Sequencing of real-world samples using a microfabricated hybrid device having unconstrained straight separation channels

We describe a microfabricated hybrid device that consists of a microfabricated chip containing multiple twin-T injectors attached to an array of capillaries that serve as the separation channels. A new fabrication process was employed to create two differently sized round channels in a chip. Twin-T injectors were formed by the smaller round channels that match the bore of the separation capillaries and separation capillaries were incorporated to the injectors through the larger round channels that match the outer diameter of the capillaries. This allows for a minimum dead volume and provides a robust chip/capillary interface. This hybrid design takes full advantage, such as sample stacking and purification and uniform signal intensity profile, of the unique chip injection scheme for DNA sequencing while employing long straight capillaries for the separations. In essence, the separation channel length is optimized for both speed and resolution since it is unconstrained by chip size. To demonstrate the reliability and practicality of this hybrid device, we sequenced over 1000 real-world samples from Human Chromosome 5 and Ciona intestinalis, prepared at Joint Genome Institute. We achieved average Phred20 read of 675 bases in about 70 min with a success rate of 91%. For the similar type of samples on MegaBACE 1000, the average Phred20 read is about 550-600 bases in 120 min separation time with a success rate of about 80-90%.     

Novel variable volume injector for performing sample introduction in a miniaturised isotachophoresis device

A microdevice design furnished with a novel sample injector, capable of delivering variable volume samples, for miniaturised isotachophoretic separations is presented. Micromachining by direct milling was used to realise two flow channel network designs on poly(methyl methacrylate) chips. Both designs comprised a wide bore sample channel interfaced, via a short connection channel, to a narrow bore separation channel. Superior injection performance was observed with a connection channel angled at 45 degrees to the separation channel compared to a device using a channel angled at 90 degrees. Automated delivery of electrolytes to the microdevice was demonstrated with both hydrostatic pumping and syringe pumps; both gave reproducible sample injection. A range of different sampling strategies were investigated. Isotachophoretic separations of model analytes (metal ions and an anionic dye) demonstrated the potential of the device. Separations of ten metal cations were achieved in under 475 s.     

Fast DNA sequencing up to 1,000 bases by capillary electrophoresis using poly(N,N-dimethylacrylamide) as a separation medium

Poly(N,N-dimethylacrylamide) (PDMA) with a molecular mass of 5.2 x 10(6) g/mol has been synthesized and used in DNA sequencing analysis by capillary electrophoresis (CE). A systematic investigation is presented on the effects of different separation conditions, such as injection amount, capillary inner diameter, polymer concentration, effective separation length, electric field and temperature, on the resolution. DNA sequencing up to 800 bases with a resolution (R) limit of 0.5 (and 1,000 bases with a resolution limit of 0.3) and a migration time of 96 min was achieved by using 2.5% w/v polymer, 150 V/cm separation electric field, and 60 cm effective separation length at room temperature on a DNA sample prepared with FAM-labeled--21M13 forward primer on pGEM3Zf(+) and terminated with ddCTP. Ultrafast and fast DNA sequencing up to 420 and 590 bases (R > or = 0.5) were also achieved by using 3% w/v polymer and 40 cm effective separation length with a separation electric field of 525 and 300 V/cm, and a migration time of 12.5 and 31.5 min, respectively. PDMA has low viscosity, long shelf life and dynamic coating ability to the glass surface. The unique properties of PDMA make it a very good candidate as a separation medium for large-scale DNA sequencing by capillary array electrophoresis (CAE).     

超高速平板通道毛细管电泳

超高速平板通道毛细管电泳是９０年代发展的一种秒级分离的新颖技术。应用现代微电子光刻技术将化学反应。进样、分离和检测等组合在数厘米玻片上。实现分离分析的小型化、集成化、一体化和自动化。     

Microfluidic device for capillary electrochromatography-mass spectrometry

A novel microfabricated device that integrates a monolithic polymeric separation channel, an injector, and an interface for electrospray ionization-mass spectrometry detection (ESI-MS) was devised. Microfluidic propulsion was accomplished using electrically driven fluid flows. The methacrylate-based monolithic separation medium was prepared by photopolymerization and had a positively derivatized surface to ensure electroosmotic flow (EOF) generation for separation of analytes in a capillary electrochromatography (CEC) format. The injector operation was optimized to perform under conditions of nonuniform EOF within the microfluidic channels. The ESI interface allowed hours of stable operation at the flow rates generated by the monolithic column. The dimensions of one processing line were sufficiently small to enable the integration of 4-8 channel multiplexed structures on a single substrate. Standard protein digests were utilized to evaluate the performance of this microfluidic chip. Low- or sub-fmol amounts were injected and detected with this arrangement.     

