence and the surface has rarely been assessed. The major goal of this work was to evaluate a number of such spacers and to assess their impact on for example the sensitivity and the reproducibility. Besides the commonly used mercaptohexyl (C(6)) spacer, a longer mercapto-undecyl (C(11)) spacer was selected. The combination of both spacers with tri(ethylene)glycol (TEG) and hexa(ethylene)glycol (HEG) was studied as well. The effect of the different spacers on the immobilization degree as well as on the consecutive hybridization was studied using surface plasmon resonance (SPR). When using the longer C(11) spacer the mixed DNA/alkanethiol films were found to be more densely packed. Further hybridization studies have indicated that C(11) modified probes improve the sensitivity, the corresponding detection limit as well as the reproducibility. In addition two different immobilization pathways, i.e. flow vs. diffusion controlled, were compared with respect to the hybridization efficiency. These data suggest that a flow-assisted approach is beneficial for DNA immobilization and hybridization events. In conclusion, this work demonstrates the considerable impact of spacers on the biosensor performance but also shows the importance of a flow-assisted immobilization approach.     

Development of DNA electrochemical biosensor based on immobilization of ssDNA on the surface of nickel oxide nanoparticles modified glassy carbon electrode

A sensitive electrochemical method for DNA hybridization based on immobilization of DNA probe and [Ru(NH₃)₅Cl]PF₆ complex onto nickel oxide nanomaterials (NiOx_np) modified glassy carbon electrode was developed. Due to strong affinity of NiOx_np for phosphate groups, oligonucleotides probe with a terminal 5′-phosphate group was attached to the surface of the modified electrode. DNA immobilization and hybridization were characterized by electrochemical impedance spectroscopy (EIS) and differential pulse voltammetry using K₃Fe(CN)₆/K₄Fe(CN)₆ and [Ru(NH₃)₅Cl]PF₆ as probe and indicator, respectively. The Ru-complex current response indicates only the complementary sequence showing an obvious current signal in comparison to non-complementary and three or single point mismatched sequences. The fabricated biosensor possessed good selectivity and sensitivity for complementary probe, taxon: 32630 tumor necrosis factor (TNF). The linear dynamic range, sensitivity and detection limit of the proposed biosensor were 4 × 10⁻¹⁰ M to 1 × 10⁻⁸ M, 34.32 nA nM⁻¹ and 6.8 × 10⁻¹¹ M, respectively. Excellent reproducibility and stability, quite simple and inexpensive preparation are the other advantages of proposed biosensor.     

A rapid non-radioactive procedure for plaque hybridization using biotinylated probes prepared by random primed labeling

A simple, non-radioactive method has been developed for the rapid screening of phage libraries. In the present study, nanogram amounts of a small restriction fragment (135 bp) were biotinylated via random primed labeling and used to probe cDNA libraries using a modified plaque hybridization protocol. The high backgrounds that are seen typically with avidin/biotin-based methods for plaque hybridization were eliminated by incubation of filters with one of several different proteases prior to hybridization. A comparison of several detection systems indicated that streptavidin conjugated to calf intestinal alkaline phosphatase (AP) was the most sensitive, yielding signals comparable to those obtained with 32P-labeled probes. The times required for phage growth and pre-hybridization were reduced substantially, permitting a convenient one-day screening protocol. Nitrocellulose filters gave the best signal to noise ratio, although "streaking" of plaque DNA was observed occasionally; this problem can be overcome by using nylon-based membranes, which allows exact visualization of the positive plaques. The method was highly reliable; 29 out of 33 putative clones retested positive and the authenticity of these was confirmed by DNA sequence analysis. The random primed biotinylation procedure has been utilized successfully with several different cDNA fragments and has proven useful for other hybridization-based methods (Northern and Southern blots), without the problems associated with the use of radiolabeled probes.     

A nucleic acid biosensor for the detection of a short sequence related to the hepatitis B virus using bis(benzimidazole)cadmium(II) dinitrate as an electrochemical indicator

