Cadmium sulfide-modified GCE for direct signal-amplified sensing of DNA hybridization

A novel DNA hybridization sensor based on nanoparticle CdS modified glass carbon electrode (GCE) was constructed and characterized coupled with Cyclic Voltammogram (CV) and Differential Pulse Voltammogram (DPV) techniques. The mercapto group-linked probe DNA was covalently immobilized onto the CdS layer and exposed to oligonucleotide (ODN) target for hybridization. The structure of DNA sensor was characterized by X-ray diffraction (XRD), field-emission microscopy (FESEM) and X-ray photoelectron spectra (XPS). Sensitive electrical readout achieved by CV and DPV techniques shown that when the target DNA hybridized with probe CdS-ODN conjugates and the double helix formed on the modified electrode, a significant increased response was observed comparing with the bare electrodes. The selectivity of the sensor was tested using a series of matched and certain-point mismatched sequences with concentration grads ranging from 10(-6) microM to 10(1) microM. The signal was in good linear with the minus logarithm of target oligonucleotide concentration with detection limit <1 pM and the optimized target DNA concentration was 10(-6) microM for the signal amplification. Due to great surface properties, the additional negative charges and space resistance of as-prepared CdS nanoparticles, the sensor was able to robustly discriminate the DNA hybridization responses with good sensitivity and stability.     

Monolayer Contact Doping of Silicon Surfaces and Nanowires Using Organophosphorus Compounds

Monolayer Contact Doping (MLCD) is a simple method for doping of surfaces and nanostructures¹. MLCD results in the formation of highly controlled, ultra shallow and sharp doping profiles at the nanometer scale. In MLCD process the dopant source is a monolayer containing dopant atoms.In this article a detailed procedure for surface doping of silicon substrate as well as silicon nanowires is demonstrated. Phosphorus dopant source was formed using tetraethyl methylenediphosphonate monolayer on a silicon substrate. This monolayer containing substrate was brought to contact with a pristine intrinsic silicon target substrate and annealed while in contact. Sheet resistance of the target substrate was measured using 4 point probe. Intrinsic silicon nanowires were synthesized by chemical vapor deposition (CVD) process using a vapor-liquid-solid (VLS) mechanism; gold nanoparticles were used as catalyst for nanowire growth. The nanowires were suspended in ethanol by mild sonication. This suspension was used to dropcast the nanowires on silicon substrate with a silicon nitride dielectric top layer. These nanowires were doped with phosphorus in similar manner as used for the intrinsic silicon wafer. Standard photolithography process was used to fabricate metal electrodes for the formation of nanowire based field effect transistor (NW-FET). The electrical properties of a representative nanowire device were measured by a semiconductor device analyzer and a probe station.     

A highly sensitive molecular structural probe applied to in situ biosensing of metabolites using PEDOT:PSS

A large amount of research within organic biosensors is dominated by organic electrochemical transistors (OECTs) that use conducting polymers such as poly(3,4-ethylene dioxythiophene) doped with poly(styrenesulfonate) (PEDOT:PSS). Despite the recent advances in OECT-based biosensors, the sensing is solely reliant on the amperometric detection of the bioanalytes. This is typically accompanied by large undesirable parasitic electrical signals from the electroactive components in the electrolyte. Herein, we present the use of in situ resonance Raman spectroscopy to probe subtle molecular structural changes of PEDOT:PSS associated with its doping level. We demonstrate how such doping level changes of PEDOT:PSS can be used, for the first time, on operational OECTs for sensitive and selective metabolite sensing while simultaneously performing amperometric detection of the analyte. We test the sensitivity by molecularly sensing a lowest glucose concentration of 0.02 mM in phosphate-buffered saline solution. By changing the electrolyte to cell culture media, the selectivity of in situ resonance Raman spectroscopy is emphasized as it remains unaffected by other electroactive components in the electrolyte. The application of this molecular structural probe highlights the importance of developing biosensing probes that benefit from high sensitivity of the material's structural and electrical properties while being complimentary with the electronic methods of detection.     