Nanoliter-scale sample preparation methods directly coupled to polymethylmethacrylate-based microchips and gel-filled capillaries for the analysis of oligonucleotides.

We are currently developing miniaturized, chip-based electrophoresis devices fabricated in plastics for the high-speed separation of oligonucleotides. One of the principal advantages associated with these devices is their small sample requirements, typically in the nanoliter to sub-nanoliter range. Unfortunately, most standard sample preparation protocols, especially for oligonucleotides, are done off-chip on a microliter-scale. Our work has focused on the development of capillary nanoreactors coupled to micro-separation platforms, such as micro-electrophoresis chips, for the preparation of sequencing ladders and also polymerase chain reactions (PCRs). These nanoreactors consist of fused-silica capillary tubes (10-20 cm x 20-50 microns I.D.) with fluid pumping accomplished using the electroosmotic flow generated by the tubes. These reactors were situated in fast thermal cyclers to perform cycle sequencing or PCR amplification of the DNAs. The reactors could be interfaced to either a micro-electrophoresis chips via capillary connectors micromachined in polymethylmethacrylate (PMMA) using deep X-ray etching (width 50 microns; depth 50 microns) or conventional capillary gel tubes using zero-dead volume glass unions. For our chips, they also contained an injector, separation channel (length 6 cm; width 30 microns; depth 50 microns) and a dual fiber optic, near-infrared fluorescence detector. The sequencing nanoreactor used surface immobilized templates attached to the wall via a biotin-streptavidin-biotin linkage. Sequencing tracks could be directly injected into gel-filled capillary tubes with minimal degradation in the efficiency of the separation process. The nanoreactor could also be configured to perform PCR reactions by filling the capillary tube with the PCR reagents and template. After thermal cycling, the PCR cocktail could be pooled from multiple reactors and loaded onto a slab gel or injected into a capillary tube or microchip device for fractionation.     

DNA sequencing in a monolithic microchannel device

We present 50 cm long microchannels in a monolithic device for high resolution, long read-length DNA sequencing. These devices were fabricated and bonded in borofloat glass using unconventional photolithography techniques with 48-188 independent, straight microchannels. The microchannel DNA separation was tested with POP-6 polymer and a DNA sequencing ladder separated at room temperature and 200 V/cm. Single-base resolution greater than 600 bases was achieved and the sequence base called to 640 bases with 98% accuracy. Under the same experimental conditions, the performance of the microchip was identical to a fused-silica capillary with similar cross-sectional area.     

Functionalized gold nanoparticles as additive to form polymer/metal composite matrix for improved DNA sequencing by capillary electrophoresis

A new matrix additive, poly (N,N-dimethylacrylamide)-functionalized gold nanoparticle (GNP-PDMA), was prepared by “grafting-to” approach, and then incorporated into quasi-interpenetrating network (quasi-IPN) composed of linear polyacrylamide (LPA, 3.3 MDa) and PDMA to form novel polymer/metal composite sieving matrix (quasi-IPN/GNP-PDMA) for DNA sequencing by capillary electrophoresis. Without complete optimization, quasi-IPN/GNP-PDMA yielded a readlength of 801 bases at 98% accuracy in about 64 min by using the ABI 310 Genetic Analyzer at 50 °C and 150 V/cm. Compared with previous quasi-IPN/GNPs, quasi-IPN/GNP-PDMA can further improve DNA sequencing performances. This is because the presence of GNP-PDMA can improve the compatibility of GNPs with the whole sequencing system, enhance the entanglement degree of networks, and increase the GNP concentration in system, which consequently lead to higher restriction and stability, higher apparent molecular weight (MW), and smaller pore size of the total sieving networks. Furthermore, the composite matrix was also compared with quasi-IPN containing higher-MW LPA and commercial POP-6. The results indicate that the composite matrix is a promising one for DNA sequencing to achieve full automation due to the separation provided with high resolution, speediness, excellent reproducibility, and easy loading in the presence of GNP-PDMA.     

