Automated and parallel microfluidic DNA extraction with integrated pneumatic microvalves/pumps and reusable open-channel columns

A novel microfluidic DNA extraction protocol based on integrated diaphragm microvalves/pumps and silica-deposited open-channel columns was developed specifically for automated and parallel DNA solid-phase extraction (SPE). The method uses microfluidic chips with a sandwiched structure containing three layers, which are the upper fluidic layer with surface-deposited silica on glass open channels as the extraction phase, the lower actuation layer with valve actuation channels on a glass wafer, and the middle poly(dimethylsiloxane) (PDMS) membrane for reversible bonding of the two glass substrates. These two glass substrates can be reused after thoroughly cleaning and the PDMS membrane can be replaced conveniently, which could effectively decrease the time and cost of chip manufacturing. The normally closed microvalves/pumps were used to automatically control all processes of the on-chip DNA SPE without cross-contamination and leakage, enabling the processing of multiple samples in parallel without changing the microvalve control module. Using the microchip device with integrated microvalves/pumps, automated, programmable, and simultaneous λ-DNA extractions from different samples could be attained, even from complex solutions such as human blood, and the silica-deposited open-channel columns could be reused stably and reliably. Results have demonstrated that most of the eluted λ-DNA was recovered in the second 2 µL of elution buffer with high-purity suitable for successful polymerase chain reaction amplification, making it possible for further integration into microfluidic devices for fully functional and high-throughput genetic analysis.     

Development of a real-world direct interface for integrated DNA extraction and amplification in a microfluidic device

Integrated DNA extraction and amplification have been carried out in a microfluidic device using electro-osmotic pumping (EOP) for fluidic control. All the necessary reagents for performing both DNA extraction and polymerase chain reaction (PCR) amplification were pre-loaded into the microfluidic device following encapsulation in agarose gel. Buccal cells were collected using OmniSwabs [Whatman?, UK] and manually added to a chaotropic binding/lysis solution pre-loaded into the microfluidic device. The released DNA was then adsorbed onto a silica monolith contained within the DNA extraction chamber and the microfluidic device sealed using polymer electrodes. The washing and elution steps for DNA extraction were carried out using EOP, resulting in transfer of the eluted DNA into the PCR chamber. Thermal cycling, achieved using a Peltier element, resulted in amplification of the Amelogenin locus as confirmed using conventional capillary gel electrophoresis. It was demonstrated that the PCR reagents could be stored in the microfluidic device for at least 8 weeks at 4 °C with no significant loss of activity. Such methodology lends itself to the production of 'ready-to-use' microfluidic devices containing all the necessary reagents for sample processing, with many obvious applications in forensics and clinical medicine.     

A valveless microfluidic device for integrated solid phase extraction and polymerase chain reaction for short tandem repeat (STR) analysis

A valveless microdevice has been developed for the integration of solid phase extraction (SPE) and polymerase chain reaction (PCR) on a single chip for the short tandem repeat (STR) analysis of DNA from a biological sample. The device consists of two domains--a SPE domain filled with silica beads as a solid phase and a PCR domain with an ~500 nL reaction chamber. DNA from buccal swabs was purified and amplified using the integrated device and a full STR profile (16 loci) resulted. The 16 loci Identifiler? multiplex amplification was performed using a non-contact infrared (IR)-mediated PCR system built in-house, after syringe-driven SPE, providing an ~80-fold and 2.2-fold reduction in sample and reagent volumes consumed, respectively, as well as an ~5-fold reduction in the overall analysis time in comparison to conventional analysis. Results indicate that the SPE-PCR system can be used for many applications requiring genetic analysis, and the future addition of microchip electrophoresis (ME) to the system would allow for the complete processing of biological samples for forensic STR analysis on a single microdevice.     

Developments toward a complete micro-total analysis system for Duchenne muscular dystrophy diagnosis

The diagnosis of Duchenne muscular dystrophy (DMD) has historically utilized either PCR or requires Southern blot analysis, a southern blot analysis, however, is not amenable to incorporation in a microdevice format. A PCR amplification-based method has been developed, and we have previously coupled this amplification with microchip separation of the PCR fragments for DMD diagnosis. Diagnoses of affected patients were performed by comparing exon concentrations to those of control samples amplified at the same time. To accurately identify mutations in patient samples, this work established normal ranges for the concentration of each amplified exon fragment using control samples amplified over successive days. Our studies show that the number of cycles used in the amplification process affects this range. Affected patient samples were analyzed using these normal ranges and the mutations detected by Southern blot analysis were also diagnosed using the microchip separation method.

