High-density fiber-optic DNA random microsphere array

A high-density fiber-optic DNA microarray sensor was developed to monitor multiple DNA sequences in parallel. Microarrays were prepared by randomly distributing DNA probe-functionalized 3.1-microm-diameter microspheres in an array of wells etched in a 500-microm-diameter optical imaging fiber. Registration of the microspheres was performed using an optical encoding scheme and a custom-built imaging system. Hybridization was visualized using fluorescent-labeled DNA targets with a detection limit of 10 fM. Hybridization times of seconds are required for nanomolar target concentrations, and analysis is performed in minutes.     

Chitosan as a polymer for pH-induced DNA capture in a totally aqueous system

A novel DNA solid-phase extraction protocol based on the pH-dependent charge of chitosan was developed specifically for low-volume DNA extraction on microchips. The method uses chitosan-coated beads to extract DNA at pH 5 and release it from the chitosan at pH 9. DNA extraction efficiency as high as 92% could be attained, even from complex samples such as human blood containing significant amounts of protein. Using this method, PCR inhibitors that are typically used in DNA extraction procedures (e.g., chaotropic salts, 2-propanol) can be avoided, making the method more conducive to downstream sample processing using PCR. A high-density multichannel microchip device was then fabricated and the microchannels coated with chitosan for DNA extraction in an open channel configuration without the need for an additional stationary phase. This design provided a relatively high surface area-to-volume ratio for extraction, while retaining the low flow resistance commensurate with open channels. With a flow rate of approximately 1 microL/min during the extraction, the total extraction time was less than 10 min, with most of the DNA recovered in the first 2 microL of elution buffer. Using the microchip device, extraction efficiencies for lambda-phage DNA and human genomic DNA were as high as 67 and 63%, respectively. Human genomic DNA from whole blood samples could be extracted in 10 min with an extraction efficiency of 75 +/- 4% (n = 3), and the purified DNA was suitable for PCR amplification of a fragment of the gelsolin gene. The combination of an entirely aqueous DNA extraction method with a high-density, low-flow resistance microchannel pattern sets the stage for future integration into microfluidic genomic analysis devices.     

SPR imaging measurements of 1-D and 2-D DNA microarrays created from microfluidic channels on gold thin films

Microfluidic channels fabricated from poly(dimethylsiloxane) (PDMS) are employed in surface plasmon resonance imaging experiments for the detection of DNA and RNA adsorption onto chemically modified gold surfaces. The PDMS microchannels are used to (i) fabricate "1-D" single-stranded DNA (ssDNA) line arrays that are used in SPR imaging experiments of oligonucleotide hybridization adsorption and (ii) create "2-D" DNA hybridization arrays in which a second set of PDMS microchannels are placed perpendicular to a 1-D line array in order to deliver target oligonucleotide solutions. In the 1-D line array experiments, the total sample volume is 500 microL; in the 2-D DNA array experiments, this volume is reduced to 1 microL. As a demonstration of the utility of these microfluidic arrays, a 2-D DNA array is used to detect a 20-fmol sample of in vitro transcribed RNA from the uidA gene of a transgenic Arabidopsis thaliana plant. It is also shown that this array fabrication method can be used for fluorescence measurements on chemically modified gold surfaces.     

Escherichia coli genosensor based on polyaniline

Avidin-modified polyaniline (PANI) electrochemically deposited onto a Pt disk electrode has been utilized for direct detection of Escherichia coli by immobilizing a 5'-biotin-labeled E. coli probe (BdE) using a differential pulse voltammetric technique in the presence of methylene blue as a DNA hybridization indicator. Depending on the target sample and the sonication time, this BdE-avidin-PANI bioelectrode can be utilized to electrochemically detect a complementary target probe (0.009 ng/microL), E. coli genomic DNA (0.01 ng/microL) and 11 E. coli cells/mL in 60 s to 14 min (hybridization time) without using PCR and can be used 5-7 times at temperatures of 30-45 degrees C.     

High-density fiber-optic genosensor microsphere array capable of zeptomole detection limits

The detection limit of a fiber-optic microsensor array was investigated for simultaneous detection of multiple DNA sequences. A random array composed of oligonucleotide-functionalized 3.1-microm-diameter microspheres on the distal face of a 500-microm etched imaging fiber was monitored for binding to fluorescently labeled complementary DNA sequences. Inherent sensor redundancy in the microarray allows the use of multiple microspheres to increase the signal-to-noise ratio, further enhancing the detection capabilities. Specific hybridization was observed for each of three sequences in an array yielding a detection limit of 10(-21) mol (approximately 600 DNA molecules).     