DNA sequencing of close to 1000 bases in 40 minutes by capillary electrophoresis using dimethyl sulfoxide and urea as denaturants in replaceable linear polyacrylamide solutions

The goal of this work was to reduce the capillary electrophoresis (CE) separation time of DNA sequencing fragments with linear polyacrylamide solutions while maintaining the previously achieved long read lengths of 1000 bases. Separation speed can be increased while maintaining long read lengths by reducing the separation matrix viscosity and/or raising the column temperature. As urea is a major contributor to the separation buffer viscosity, reducing its concentration is desirable both for increase in the separation speed and easier solution replacement from the capillary. However, at urea concentrations below 6 M, the denaturing capacity of the separation buffer is not sufficient for accurate base-calling. To restore the denaturing properties of the buffer, a small amount of an organic solvent was added to the formulation. We found that a mixture of 2 M urea with 5% v/w of dimethyl sulfoxide (DMSO) resulted in 975 bases being sequenced at 70 degrees C in 40 min with 98.5% accuracy. To achieve this result, the software was modified to perform base-calling at a peak resolution as low as 0.24. It is also demonstrated that the products of thermal decomposition of urea had a deleterious effect on the separation performance at temperatures above 70 degrees C. With total replacement of urea with DMSO, at a concentration of 5% v/w in the same linear polyacrylamide (LPA)-containing buffer, it was possible to increase the column temperature up to 90 degrees C. At this temperature, up to 951 bases with 98.5% accuracy could be read in only 32 min of separation. However, with DMSO alone, some groups of C-terminated peaks remained compressed, and column temperature at this level cannot at present be utilized with existing commercial instrumentation.     

Integration of immobilized trypsin bead beds for protein digestion within a microfluidic chip incorporating capillary electrophoresis separations and an electrospray mass spectrometry interface

A microfluidic device is described in which an electrospray interface to a mass spectrometer is integrated with a capillary electrophoresis channel, an injector and a protein digestion bed on a monolithic substrate. A large channel, 800 microm wide, 150 microm deep and 15 mm long, was created to act as a reactor bed for trypsin immobilized on 40-60 microm diameter beads. Separation was performed in channels etched 10 microm deep, 30 microm wide and about 45 mm long, feeding into a capillary, attached to the chip with a low dead volume coupling, that was 30 mm in length, with a 50 microm i.d. and 180 microm o.d. Sample was pumped through the reactor bed at flow rates between 0.5 and 60 microL/min. The application of this device for rapid digestion, separation and identification of proteins is demonstrated for melittin, cytochrome c and bovine serum albumin (BSA). The rate and efficiency of digestion was related to the flow rate of the substrate solution through the reactor bed. A flow rate of 1 or 0.5 microL/min was found adequate for complete consumption of cytochrome c or BSA, corresponding to a digestion time of 3-6 min at room temperature. Coverage of the amino acid sequence ranged from 92% for cytochrome c to 71% for BSA, with some missed cleavages observed. Melittin was consumed within 5 s. In contrast, a similar extent of digestion of melittin in a cuvet took 10-15 min. The kinetic limitations associated with the rapid digestion of low picomole levels of substrate were minimized using an integrated digestion bed with hydrodynamic flow to provide an increased ratio of trypsin to sample. This chip design thus provides a convenient platform for automated sample processing in proteomics applications.     

Fluorescence detection in short capillary and chip using a variable wavelength epi-fluorescence microscope

Fast, efficient separation of five free acid forms of porphyrins was achieved in a short capillary and a chip, respectively. The capillary was 6 cm long from injection end to detector with an electric field strength of 214 V cm(-1). Separations were performed within 5 min. A glass microchip device was fabricated using standard photolithographic procedures and chemical wet etching. The channels were sealed using a direct bonding technique. For a separation length of 2.8 cm with electric field strength of 500 V cm(-1), electrophoretic separations with baseline resolution were achieved in less than 2 min. A variable wavelength epi-fluorescence microscope was used as an on-column detector.     