Employing the microchip separation method decreases the time required for the analysis, but the time required for DNA purification and PCR amplification must also be decreased for faster total analysis of patient samples. Development of microchip methods for these processing steps is one approach for reducing the individual times, while also providing the possibility of integrating these steps in a single device. Here we report on the microchip extraction of genomic DNA from whole blood using a novel sol–gel matrix that is easily formed in microdevices. IR-mediated PCR amplification of a β-globin fragment from genomic DNA followed by electrophoretic analysis on a single integrated microdevice is presented for the first time. Work towards the development of a micro-total analysis device for DMD diagnosis, through integration of all processing steps on a single device, is also discussed.     

Microchip-based one step DNA extraction and real-time PCR in one chamber for rapid pathogen identification

Optimal detection of a pathogen present in biological samples depends on the ability to extract DNA molecules rapidly and efficiently. In this paper, we report a novel method for efficient DNA extraction and subsequent real-time detection in a single microchip by combining laser irradiation and magnetic beads. By using a 808 nm laser and carboxyl-terminated magnetic beads, we demonstrate that a single pulse of 40 seconds lysed pathogens including E. coli and Gram-positive bacterial cells as well as the hepatitis B virus mixed with human serum. We further demonstrate that the real-time pathogen detection was performed with pre-mixed PCR reagents in a real-time PCR machine using the same microchip, after laser irradiation in a hand-held device equipped with a small laser diode. These results suggest that the new sample preparation method is well suited to be integrated into lab-on-a-chip application of the pathogen detection system.     

Capillary electrochromatography and preconcentration of neutral compounds on poly(dimethylsiloxane) microchips

Capillary electrochromatography (CEC) and preconcentration of neutral compounds have been realized on poly(dimethylsiloxane) (PDMS) microchips. The channels are coated with polyelectrolyte multilayers to avoid absorption of hydrophobic analytes into PDMS. The structures of a microchip include an injector and a bead chamber with integrated frits, where the particles of the stationary phase are completely retained. Dimensions of the frit structures are 25 micro mx20 micro m, and the space between the structures is 3 micro m. A neutral compound, BODIPY, that is strongly absorbed into native PDMS, is successfully and selectively retained on octadecylsilane-coated silica beads in the bead chamber with a concentration enhancement of up to 100 times and eluted with elution buffer solution containing 70% acetonitrile. Preconcentrations and CEC separations of coumarins have been conducted with the same device and achieved complete separations in less than 50 s.     

N-Methylimidazolium modified magnetic particles as adsorbents for solid phase extraction of genomic deoxyribonucleic acid from genetically modified soybeans

N-Methylimidazolium modified magnetic particles (MIm-MPs) were prepared and applied in the solid phase extraction of genomic deoxyribonucleic acid (DNA) from genetically modified soybeans. The adsorption of MIm-MPs for DNA mainly resulted from the strong electrostatic interaction between the positively charged MPs and the negatively charged DNA. The elution of DNA from MPs–DNA conjugates using phosphate buffer resulted from the stronger electrostatic interaction of phosphate ions with MPs than DNA. In the extraction procedure, no harmful reagents (e.g. phenol, chloroform and isopropanol, etc.) used, high yield (10.4 μg DNA per 30 mg sample) and high quality (A₂₆₀/A₂₈₀ = 1.82) of DNA can be realized. The as-prepared DNA was used as template for duplex-polymerase chain reaction (PCR) and the PCR products were analyzed by a sieving capillary electrophoresis method. Quick and high quality extraction of DNA template, and fast and high resolution detection of duplex PCR products can be realized using the developed method. No toxic reagents are used throughout the method.     