Fiber-optic microsphere-based arrays for multiplexed biological warfare agent detection

We report a multiplexed high-density DNA array capable of rapid, sensitive, and reliable identification of potential biological warfare agents. An optical fiber bundle containing 6000 individual 3.1-mum-diameter fibers was chemically etched to yield microwells and used as the substrate for the array. Eighteen different 50-mer single-stranded DNA probes were covalently attached to 3.1-mum microspheres. Probe sequences were designed for Bacillus anthracis, Yersinia pestis, Francisella tularensis, Brucella melitensis, Clostridium botulinum, Vaccinia virus, and one biological warfare agent (BWA) simulant, Bacillus thuringiensis kurstaki. The microspheres were distributed into the microwells to form a randomized multiplexed high-density DNA array. A detection limit of 10 fM in a 50-microL sample volume was achieved within 30 min of hybridization for B. anthracis, Y. pestis, Vaccinia virus, and B. thuringiensis kurstaki. We used both specific responses of probes upon hybridization to complementary targets as well as response patterns of the multiplexed array to identify BWAs with high accuracy. We demonstrated the application of this multiplexed high-density DNA array for parallel identification of target BWAs in spiked sewage samples after PCR amplification. The array's miniaturized feature size, fabrication flexibility, reusability, and high reproducibility may enable this array platform to be integrated into a highly sensitive, specific, and reliable portable instrument for in situ BWA detection.     

Array-based binary analysis for bacterial typing

An allele-specific oligonucleotide microarray was developed for rapid typing of pathogens based on analysis of genomic variations. Using a panel of Escherichia coli strains as a model system, selected loci were sequenced to uncover differences, such as single- or multiple-nucleotide polymorphisms as well as insertion/deletions (indels). While typical genomic profiling experiments employ specific sequences targeted to genomic DNA unique to a single strain or virulent gene, the present array is designed to type bacteria based on a patterned signature response across multiple loci. In the signature concept, all strains are interrogated by hybridizing their amplified DNA to an array containing multiple probe sequences. Allele-specific oligonucleotide probe sequences targeting each of these variable regions were synthesized and included in a custom fiber-optic array. For each locus, a set of specific probe sequences is selected, such that hybridization gives a binary signal/no signal response to each of the probes. Using this strategy for multiple loci, many pathogens or microorganisms could be classified using a limited number of probes. Because of the advantages of the fiber-optic array platform over other array formats, including sensitivity and speed, the platform described in this paper is capable of supporting a high-throughput diagnostic strategy.     

Detection of Salmonella spp. using microsphere-based, fiber-optic DNA microarrays

Salmonella spp. are one of the most problematic food pathogens in public health, as they are responsible for food poisoning associated with contamination of meat, poultry, and eggs. Thus, rapid and sensitive detection of Salmonella spp. is required to ensure food safety. In this study, a fiber-optic DNA microarray using microsphere-immobilized oligonucleotide probes specific for the Salmonella invA and spvB genes was developed for detection of Salmonella spp. Microarrays were prepared by randomly distributing DNA probe-functionalized microspheres (3.1-microm diameter) into microwells created by etching optical fiber bundles. Hybridization of the probe-functionalized microspheres to target DNA from Salmonella was performed and visualized using Cy3-labeled secondary probes in a sandwich-type assay format. In this study, 10(3)-10(4) cfu/mL of the target organism could be detected after 1-h hybridization without any additional amplification. The DNA microarray showed no cross-reactivity with other common food pathogens, including E. coli and Y. enterocolitica, and could even detect Salmonella spp. from cocktails of bacterial strains with only moderate loss of sensitivity due to nonspecific binding. This work suggests that fiber-optic DNA microarrays can be used for rapid and sensitive detection of Salmonella spp. Since fiber-optic microarrays can be prepared with different probes, this approach could also enable the simultaneous detection of multiple food pathogens.     