DNA sequencing and multiplex STR analysis on plastic microfluidic devices

The ability of plastic microfluidic devices with separation channel lengths of 6, 10 or 18 cm to perform high-quality and high-performance ssDNA analysis was evaluated. Specifically, four-color DNA sequencing separation of a terminator sequencing standard using replaceable, urea-denaturing linear polyacrylamide (LPA) solution as a sieving matrix, yielded read lengths of 410 bases in 15 min with base calling accuracy of 99.2% on a 6-cm device, and 640 bases in 35 min with accuracy of 98.0% on a 18-cm device. A two-color sizing analysis of four-locus (CSF1PO, TPOX, TH01, vWA) short tandem repeats (STRs) allelic ladder on a 10-cm device indicated a mean SD of +/- 0.08 base pairs (bp) between runs, and single bp resolution of spiked TH01 allele 9.3 (198 bp) from TH01 allele 10 (199 bp) of the CTTv ladder with R = 0.81. A four-color multiplex sizing analysis of three different AmpFlSTR allelic ladders consisting of nine loci (D3S1358, vWA, FGA, D8S1179, D21S11, D18S51, D5S818, D13S317, D7S820) and gender alleles (Amelogenin) on a 10-cm device had a mean SD of +/- 0.15 bp between runs for sizing three loci, i.e., FGA, D18S51 and D3S818; alleles differing by 2 bp in size were resolved with resolutions close to baseline. This work demonstrates that plastic microfluidic devices are capable of quality sequencing and STR sizing comparable to that of glass devices of similar separation lengths.     

Separation of double-stranded DNA fragments in plastic capillary electrophoresis chips by using E99P69E99 as separation medium.

The separation of double-stranded DNA (dsDNA) fragments in polymethylmethacrylate (PMMA) capillary electrophoresis (CE) chips by using E99P69E99 as a separation medium has been demonstrated. The PMMA CE chips were simply manufactured by micromachining and adhesive tape sealing. To make the separation channel compatible with the separation medium, a dynamic nonionic surfactant coating procedure was developed, which made the plastic separation channel sufficiently hydrophilic to allow the separation medium to fill the channel by capillary action. Subsequent separation of DNA fragments was successful with a separation efficiency of the order of 10(4) theoretical plates over an effective separation distance of 1.5 cm. By using an applied electric field strength of 200 V/cm, the separation of low DNA mass ladder was completed within 5 min. The simple coating procedure, together with the self-assembled viscosity-adjustable separation medium, should be useful to meet some of the essential requirements for developing single-use disposable CE chips. Coating the channels with polymer blends of PMMA and the separation medium also showed promise.     

集成毛细管电泳芯片系统的制作、测试及应用

使用标准光刻和化学湿法腐蚀技术,在玻璃板材上制作了由样样管道和分离管道内构成的集成毛细管网路系统,对影响芯片质量的一些因素进行了讨论,并进行了性能测试和评价。芯片上毛细管道散热良好。使用激光诱导荧光和CCD成像检测系统,以电渗作用为驱动力,对混合样品进行了进样、快速分离（20s以内）和监测,证明了自制集成毛细管电泳芯片及检测系统的可行性。比较了两种注样方式（float和pinched)的不同;证明了在分离时可以优化加电策略,防止拖尾,改善峰形。     

A transmission imaging spectrograph and microfabricated channel system for DNA analysis

In this paper we present the development of a DNA analysis system using a microfabricated channel device and a novel transmission imaging spectrograph which can be efficiently incorporated into a high throughput genomics facility for both sizing and sequencing of DNA fragments. The device contains 48 channels etched on a glass substrate. The channels are sealed with a flat glass plate which also provides a series of apertures for sample loading and contact with buffer reservoirs. Samples can be easily loaded in volumes up to 640 nL without band broadening because of an efficient electrokinetic stacking at the electrophoresis channel entrance. The system uses a dual laser excitation source and a highly sensitive charge-coupled device (CCD) detector allowing for simultaneous detection of many fluorescent dyes. The sieving matrices for the separation of single-stranded DNA fragments are polymerized in situ in denaturing buffer systems. Examples of separation of single-stranded DNA fragments up to 500 bases in length are shown, including accurate sizing of GeneCalling fragments, and sequencing samples prepared with a reduced amount of dye terminators. An increase in sample throughput has been achieved by color multiplexing.     

Faster and improved microchip electrophoresis using a capillary bundle

Joule heating generated in CE microchips is known to affect temperature gradient, electrophoretic mobility, diffusion of analytes, and ultimately the efficiency and reproducibility of the separation. One way of reducing the effect of Joule heating is to decrease the cross-section area of microchannels. Currently, due to the limit of fabrication technique and detection apparatus, the typical dimensions of CE microchannels are in the range of 50-200 microm. In this paper, we propose a novel approach of performing microchip CE in a bundle of extremely narrow channels by using photonic crystal fiber (PCF) as separation column. The PCF was simply encapsulated in a poly(methyl methacrylate) (PMMA) microchannel right after a T-shaped injector. CE was simultaneously but independently carried out in 54 narrow capillaries, each capillary with diameter of 3.7 microm. The capillary bundle could sustain high electric field strength up to 1000 V/cm due to efficient heat dissipation, thus faster and enhanced separation was attained.     