Towards a portable microchip system with integrated thermal control and polymer waveguides for real-time PCR

A novel real-time PCR microchip platform with integrated thermal system and polymer waveguides has been developed. The integrated polymer optical system for real-time monitoring of PCR was fabricated in the same SU-8 layer as the PCR chamber, without additional masking steps. Two suitable DNA binding dyes, SYTOX Orange and TO-PRO-3, were selected and tested for the real-time PCR processes. As a model, cadF gene of Campylobacter jejuni has been amplified on the microchip. Using the integrated optical system of the real-time PCR microchip, the measured cycle threshold values of the real-time PCR performed with a dilution series of C. jejuni DNA template (2 to 200 pg/microL) could be quantitatively detected and compared with a conventional post-PCR analysis (DNA gel electrophoresis). The presented approach provided reliable real-time quantitative information of the PCR amplification of the targeted gene. With the integrated optical system, the reaction dynamics at any location inside the micro reaction chamber can easily be monitored.     

Microaffinity purification of proteins based on photolytic elution: toward an efficient microbead affinity chromatography on a chip

A bead affinity chromatography system, which was based on the photolytic elution method, was integrated into a glass-silicon microchip to purify specific target proteins. CutiCore beads, which were coupled with a photo-cleavable ligand, such as biotin and an RNA aptamer, were introduced into a filter chamber in the microchip. The protein mixture containing target protein labeled with fluorescein isothiocyanate (FITC) was then passed through the packed affinity beads in the microchamber by pressure-driven flow. During the process, the adsorbed protein on the bead was monitored by fluorescence. The concentrated target protein on the affinity bead was released by simple irradiation with UV light at a wavelength of 360 nm, and subsequently eluted with the phosphate buffer flow. The eluted target protein was quantitatively detected via the fluorescence intensity measurements at the downstream of the capillary connected to the outlet of the microchip. The microaffinity purification allowed for a successful method for the identification of specific target proteins from a protein mixture. In addition, the feasibility of this system for use as a diagnosis chip was demonstrated.     

Continuous microfluidic DNA extraction using phase-transfer magnetophoresis

This paper reports a novel microfluidic-chip based platform using "phase-transfer magnetophoresis" enabling continuous biomolecule processing. As an example we demonstrate for the first time continuous DNA extraction from cell lysate on a microfluidic chip. After mixing bacterial Escherichia coli culture with superparamagnetic bead suspension, lysis and binding buffers, DNA is released from cells and captured by the beads. These DNA carrying beads are continuously transported across the interfaces between co-flowing laminar streams of sample mixture, washing and elution buffer. Bead actuation is achieved by applying a time-varying magnetic field generated by a rotating permanent magnet. Flagella-like chains of magnetic beads are formed and transported along the microfluidic channels by an interplay of fluid drag and periodic magnetic entrapment. The turnover time for DNA extraction was approximately 2 minutes with a sample flow rate of 0.75 μl s(-1) and an eluate flow rate of 0.35 μl s(-1). DNA recovery was 147% (on average) compared to bead based batch-wise extraction in reference tubes within a dilution series experiment over 7 orders of magnitude. The novel platform is suggested for automation of various magnetic bead based applications that require continuous sample processing, e.g. continuous DNA extraction for flow-through PCR, capture and analysis of cells and continuous immunoassays. Potential applications are seen in the field of biological safety monitoring, bioprocess control, environmental monitoring, or epidemiological studies such as monitoring the load of antibiotic resistant bacteria in waste water from hospitals.     

多孔磁性硅胶微球的制备及其在基因组脱氧核糖核酸提取中的应用

采用模板法制备了多孔磁性硅胶微球,用于生物样品中基因组脱氧核糖核酸(DNA)的分离纯化。以球形和无定型硅胶为对照,考察了吸附液组成和洗脱时间等实验参数对小牛胸腺基因组DNA在磁性硅胶固相载体上的提取回收率的影响。实验结果表明:20%(W/V)聚乙二醇和2 mol/L氯化钠,洗脱10 m in,DNA的回收率可达80%;采用简单的细胞裂解体系和合适的吸附液组成,磁性微球应用于酿酒酵母中基因组DNA的提取,得到了平均长度约为5 kb、A260/A280大于1.77的高纯度DNA片段。     

Rapid microvolume PCR of DNA confirmed by microchip electrophoresis.