Fluorometric identification of 5-methylcytosine modification in DNA: combination of photosensitized oxidation and invasive cleavage

An efficient fluorometric detection system of DNA methylation has been developed by a combination of a photooxidative DNA cleavage reaction with 2-methyl-1,4-naphthoquinone (NQ) chromophore and an invasive cleavage reaction with human Flap endonuclease-1. Enzymatic treatment of a mixture of photochemically fragmented target oligodeoxynucleotides (ODNs) at 5-methylcytosine mC) and hairpin-like probe oligomer possessing a fluorophore (F) and a quencher (D) resulted in a dramatic enhancement of fluorescence. In contrast, fluorescence emission for the ODN containing cytosine but not mC at the target sequence was extremely weak. In addition, by monitoring the fluorescence change, this system allows for the detection of mC in DNA at subfemtomole amounts. This system would provide a highly sensitive protocol for determining the methylation status in DNA by fluorescence emission.     

2'-anthraquinone-conjugated oligonucleotide as an electrochemical probe for DNA mismatch

We previously prepared the oligonucleotides (ODNs) conjugated to an anthraquinone (AQ) group via one carbon linker at the 2'-sugar position. When these modified ODNs bind to cDNA sequences, the AQ moiety can be intercalated into the predetermined base-pair pocket of a duplex DNA. In this paper, 2'-AQ-modified ODNs are shown to be an excellent electrochemical probe to clarify the effect of a mismatch base on the charge transfer (CT) though DNA. Two types of DNA-modified electrodes were constructed by assembly of disulfide-terminated 2'-AQ-ODN duplexes onto gold electrodes. One type of electrodes (system I) contains fully matched base pairs or a single-base mismatch in duplex DNA between the redox center and the electrode. The other (system II) consists of the mismatch but at the outside of the redox center. The modified electrodes were analyzed by cyclic voltammetry to estimate the CT rate through duplex DNA. In system I, the CT rate was found to be approximately 50 s (-1) for the fully matched AQ-ODN duplexes, while the CT rates of the mismatched DNA were considerably slower than that of the fully matched DNA. In system II, the AQ-ODN duplexes showed almost similar CT rates ( approximately 50 s (-1)) for the fully matched DNA and for the mismatched DNAs. The detection of a single-base mismatch was then performed by chronocoulometry (CC). All the DNA duplexes containing a mismatch base in system I gave the reduced electrochemical responses when compared to the fully matched DNA. In particular, the mismatched DNAs including G--A mismatch can be differentiated from fully matched DNA without using any electrochemical catalyst. We further tested the usefulness of single-stranded (ss) AQ-ODN immobilized on a gold electrode in the electrochemical detection of a single-base mismatch through hybridization assay. The ss-AQ-ODN electrodes were immersed in target-containing buffer at room temperature, and the CC measurements were carried out to see the changes in the integrated charge. Within 60 min, the mismatched DNA was clearly distinguishable by the CC differences from the fully matched target. Thus, the electrochemical hybridization assay provides an easy and convenient detection for DNA mutation that does not require any extra reagents, catalyst, target labeling, and washing steps.     

Label-free detection of DNA hybridization based on a novel functionalized conducting polymer

A new functionalized pyrrole monomer, 3-pyrrolylacrylic acid (PAA) was synthesized. It was used to prepare a copolymer with pyrrole, poly(Py-co-PAA), which was investigated by reflective FT-IR, UV-vis spectroscopy and cyclic voltammetry. A label-free DNA sensor was prepared based on a poly(Py-co-PAA) film. Hybridization with complementary and non-complementary DNA targets was studied by electrochemical impedance spectroscopy. Results show a significant increase in the charge-transfer resistance upon addition of complementary target. The impedance spectra were analyzed by using a modified Randles and Ershler equivalent circuit model. The change in charge-transfer resistance that was used as an index of sensor response was found to be linear with logarithmic target concentration in the range of 2 x 10(-9) to 2 x 10(-7)M. The detection limit was 0.98 nM.     

Monitoring cell adhesion by using thickness shear mode acoustic wave sensors

The thickness shear mode (TSM) acoustic wave sensor attached with living cells has been shown to be an effective functional biosensing device to monitor the process of cell adhesion to a surface in real time. In this study, a multilayer sensor model that includes a quartz substrate, a cell-substrate interfacial layer and a cell layer was constructed based on the state of cell adhesion to the substrate. The dynamic process of cell adhesions as a function of cell seeding densities was monitored using the acoustic wave sensor. The mechanisms that are responsible for the frequency and resistance change are discussed according to the predictions of the acoustic wave sensor model. In addition, knowing that the actin cytoskeleton is important for cell adhesion, we investigated the motional resistance change caused by the disruption of actin cytoskeleton induced by fungal toxin cytochalasin D in the human skin fibroblasts. The results indicate that resistance changes are related to the disruption of actin cytoskeleton and dosage-dependent.     