Polymer microfluidic chips with integrated waveguides for reading microarrays

A microfluidic chip with an integrated planar waveguide was fabricated in poly(methyl methacrylate), PMMA, using a single-step, double-sided hot-embossing approach. The waveguide was embedded in air on three sides, the solution being interrogated on the fourth. DNA probes were covalently attached to the waveguide surface by plasma activating the PMMA and the use of carbodiimide coupling chemistry. Successful hybridization events were read using evanescent excitation monitored by an imaging microscope, which offered high spatial resolution (2 microm) and a large field-of-view (20 mm diameter field-of-view), providing imaging of the entire array without scanning. The application of the microfluidic/waveguide assembly was demonstrated by detecting low abundant point mutations; insertion C mutations in BRCA1 genes associated with breast cancer were analyzed using a universal array coupled to an allele-specific ligation assay. DNA probes consisting of amine-terminated oligonucleotides were printed inside the microfluidic channel using a noncontact microspotter. Mutant and wild-type genomic DNAs of BRCA1 were PCR (polymerase chain reaction) amplified, with the amplicons subjected to ligation detection reactions (LDRs). LDR solutions were allowed to flow over the microarray positioned on the polymer waveguide with successful ligation events discerned through fluorescence signatures present at certain locations of the array. The microfluidic/waveguide assembly could detect polymorphisms present at <1% of the total DNA content.     

Dynamic DNA hybridization on a chip using paramagnetic beads

Dynamic DNA hybridization is presented as an approach to perform gene expression analysis. The method is advantageous because of its dynamic supplies of both DNA samples and probes. The approach was demonstrated on a microfluidic platform by incorporating paramagnetic beads as a transportable solid support. A glass chip was fabricated to allow simultaneous interrogation of eight DNA target samples by DNA probes. DNA targets were immobilized on beads via streptavidin-biotin conjugation or base pairing between oligonucleotide residues. The DNA/bead complex was introduced into the device in which hybridization took place with a complementary probe. The hybridized probe was then removed by heat denaturation to allow the DNA sample to be interrogated again by another probe with a different sequence of interest. A pneumatic pumping apparatus was constructed to transport DNA probes and other reagents into the microfluidic device while hydrostatic pumping was used for the introduction of paramagnetic beads with samples. After investigating three types of paramagnetic beads, we found Dynabeads Oligo(dT)25 best suited this application. Targets on the beads could be sequentially interrogated by probes for 12 times, and the hybridization signal was maintained within experimental variation. Demonstration of specific hybridization reactions in an array format was achieved using four synthesized DNA targets in duplicate and five probes in sequence, indicating the potential application of this approach to gene expression analysis.     

Multi-technique comparison of immobilized and hybridized oligonucleotide surface density on commercial amine-reactive microarray slides

To establish a quantitative, corroborative understanding of observed correlations between immobilized probe DNA density on microarray surfaces and target hybridization efficiency in biological samples, we have characterized amine-terminated, single-stranded DNA probes attached to amine-reactive commercial microarray slides and complementary DNA target hybridization using fluorescence imaging, X-ray photoelectron spectroscopy (XPS) and 32P-radiometric assays. Importantly, we have reproduced DNA probe microarray immobilization densities in macroscopic spotted dimensions using high ionic strength, high-concentration DNA probe solutions to permit direct XPS surface analysis of DNA surface chemistry with good reliability and reproducibility. Target capture hybridization efficiency with complementary DNA exhibited an optimum value at intermediate DNA probe immobilization densities. The macroscopic array model provides a new platform for the study of DNA surface chemistry using highly sensitive, quantitative surface analytical techniques (e.g., XPS, ToF-SIMS). Sensitive 32P-DNA radiometric density measurements were calibrated with more routine XPS DNA signals, facilitating future routine DNA density determinations without the use of a hazardous radioactive assay. The objective is to provide new insight into different surface chemistry influences on immobilized DNA probe environments that affect target capture efficiency from solution to improve microarray assay performance.     

High-sensitivity detection of DNA hybridization on microarrays using resonance light scattering

The application of resonance light scattering (RLS) particles for high-sensitivity detection of DNA hybridization on cDNA microarrays is demonstrated. Arrays composed of approximately 2000 human genes ("targets") were hybridized with colabeled (Cy3 and biotin) human lung cDNA probes at concentrations ranging from 8.3 ng/microL to 16.7 pg/microL. After hybridization, the arrays were imaged using a fluorescence scanner. The arrays were then treated with 80-nm-diameter gold RLS Particles coated with anti-biotin antibodies and imaged in a white light, CCD-based imaging system. At low probe concentrations, significantly more genes were detected by RLS compared to labeling by Cy3. For example, for hybridizations with a probe concentration of 83.3 pg/microL, approximately 1150 positive genes were detected using RLS compared to approximately 110 positive genes detected with Cy3. In a differential gene expression experiment using human lung and leukemia RNA samples, similar differential expression profiles were obtained for labeling by RLS and fluorescence technologies. The use of RLS Particles is particularly attractive for detection and identification of low-abundance mRNAs and for those applications in which the amount of sample is limited.     