PCR is an indispensable technique used in DNA analysis. However, with the traditional methods, the time spent on amplification and the subsequent analysis of PCR products is generally long. Therefore, it is essential to improve these two steps so that the whole procedure can be made faster. In the present work, with lambda-DNA as the control template, the amplification of 300-bp fragment could be completed within 37 s with capillary reaction chambers of LightCycler, and the following analysis of PCR products could be completed within 120 s with microchip electrophoresis as the detector. Since the high detection sensitivity of microchip electrophoresis, PCR products with template concentration as low as 5 fg/microL could be detected only after 435 s of amplification. In addition, based on additional optimized conditions simulated by CoventorWare, PCR microchips with distinct structure of the reaction chambers have been designed and successfully applied to the amplification of 300-bp fragment. By comparison, those chambers with ellipse and racket shapes were found to offer very high amplification efficiency. All of these results demonstrate the promise of integrating PCR and electrophoresis on microchip for developing easy-carrying instruments for the fast in situ detection of DNA.     

A Parametric Study of Sample Lysis and DNA Purification Techniques for Use in Automated Devices

Abstract

We present a parametric study on the efficiency of several automatable procedures for the extraction and purification of DNA from a variety of pathogens. Based on the results of this work, an optimized protocol has been developed for use with both spiked buffers and nasal wash. All steps of this protocol are suitable for incorporation into a field-portable, automated sample preparation device. From introduction of the sample to elution of DNA, the entire process was completed in less than 60 min, and the time could be reduced further by automation. The recovered DNA is of sufficient quality for real-time or multiplex PCR amplification. The protocol was demonstrated on nasal wash samples spiked with E. coli containing the J7R and crmB genes. Subsequent testing on resequencing microarrays correctly identified the samples as Variola major virus.     

Integration of the cleanup process: pretreatment of polycyclic aromatic hydrocarbons from diesel exhaust particles on silica gel beads in a microchannel.

This paper presents an integrated microfluidic system that performs cleanup for polycyclic aromatic hydrocarbons (PAHs) from diesel exhaust particles on silica gel beads in a microchip. A column chromatography phase was constructed by filling the silica gel beads into a microchannel that had a dam structure 25 microm high. The height of the dam structure was determined according to the rate of the wet etching. This work on the cleanup of PAHs from diesel exhaust particles showed that the microchip-based system has the same performance as the conventional method on the solid phase extraction column and has some advantages, such as less reagent consumption and shorter pretreatment time, over the conventional method.     

Quantitative and qualitative analysis of a microfluidic DNA extraction system using a nanoporous AlO(x) membrane

A nanoporous aluminium oxide membrane was integrated into a microfluidic system designed to extract hgDNA (human genomic DNA) from lysed whole blood. The effectiveness of this extraction system was determined by passing known concentrations of purified hgDNA through nanoporous membranes with varying pore sizes and measuring the amount of hgDNA deposited on the membrane while also varying salt concentration in the solution. DNA extraction efficiency increased as the salt concentration increased and nanopore size decreased. Based on these results, hgDNA was extracted from whole blood while varying salt concentration, nanopore size and elution buffer to find the conditions that yield the maximum concentration of hgDNA. The optimal conditions were found to be using a low-salt lysis solution, 100 nm pores, and a cationic elution buffer. Under these conditions the combination of flow and ionic disruption were sufficient to elute the hgDNA from the membrane. The extracted hgDNA sample was analysed and evaluated using PCR (polymerase chain reaction) to determine whether the eluted sample contained PCR inhibition factors. Eluted samples from the microfluidic system were amplified without any inhibition effects. PCR using extracted samples was demonstrated for several genes of interest. This microfluidic DNA extraction system based on embedded membranes will reduce the time, space and reagents needed for DNA analysis in microfluidic systems and will prove valuable for sample preparation in lab-on-a-chip applications.     

Improved manufacture and application of an agarose magnetizable solid-phase support

A simple, semiautomated, nonhazardous procedure for the production of a magnetizable solid-phase support (MSPS) has been developed based on the extrusion of molten agarose-iron oxide mixtures, which enables manufacture of a range of differently sized spherical agarose-iron oxide beads. This system has enabled scale-up of an original manufacture procedure and reproducible preparation of kg quantities of MSPS suitable for biomolecular purifications. An improved protocol for the isolation of plasmid DNA directly from cell lysates using this MSPS, derivatized with diethylaminoethyl (DEAE) groups, is reported. This involves a modified alkaline lysis, followed by adsorption to and elution from the support, yielding plasmid DNA of a purity comparable with, or better than, other methods of plasmid isolation. Using the same procedure, plasmid DNA can be isolated from bacterial cell culture volumes of 1.5 mL and 100 mL with equal efficiency and purity.     