Nucleosides and nucleotides. Part 214: thermal stability of triplexes containing 4'alpha-C-aminoalkyl-2'-deoxynucleosides

In order to develop novel antigene molecules forming thermally stable triplexes with target DNAs and having nuclease resistance properties, we synthesized oligodeoxynucleotides (ODNs) with various lengths of aminoalkyl-linkers at the 4'alpha position of thymidine and the aminoethyl-linker at the 4'alpha position of 2'-deoxy-5-methylcytidine. Thermal stability of triplexes between these ODNs and a DNA duplex was studied by thermal denaturation. The ODNs containing the nucleoside 2 with the aminoethyl-linker or the nucleoside 3 with the aminopropyl-linker thermally stabilized the triplexes, whereas the ODNs containing the nucleoside 1 with the aminomethyl-linker or the nucleoside 4 with the 2-[N-(2-aminoethyl)carbamoyl]oxy]ethyl-linker thermally destabilized the triplexes. The ODNs containing 2 were the most efficient at stabilizing the triplexes with the target DNA. The ODNs containing 4'alpha-C-(2-aminoethyl)-2'-deoxy-5-methylcytidine (5) also efficiently stabilized the triplexes with the target DNA. Stability of the ODN containing 5 to nucleolytic hydrolysis by snake venom phosphodiesterase (a 3'-exonuclease) was studied. It was found that the ODN containing 5 was more resistant to nucleolytic digestion by the enzyme than an unmodified ODN. In a previous paper, we reported that the ODNs containing 2 were more resistant to nucleolytic digestion by DNase I (an endonuclease) than the unmodified ODNs. Thus, it was found that the ODNs containing 4'alpha-C-(2-aminoethyl)-2'-deoxynucleosides were good candidates for antigene molecules.     

Label-free and high-sensitive detection of Salmonella using a surface plasmon resonance DNA-based biosensor

A method based on surface plasmon resonance (SPR) DNA biosensor has been developed for label-free and high-sensitive detection of Salmonella. A biotinylated single-stranded oligonucleotide probe was designed to target a specific sequence in the invA gene of Salmonella and then immobilized onto a streptavidin coated dextran sensor surface. The invA gene was isolated from bacterial cultures and amplified using a modified semi-nested asymmetric polymerase chain reaction (PCR) technique. In order to investigate the hybridization detection, experiments with different concentration of synthetic target DNA sequences have been performed. The calibration curve of synthetic target DNA had good linearity from 5 nM to 1000 nM with a detection limit of 0.5 nM. The proposed method was applied successfully to the detection of single-stranded invA amplicons from three serovars of Salmonella, i.e., Typhimurium, Enterica and Derby, and the responses to PCR products were related to different S. typhimurium concentrations in the range from 10(2) to 10(10) CFU mL(-1). While with this system to detect E. coli and S. aureus, no significant signal was observed, demonstrating good selectivity of the method. In addition, the hybridization can be completed within 15 min, and the excellent sensor surface regeneration allows at least 300 assay cycles without obvious loss of performance.     

Monitoring Redox Conditions with Flow-Based and Fiber Optic Sensors Based on Redox Indicators: Application to Reductive Dehalogenation in a Bioaugmented Soil Column

Redox indicators were employed to monitor redox status in a bioaugmented, sediment-packed column during the dechlorination of tetrachloroethene (PCE) to ethene (ETH). The speciation of the indicators thionine and cresyl violet, immobilized on transparent films, was spectrometrically monitored with a flow sensor based on circulating the column solution through a specially constructed flow cell placed in a conventional spectrometer. A fiber optic redox probe based on immobilized azure C was constructed. A 75-cm column with 4 sets of ports along the column axis at regular intervals was constructed and packed with aquifer material. These ports enabled sampling to determine concentrations of chlorinated ethene species and allowed for in situ or non-invasive monitoring of redox conditions with negligible O ₂ contamination. The flow sensor and fiber optic sensor showed similar responses to redox conditions in the column. After 60 days, complete conversion of PCE to ETH occurred by the end of the column and the redox level indicated by the indicators was consistent throughout the column. Significant formation of vinyl chloride or ETH was observed only after significant reduction of cresyl violet.     