A novel hybridization indicator, bis(benzimidazole)cadmium(II) dinitrate (Cd(bzim)(2)(NO(3))(2)), was utilized to develop an electrochemical DNA biosensor for the detection of a short DNA sequence related to the hepatitis B virus (HBV). The sensor relies on the immobilization and hybridization of the 21-mer single-stranded oligonucleotide from the HBV long repeat at the glassy carbon electrode (GCE). The hybridization between the probe and its complementary sequence as the target was studied by enhancement of the peak of the Cd(bzim)(2)(2+) indicator using cyclic voltammetry (CV) and differential pulse voltammetry (DPV). Numerous factors affecting the probe immobilization, target hybridization, and indicator binding reactions were optimized to maximize the sensitivity and speed of the assay time. With this approach, a sequence of the HBV could be quantified over the range from 1.49x10(-7)M to 1.06x10(-6)M, with a linear correlation of r=0.9973 and a detection limit of 8.4x10(-8)M. The Cd(bzim)(2)(2+) signal observed from the probe sequence before and after hybridization with a four-base mismatch containing sequence was lower than that observed after hybridization with a complementary sequence, showing good selectivity. These results demonstrate that the Cd(bzim)(2)(2+) indicator provides great promise for the rapid and specific measurement of the target DNA.     

Detection of DNA recognition events using multi-well field effect devices

We proposed the multi-well field effect device for detection of charged biomolecules and demonstrated the detection principle for DNA recognition events using quasi-static capacitance-voltage (QSCV) measurement. The multi-well field effect device is based on the electrostatic interaction between molecular charges induced by DNA recognition and surface electrons in silicon through the Si(3)N(4)/SiO(2) thin double-layer. Since DNA molecules and DNA binders such as Hoechst 33258 have intrinsic charges in aqueous solutions, respectively, the charge density changes due to DNA recognition events at the Si(3)N(4) surface were directly translated into electrical signal such as a flat band voltage change in the QSCV measurement. The average flat band shifts were 20.7 mV for hybridization and -13.5 mV for binding of Hoechst 33258. From the results of flat band voltage shifts due to hybridization and binding of Hoechst 33258, the immobilization density of oligonucleotide probes at the Si(3)N(4) surface was estimated to be 10(8) cm(-2). The platform based on the multi-well field effect device is suitable for a simple and arrayed detection system for DNA recognition events.     

Green-synthesized gold nanoparticles decorated graphene sheets for label-free electrochemical impedance DNA hybridization biosensing

Sensitive electrochemical impedance assay of DNA hybridization by using a novel graphene sheets platform was achieved. The graphene sheets were firstly functionalized with 3,4,9,10-perylene tetracarboxylic acid (PTCA). PTCA molecules separated graphene sheets efficiently and introduced more negatively-charged -COOH sites, both of which were beneficial to the decoration of graphene with gold nanoparticles. Then amine-terminated ionic liquid (NH?-IL) was applied to the reduction of HAuCl? to gold nanoparticles. The green-synthesized gold nanoparticles, with the mean diameter of 3 nm, dispersed uniformly on graphene sheets and its outer layer was positively charged imidazole termini. Due to the presence of large graphene sheets and NH?-IL protected gold nanoparticles, DNA probes could be immobilized via electrostatic interaction and adsorption effect. Electrochemical impedance value increased after DNA probes immobilization and hybridization, which was adopted as the signal for label-free DNA hybridization detection. Unlike previously anchoring DNA to gold nanoparticles, this label-free method was simple and noninvasive. The conserved sequence of the pol gene of human immunodeficiency virus 1 was satisfactorily detected via this strategy.     

Microgravimetric DNA sensor based on quartz crystal microbalance: comparison of oligonucleotide immobilization methods and the application in genetic diagnosis

We report on the study of immobilization DNA probes onto quartz crystal oscillators by self-assembly technique to form variety types of mono- and multi-layered sensing films towards the realization of DNA diagnostic devices. A 18-mer DNA probe complementary to the site of genetic beta-thalassaemia mutations was immobilized on the electrodes of QCM by covalent bonding or electrostatic adsorption on polyelectrolyte films to form mono- or multi-layered sensing films by self-assembled process. Hybridization was induced by exposure of the QCMs immobilized with DNA probe to a test solution containing the target nucleic acid sequences. The kinetics of DNA probe immobilization and hybridization with the fabricated DNA sensors were studied via in-situ frequency changes. The characteristics of QCM sensors containing mono- or multi-layered DNA probe constructed by direct chemical bonding, avidin-biotin interaction or electrostatic adsorption on polyelectrolyte films were compared. Results indicated that the DNA sensing films fabricated by immobilization of biotinylated DNA probe to avidin provide fast sensor response and high hybridization efficiencies. The effects of ionic strength of the buffer solution and the concentration of target nucleic acid used in hybridization were also studied. The fabricated DNA biosensor was used to detect a set of real samples. We conclude that the microgravimetric DNA sensor with its direct detection of amplified products provide a rapid, low cost and convenient diagnostic method for genetic disease.