Ligase detection reaction/hybridization assays using three-dimensional microfluidic networks for the detection of low-abundant DNA point mutations

We have fabricated a flow-through biochip assembly that consisted of two different microchips: (1) a polycarbonate (PC) chip for performing an allele-specific ligation detection reaction (LDR) and (2) a poly(methyl methacrylate) (PMMA) chip for the detection of the LDR products using an universal array platform. The operation of the device was demonstrated by detecting low-abundant DNA mutations in gene fragments (K-ras) that carry point mutations with high diagnostic value for colorectal cancers. The PC microchip was used for the LDR in a continuous-flow format, in which two primers (discriminating primer that carried the complement base to the mutation being interrogated and a common primer) that flanked the point mutation and were ligated only when the particular mutation was present in the genomic DNA. The miniaturized reactor architecture allowed enhanced reaction speed due to its high surface-to-volume ratio and efficient thermal management capabilities. A PMMA chip was employed as the microarray device, where zip code sequences (24-mers), which were complementary to sequences present on the target, were microprinted into fluidic channels embossed into the PMMA substrate. Microfluidic addressing of the array reduced the hybridization time significantly through enhanced mass transport to the surface-tethered zip code probes. The two microchips were assembled as a single integrated unit with a novel interconnect concept to produce the flow-through microfluidic biochip. A microgasket, fabricated from an elastomer poly(dimethylsiloxane) with a total volume of the interconnecting assembly of <200 nL, was used as the interconnect between the two chips to produce the three-dimensional microfluidic network. We successfully demonstrated the ability to detect one mutant DNA in 100 normal sequences with the biochip assembly. The LDR/hybridization assay using the assembly performed the entire assay at a relatively fast processing speed: 6.5 min for on-chip LDR, 10 min for washing, and 2.6 min for fluorescence scanning (total processing time 19.1 min) and could screen multiple mutations simultaneously.     

An integrated microfluidic device for rapid cell lysis and DNA purification of epithelial cell samples

In this paper, we describe the design and fabrication of a microfluidic device for cell lysis and DNA purification, and the results of device tests using a real sample of buccal cells. Cell lysis was thermally executed for two minutes at 80 degrees C in a serpentine type microreactor (20 microL) using an Au microheater with a microsensor. The DNA was then mixed with other residual products and purified by a new filtration process involving micropillars and 50-80 microm microbeads. The entire process of sample loading, cell lysis, DNA purification, and sample extraction was successfully completed in the microchip within five minutes. Sample preparation within the microchip was verified by performing a SY158 gene PCR analysis and gel electrophoresis on the products obtained from the chip. The new purification method enhanced DNA purity from 0.93 to 1.62 after purification.     

Hybridization reaction kinetics of DNA probes on beads arrayed in a capillary enhanced by turbulent flow

The hybridization reaction kinetics of DNA probes on beads arrayed in a capillary was investigated experimentally and theoretically by using fluid mechanical methods. A device was prepared to contain DNA probes conjugated on 103-microm-diameter beads that were queued in a 150-microm-diameter capillary. The hybridization experiments were performed by introducing sample into the capillary and moving it with a one-way or a reciprocal flow. From the relation between Reynolds number and the resistance coefficient of the system, we found that the flow in the system was turbulent and not laminar as has been said of other microfluidic devices. The reaction efficiency was estimated using a mass-transfer coefficient derived from Chilton-Colburn's analogy. The estimate agreed well with the experimental data. A diffusion equation under laminar assumption was also solved, but this estimated value was 4.0-10.4 times smaller than the experimental data. Using the device achieved a hybridization efficiency as high as approximately 90% in 10 min. It was concluded that the high hybridization performance of the device resulted from turbulent flow and that the flow compensated the slow molecular diffusion. Using this bead-included structure resulted in a rapid and effective reaction at the solid-liquid interface, and the device seems very promising for many future applications.     