Quantification of methanogens by fluorescence in situ hybridization with oligonucleotide probe

To monitor anaerobic environmental engineering system, new method of quantification for methanogens was tested. It is based on the measurement of specific binding (hybridization) of 16S rRNA-targeted oligonucleotide probe Arc915, performed by fluorescence in situ hybridization (FISH) and quantified by fluorescence spectrometry. Average specific binding of Arc915 probe was 13.4±0.5 amol/cell of autofluorescent methanogens. It was 14.3, 13.3, and 12.9 amol/cell at the log phase, at stationary phase and at the period of cell lysis of batch culture, respectively. Specific binding of Arc915 probe per 1 ml of microbial sludge suspension from anaerobic digester linearly correlated with concentration of autofluorescent cells of methanogens. Coefficient of correlation was 0.95. Specific binding of oligonucleotide probe Arc915 can be used for the comparative estimation of methanogens during anaerobic digestion of organic waste. Specific binding of Arc915 probe was linear function of anaerobic sludge concentration when it was between 1.4 and 14.0 mg/ml. Accuracy of the measurements in this region was from 5 to 12%.     

On-line fluorescence-monitoring of the methanogenic fermentation

On-line in situ fluorescence measurements of the methanogenic fermentation were conducted with reactors receiving either glucose or a mixture of volatile fatty acids as the substrate. The reactors were perturbed from steady-state conditions in order to assess the response of fluorescencemonitoring probes. Two fluorescence-monitoring probes were evaluated over a period of 8 months; they performed in a consistent manner, and their response was not significantly affected by the changes in pH and redox potential encountered during routine reactor operation. A commercially available probe, designed to measure NAD(P)H, demonstrated particular promise for detecting imbalance caused by the entry of air, inhibitor addition and was capable of distinguishing between different substrates. This fluorescence-monitoring probe detected imbalance more rapidly than other on-line measurements such as pH, Eh, or gas production, or off-line measurements such as volatile fatty acid concentration or gas composition. An experimental fluorescence-monitoring probe, designed to measure coenzyme F(420), also showed some promise in this regard. The response of the fluorescence-monitoring probes also revealed details of the metabolic routes in the reactors and the probes represent a useful research tool. For example, a failure to observe the characteristic response of the NAD(P)H-monitoring probe to formate addition during the metabolism of acetate, propionate, or glucose strongly suggests that any formate liberated during their catabolism is degraded via a different route to exogenously added formate.     

Bis-pyrene-labeled oligonucleotides: sequence specificity of excimer and monomer fluorescence changes upon hybridization with DNA

The design, synthesis, and properties of a new pyrene excimer-forming probe of DNA have been described. 2,2-(Aminomethyl)propanediol was converted by the reaction with 1-pyrenebutylic acid to bis-pyrene-modified propanediol as a fluorescent non-nucleosidic linker. The bis-pyrene-modified linker can be incorporated via phosphoramidite chemistry into the 5'-terminal or internal positions of oligonucleotides (ODNs). The terminally modified ODNs showed almost similar affinity for complementary DNA when compared with the corresponding unmodified ODNs. The duplexes containing the bis-pyrene in the main chain exhibited higher melting temperatures relative to the corresponding duplexes containing propanediol linker at the same position. The UV and CD spectral studies indicate that the stacking interactions between the pyrene and DNA bases occur in the internally modified duplex and do not in the terminally modified duplex. The bis-pyrene modified linker itself displays excimer (E at 480 nm) and monomer (M at 380 nm) emission in a quantum yield (QY) of 0.17 and the E/M intensity ratio of 15. Incorporation of this linker into the terminal or internal positions of ODNs reduced the QY (0.003-0.009) and the E/M ratio (0.3-0.8). While small changes in the QY and E/M ratio was obtained in binding of the internally labeled ODNs to DNA, up to 27-fold increase in the QY and 17-fold increase in the E/M ratio was observed upon hybridization of the terminally labeled ODNs with DNA. The excimer and monomer fluorescence changes were found to be sensitive to a mismatch base present in the target DNA. The bis-pyrene-modified ODNs thus provide a sequence-sepcific fluorescent probe of DNA.     