Sheathless capillary electrophoresis electrospray ionization‐mass spectrometry interface based on poly(dimethylsiloxane) membrane emitter and thin conducting liquid film

This study develops a sheathless CE‐MS interface using a robust PDMS membrane emitter and liquid‐film electric conduction. A 3D mold was constructed for casting the device by using a one‐step casting procedure. The interface consisted of a 125 μm‐thick triangular emitter with a 50 μm‐diameter microchannel, a conducting reservoir, and a 375 μm‐diameter channel for assembling the separation capillary. The separation capillary was inserted into the 375 μm channel and connected to the emitter through the conducting reservoir. The electric contact for the CE outlet was established through a conductive liquid film in the space between the capillary terminus and the 375 μm channel. The one‐step casting procedure and using a membrane emitter instead of a tapered emitter produced an easily fabricated and robust interface. A stable electrospray was obtained from 30 to 350 nL/min. Analyzing a five‐peptide mixture in low‐EOF (60 nL/min) and high‐EOF (210 nL/min) conditions demonstrated the utility of the interface.     

毛细管阵列电泳与规模化DNA测序

 根据 10 0 80份基因组DNA测序的结果 ,讨论了毛细管阵列电泳测序方法的技术特点 ,并对影响测序结果的一些因素进行了分析。在此基础上与平板凝胶电泳方法进行比较 ,显示了毛细管阵列电泳的优点。同时也对大规模测序技术环节之间的协调进行了探讨 。     

A continuous-flow,microfluidic fraction collection device

A microfluidic device is presented that performs electrophoretic separation coupled with fraction collection. Effluent from the 3.5 cm separation channel was focused via two sheath flow channels into one of seven collection channels. By holding the collection channels at ground potential and varying the voltage ratio at the two sheath flow channels, the separation effluent was directed to either specific collection channels, or could be swept past all channels in a defined time period. As the sum of the voltages applied to the two sheath flow channels was constant, the electric field remained at 275 V/cm during the separation regardless of the collection channel used. The constant potential in the separation channel allowed uninterrupted separation for late-migrating peaks while early-migrating peaks were being collected. To minimize the potential for carryover between fractions, the device geometry was optimized using a three-level factorial model. The optimum conditions were a 22.5° angle between the sheath flow channels and the separation channel, and a 350 μm length of channel between the separation outlet and the fraction channels. Using these optimized dimensions, the device performance was evaluated by separation and fraction collection of a fluorescently labeled amino acid mixture. The ability to fraction collect on a microfluidic platform will be especially useful during automated or continuous operation of these devices or to collect precious samples.     

Coupling of hydrodynamically closed large bore capillary isotachophoresis with electrospray mass spectrometry

Capillary isotachophoresis with coupled columns provides efficient means for rapid electrophoretic analysis of sample volumes of up to 10 μl or more. Commercially available instruments are commonly equipped with conductivity and UV absorbance detectors; however, their on-line coupling with electrospray mass spectrometry is highly desirable. In this work we have modified the commercial coupled column isotachophoresis system for direct connection to an ion trap mass spectrometer. The design included attachment of an elution block with a short capillary transfer line directing the separated zones towards the mass spectrometer. The modification further included separation of the injection and electrode blocks from the separation columns by semipermeable membranes eliminating unwanted fluid movements in the wide bore fluoropolymer separation capillaries. Fused silica capillaries with varying internal diameter were connected as a transfer line between the elution block and mass spectrometer. The transfer line served also as the ESI tip of the sheathless electrospray interface. During the analysis the first, wide bore preseparation capillary with 0.8 mm internal diameter served for removal of the bulk sample components and preseparation of the potentially interfering analytes. After the electronic column switching the separation was finished in a 0.3 mm internal diameter capillary and the separated ITP zones were transferred in-line by a spray liquid towards the mass spectrometer. The instrumentation was tested for determination of vitamins in whole blood analysis and separation of tryptic peptides.