A microfluidic platform using molecular beacon-based temperature calibration for thermal dehybridization of surface-bound DNA

This work presents a simple microfluidic device with an integrated thin-film heater for studies of DNA hybridization kinetics and double-stranded DNA melting temperature measurements. The heating characteristics of the device were evaluated with a novel, noninvasive indirect technique using molecular beacons as temperature probes inside reaction chambers. This is the first microfluidic device in which thermal dehybridization of surface-bound oligonucleotides was performed for measurement of double-stranded DNA melting temperatures with +/- 1 degrees C precision. Surface modification and oligonucleotide immobilization were performed by continuously flowing reagents through the microchannels. The resulting reproducibility of oligonucleotide surface densities, at 9% RSD, was better than for the same modification chemistries on glass slides in unstirred reagent solutions (RSD=20%). Moreover, the surface density of immobilized DNA probe molecules could be varied controllably by changing the concentration of the reagent solution used for immobilization. Thus, excellent control of surface characteristics was made possible, something which is often difficult to achieve with larger devices. Solid-phase hybridization reactions, a fundamental aspect of microarray technologies often taking several hours in conventional systems, were reduced to minutes in this device. It was also possible to determine forward rate constants for hybridization, k. These varied from 820,000 to 72,000 M(-1) s(-1), decreasing as surface densities increased. Surface densities could therefore be optimized to obtain rapid hybridization using such an approach. Taken together, this combined microfluidic/small-volume heating approach represents a powerful tool for surface-based DNA analysis.     

The detection of p53 gene via fluorescence quenching of quantum dot in microfluidic chip

Recently, quantum dot (QD) has been used widely in the field of bio assay including cell imaging, biomarker, and fluorescence resonance energy transfer (FRET) sensor. The DNA assay without labeling process has several advantages including low cost, short time, and simplicity. Microbeads of agarose, glass, and polystyrene have been used as a solid support in microfluidic devices to trace molecules. The main advantages of microfluidics include high throughput, short analysis time, small sample volume, and high sensitivity. PDMS based microfluidic chips were prepared for the detection of p53 gene by using QD-DNA conjugate. The microfluidic chip has a weir in the channel to trap microbeads to which QD-DNA probes bind. Carboxylated CdSe/ZnS QDs (wavelength of emission: 605 nm) could bind to microbeads of polystyrene/divinyl benzene via EDC/NHS crosslinking reaction. The target gene and DNA intercalating dye (TOTO-3) were loaded into the micro-channel. Fluorescence quenching from QDs by intercalating dye was observed after hybridization of DNA at the weir in the channel of microfluidic chip. The fluorescence quenching from QDs by TOTO-3 was dependent on the concentration of target gene. This experiment shows the possibility of rapid detection of DNA via bead-QD complex on microfluidic chip.     

Detection of viable Cryptosporidium parvum using DNA-modified liposomes in a microfluidic chip

This paper describes a microfluidic chip that enables the detection of viable Cryptosporidium parvum by detecting RNA amplified by nucleic-acid-sequence-based amplification (NASBA). The mRNA serving as the template for NASBA is produced by viable C. parvum as a response to heat shock. The chip utilizes sandwich hybridization by hybridizing the NASBA-generated amplicon between capture probes and reporter probes in a microfluidic channel. The reporter probes are tagged with carboxyfluorescein-filled liposomes. These liposomes, which generate fluorescence intensities not obtainable from single fluorophores, allow the detection of very low concentrations of targets. The limit of detection of the chip is 5 fmol of amplicon in 12.5 microL of sample solution. Samples of C. parvum that underwent heat shock, extraction, and amplification by NASBA were successfully detected and clearly distinguishable from controls. This was accomplished without having to separate the amplified RNA from the NASBA mixture. The microfluidic chip can easily be modified to detect other pathogens. We envision its use in mu-total analysis systems (mu-TAS) and in DNA-array chips utilized for environmental monitoring of pathogens.     

Microfluidic capillary system for immunoaffinity separations of C-reactive protein in human serum and cerebrospinal fluid

A miniaturized system based on microfluidic capillaries is presented for point-of-care testing and clinical assessment. The approach relies on microsyringe pump-generated flow to deliver reagents and immunoaffinity chromatography to isolate the antigen from biological matrixes. Capillary sandwich immunoassays for C-reactive protein (CRP) were demonstrated in human serum and cerebrospinal fluid (CSF), which are relevant matrixes for cardiovascular disease risk and meningitis research, respectively. Capillaries packed with antibody-coated silica beads were used to capture CRP from the matrix and a second, dye-labeled antibody was introduced to form a sandwich complex. An acidic elution buffer dissociated the antibody-antigen complexes, and the labeled antibody was detected with diode laser-induced fluorescence. Four parameter logistic functions and % relative error plots were used to model and assess the data. The calibration ranges for CRP were 0.05-3.0 microg/mL in 1:10 diluted serum and 0.01-30 microg/mL in undiluted CSF. The microfluidic apparatus employed a flow rate of 2 microL/min and a sample injection volume of 250 nL. Since it was not necessary to reach antibody-antigen reaction equilibrium and the assay platform dimensions were minimal, run times were as short as 10 min.