A label-free optical sensor based on nanoporous gold arrays for the detection of oligodeoxynucleotides

Interest in using nanoporous materials for sensing applications has increased. The present study reports a method of preparing well-ordered nanoporous gold arrays using a porous silicon (PSi) template. Gold nanolayer could be electrodeposited on the surface of the PSi template at low electrolysis currents in low concentration of chloroauric acid (HAuCl₄) solution. Surface morphology characterizations and optical measurements revealed that a PSi-templated nanoporous gold (Au–PSi) array well replicated the nanoporous structure and retained the optical properties of PSi. Fourier transform reflectometric interference spectra showed that a characteristic blue-shifted effective optical thickness (EOT) was observed due to the low refractive index of the gold film. An optical DNA biosensor was then fabricated via the self-assembly of single-stranded DNA (ssDNA) with a specific sequence on the surface of Au–PSi. The attachment of ssDNA and its hybridization with target oligonucleotides (ODNs) persistently caused the blue shift of the EOT. Consequently, a relationship between the EOT shift and the ODN concentration was established. The mechanism of the optical response caused by DNA hybridization on the Au–PSi surface was qualitatively explained by the electromagnetic theory and electrochemical impedance spectroscopy (EIS). The lowest detection limit for target ODNs was estimated at around 10⁻¹⁴ mol L⁻¹, when the baseline noise, a variation in the value of EOT is around 5 nm. The fabricated Au–PSi based optical biosensor has potential use in the discovery of new ODN drugs because it will be able to detect the binding event between ODNs and the target DNA.     

Is the in situ accessibility of the 16S rRNA of Escherichia coli for Cy3-labeled oligonucleotide probes predicted by a three-dimensional structure model of the 30S ribosomal subunit?

Systematic studies on the hybridization of fluorescently labeled, rRNA-targeted oligonucleotides have shown strong variations in in situ accessibility. Reliable predictions of target site accessibility would contribute to more-rational design of probes for the identification of individual microbial cells in their natural environments. During the past 3 years, numerous studies of the higher-order structure of the ribosome have advanced our understanding of its spatial conformation. These studies range from the identification of rRNA-rRNA interactions based on covariation analyses to physical imaging of the ribosome for the identification of protein-rRNA interactions. Here we reevaluate our Escherichia coli 16S rRNA in situ accessibility data with regard to a tertiary-structure model of the small subunit of the ribosome. We localized target sequences of 176 oligonucleotides on a 3.0-A-resolution three-dimensional (3D) model of the 30S ribosomal subunit. Little correlation was found between probe hybridization efficiency and the proximity of the probe target region to the surface of the 30S ribosomal subunit model. We attribute this to the fact that fluorescence in situ hybridization is performed on fixed cells containing denatured ribosomes, whereas 3D models of the ribosome are based on its native conformation. The effects of different fixation and hybridization protocols on the fluorescence signals conferred by a set of 10 representative probes were tested. The presence or absence of the strongly denaturing detergent sodium dodecyl sulfate had a much more pronounced effect than a change of fixative from paraformaldehyde to ethanol.     

Culture fluorescence studies on aerobic continuous cultures ofSaccharomyces cerevisiae

Summary Fluorometric measurements were performed in continuous aerobic cultures ofSaccharomyces cerevisiae in order to study the effect of substrate concentration and residence time on the intracellular NADH-level. A modified Beyelermicrofluorometer probe (Beyeler et al. 1981) was used for the experiments. It was possible to use this sensor continuously up to five weeks without problems. The relative NADH-values obtained by the on-line monitoring of the NADH-dependent culture fluorescence were compared to the enzymatically determined NADH-content. Biomass estimation from fluorescence data was performed. During oxidative-reductive catabolism the deviation between calculated and measured data were below 5%. The differences between oxidative and oxidative-reductive catabolism were studied regarding glucose addition, dilution rate increase and aerobic-anaerobic transition. For synchronized continuous cultures, changes in dilution rate resulted in changes of the oscillating behaviour. Flow cytometric studies in comparison with fluorometric studies showed changes in budding behaviour during the oscillations.     