Preparation of multi-walled carbon nanotubes functionalized magnetic particles by sol-gel technology and its application in extraction of estrogens

Magnetic silica particles coated with hydroxy-terminated multi-walled carbon nanotubes (MWCNTs-OH) were prepared by sol-gel technology, characterized and used for the convenient, rapid and efficient extraction of several estrogens (including diethylstilbestrol, estrone and estriol) in water followed by sweeping micellar electrokinetic chromatography analysis with UV detection. The results demonstrated that sol-gel technology was a feasible, simple and effective technique for the preparation of MWCNTs-OH functionalized magnetic silica particles. The factors affecting the extraction efficiency of estrogens (the pre-activation of magnetic particles, adsorption time, desorption time and the amount of elution solvent) were carefully investigated. The extraction efficiencies for diethylstilbestrol, estrone and estriol were 95.9%, 93.9%, and 52.4%, respectively, under the optimum conditions. The method detection limits for the three estrogens were less than 0.2 ng mL⁻¹. The developed method was applied for the analysis of tap water, mineral water, Pearl River water and honey.     

Solvent-resistant sol-gel polydimethyldiphenylsiloxane coating for on-line hyphenation of capillary microextraction with high-performance liquid chromatography

A sol-gel polydimethyldiphenylsiloxane (PDMDPS) coating was developed for capillary microextraction on-line hyphenated with high-performance liquid chromatography (HPLC). This coating was created using methyltrimethoxysilane (MTMS) as the sol-gel precursor and di-hydroxy-terminated PDMDPS as the sol-gel active polymer. The methyl and phenyl groups on the sol-gel active polymer and the methyl groups on the sol-gel precursor ultimately turned into pendant groups providing the ability to extract non-polar analytes. A 40-cm segment of 0.25mm I.D. fused silica capillary containing the sol-gel PDMDPS coating was installed as an external sampling loop in an HPLC injection port. Aqueous samples containing polycyclic aromatic hydrocarbons (PAHs), aromatic compounds, ketones, and aldehydes were passed through this capillary wherein the analytes were extracted by the sol-gel coating. The extracted analytes were then transferred to the HPLC column using isocratic or gradient elution with an acetonitrile/water mobile phase. This capillary demonstrated excellent extraction capability for non-polar (e.g., polycyclic aromatic hydrocarbons and aromatic compounds) as well as moderately polar compounds, such as aromatic amines, ketones, and aldehydes. The test results indicate that PDMDPS can be successfully immobilized into a sol-gel network and that the resulting solvent-resistant sol-gel organic-inorganic hybrid coating can be effectively used for on-line hyphenation of capillary microextraction with high-performance liquid chromatography. The test results also indicate that the sol-gel PDMDPS coated capillary is resistant to high-temperature solvents, making it suitable for applications in high-temperature HPLC. To the best of our knowledge, this is the first report on the creation of a silica-based sol-gel PDMDPS coating used in capillary microextraction on-line hyphenated to HPLC.     

Microfluidic chip for high efficiency DNA extraction

A high efficiency DNA extraction microchip was designed to extract DNA from lysed cells using immobilized beads and the solution flowing back and forth. This chip was able to increase the extraction efficiency by 2-fold when there was no serum. When serum existed in the solution, the extraction efficiency of immobilized beads was 88-fold higher than that of free beads. The extraction efficiency of the microchip was tested under different conditions and numbers of E. coli cells. When the number of E. coli cells was between 10(6) and 10(8) in 25 microl of whole blood, the extraction efficiency using immobilized beads was only slightly higher than that using free beads (10(0) to 10(1) fold). When the number of E. coli cells was in the range 10(4) to 10(6) in 25 microl of whole blood, the extraction efficiency of immobilized beads was greater than that of the free beads (10(1) to 10(2) fold). When the number of E. coli cells was lower, in the range 10(3) to 10(4) in 25 microl of whole blood, the extraction efficiency of immobilized beads was much higher than that of the free beads (10(2) to 10(3) fold). This study indicated that DNA could be efficiently extracted even when the number of bacterial cells was smaller (10(5) to 10(3)). This microfluidic extraction chip could find potential applications in rare sample genomic study.