Detection of cadmium by a fiber-optic biosensor based on localized surface plasmon resonance

A novel transmission-based localized surface plasmon resonance (LSPR) fiber-optic probe has been developed to determine the heavy metal cadmium ion (Cd(II)) concentration. The LSPR sensor was constructed by immobilizing phytochelatins (PCs), (gammaGlc-Cys)(8)-Gly, onto gold nanoparticle-modified optical fiber (NM(Au)OF). The optimal immobilizing conditions of PCs on to the NM(Au)OF are 71.6mug/ml PCs in pH 7.4 PBS for 2h. The absorbability (change of light absorption) of the PC-functionalized NM(Au)OF sensor increases to 9% upon changing the Cd(II) level from 1 to 8ppb with a sensitivity of 1.24ppb(-1) and a detection limit of 0.16ppb. The sensor retained 85% of its original activity after nine cycles of deactivation and reactivations. In addition, the sensor retains its activity and gives reproducible results after storage in 5% d-(+)-trehalose dehydrate solution at 4 degrees C for 35 days. The dissociation constant (K(d)) of the immobilized PCs with Cd(II) was about 6.77x10(-8)M. In conclusion, the PCs-functionalized NM(Au)OF sensor can be used to determine the concentration of Cd(II) with high sensitivity.     

A novel homogenous detection method based on the self-assembled DNAzyme labeled DNA probes with SWNT conjugates and its application in detecting pathogen

In this paper, a novel and cost-effective homogeneous detection method was constructed for the detection of genomic DNA and Staphylococcus aureus (S. aureus), based on the noncovalent assembly of DNAzyme-labeled detection probe and single-walled carbon nanotubes (SWNTs). When the target genomic DNA and hemin was existed in the detection solution, the detection probe wrapped on the SWNTs by π-stacking interactions would keep away from SWNTs and form a DNAzyme-self-assembly construction. This DNAzyme construction could catalyze 2,2'-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid) (ABTS2?) and generate a colored product which could lead to the absorbance changes. Hence, according to its catalyzed capacity, the DNAzyme construction could amplify the detection signal. The concentration of target DNA could be quantified by exploiting their optical absorption changes at 414 nm and the concentration limit of detection of the method was 30 nM. And this detection method detected S. aureus quantitatively. In addition, this work proved that the method obtain higher detection sensitivity compared with the method without SWNTs because of the protection profile of SWNTs towards the detection probe.     

In situ observation of spherical DNA assembly in water and the controlled release of bound dyes

Three strands of 30-mer oligodeoxyribonucleotides (ODNs) were designed to form three-way junctions that possess self-complementary sticky ends. The morphology of self-assembled ODNs in water was observed in situ by confocal laser scanning fluorescence microscopy. The three-way junctions self-assembled into spherical assemblies, in accordance with transmission and scanning electron microscopy. The size of nucleospheres was in the range of several tens of nanometers to micrometers, which varied depending on the concentration of ODNs and added salts. Fluorescence images of spherical ODN assemblies suggested that the nucleospheres possess multiwalled structures. The fluorescence of sodium 1-anilinonaphthalene-8-sulfonate in the presence of nucleospheres revealed that the interior of nucleospheres possesses polarity corresponding to that between methanol and ethanol. A dye-inclusion experiment showed that cationic and even anionic dyes were adsorbed to the interior of the nucleospheres. The dye-included nucleospheres released dyes by thermal dissociation or digestion of the constituent ODNs.     

Electrochemical growth of gold nanoparticles on horizontally aligned carbon nanotubes: a new platform for ultrasensitive DNA sensing

A new platform based on electrochemical growth of Au nanoparticles on horizontally aligned single walled carbon nanotube (SWCNT) array was developed for ultrasensitive DNA detection. The as-prepared DNA-functionalized SWCNT-Au platform, in which every gold-coated SWCNT acts as an isolated micro electrode, could detect lower than 10 zmol complimentary 10-base DNA, which corresponded to having 6 DNA molecules in a 1 mL sample solution. For a 1-base mismatched DNA, the experimental detection limit was 100 amol. A linear relationship between the change of charge transfer resistance and target DNA concentration was achieved at low concentration range. Over the extended DNA concentration range, the change of charge transfer resistance was found to have a linear relationship with respect to the logarithm of the target DNA concentration. The sensor also showed great stability and could be conveniently regenerated via dehybridization in hot water. The significant improvement in sensitivity illustrates that combining Au nanoparticles with the on-site fabricated SWCNT array represents a promising platform for achieving ultrasensitive biosensor.