Brian E. Root

Ultrafast DNA sequencing on a microchip by a hybrid separation mechanism that gives 600 bases in 6.5 minutes

To realize the immense potential of large-scale genomic sequencing after the completion of the second human genome (Venters), the costs for the complete sequencing of additional genomes must be dramatically reduced. Among the technologies being developed to reduce sequencing costs, microchip electrophoresis is the only new technology ready to produce the long reads most suitable for the de novo sequencing and assembly of large and complex genomes. Compared with the current paradigm of capillary electrophoresis, microchip systems promise to reduce sequencing costs dramatically by increasing throughput, reducing reagent consumption, and integrating the many steps of the sequencing pipeline onto a single platform. Although capillary-based systems require ≈70 min to deliver ≈650 bases of contiguous sequence, we report sequencing up to 600 bases in just 6.5 min by microchip electrophoresis with a unique polymer matrix/adsorbed polymer wall coating combination. This represents a two-thirds reduction in sequencing time over any previously published chip sequencing result, with comparable read length and sequence quality. We hypothesize that these ultrafast long reads on chips can be achieved because the combined polymer system engenders a recently discovered “hybrid” mechanism of DNA electromigration, in which DNA molecules alternate rapidly between reptating through the intact polymer network and disrupting network entanglements to drag polymers through the solution, similar to dsDNA dynamics we observe in single-molecule DNA imaging studies. Most importantly, these results reveal the surprisingly powerful ability of microchip electrophoresis to provide ultrafast Sanger sequencing, which will translate to increased system throughput and reduced costs.

DNA analysis using an integrated microchip for multiplex PCR amplification and electrophoresis for reference samples.

A system that automatically performs the PCR amplification and microchip electrophoretic (ME) separation for rapid forensic short tandem repeat (STR) forensic profiling in a single disposable plastic chip is demonstrated. The microchip subassays were optimized to deliver results comparable to conventional benchtop methods. The microchip process was accomplished in sub-90 min compared with >2.5 h for the conventional approach. An infrared laser with a noncontact temperature sensing system was optimized for a 45 min PCR compared with the conventional 90 min amplification time. The separation conditions were optimized using LPA-co-dihexylacrylamide block copolymers specifically designed for microchip separations to achieve accurate DNA size calling in an effective length of 7 cm in a plastic microchip. This effective separation length is less than half of other reports for integrated STR analysis and allows a compact, inexpensive microchip design. This separation quality was maintained when integrated with microchip PCR. Thirty samples were analyzed conventionally and then compared with data generated by the microfluidic chip system. The microfluidic system allele calling was 100% concordant with the conventional process. This study also investigated allelic ladder consistency over time. The PCR-ME genetic profiles were analyzed using binning palettes generated from two sets of allelic ladders run three and six months apart. Using these binning palettes, no allele calling errors were detected in the 30 samples demonstrating that a microfluidic platform can be highly consistent over long periods of time.

Purification of HIV RNA from serum using a polymer capture matrix in a microfluidic device

In this report, we demonstrate the purification of DNA and RNA from a 10% serum sample using an oligonucleotide capture matrix. This approach provides a one-stage, completely aqueous system capable of purifying both RNA and DNA for downstream PCR amplification. The advantages of utilizing the polymer capture matrix method in place of the solid-phase extraction method is that the capture matrix eliminates both guanidine and the 2-propanol wash that can inhibit downstream PCR and competition with proteins for the binding sites that can limit the capacity of the device. This method electrophoreses a biological sample (e.g., serum) containing the nucleic acid target through a polymer matrix with covalently bound oligonucleotides. These capture oligonucleotides selectively hybridize and retain the target nucleic acid, while the other biomolecules and reagents (e.g., SDS) pass through the matrix to waste. Following this purification step, the solution can be heated above the melting temperature of the capture sequence to release the target molecule, which is then electrophoresed to a recovery chamber for subsequent PCR amplification. We demonstrate that the device can be applied to purify both DNA and RNA from serum. The gag region of HIV at a starting concentration of 37.5 copies per microliter was successfully purified from a 10% serum sample demonstrating the applicability of this method to detect viruses present in low copy numbers.

Polymer systems designed specifically for DNA sequencing by microchip electrophoresis: a comparison with commercially available materials.

Electrophoresis‐based DNA sequencing is the only proven technology for the de novo sequencing of large and complex genomes. Miniaturization of capillary array electrophoresis (CAE) instruments can increase sequencing throughput and decrease cost while maintaining the high quality and long read lengths that has made CAE so successful for de novo sequencing. The limited availability of high‐performance polymer matrices and wall coatings designed specifically for microchip‐sequencing platforms continues to be a major barrier to the successful development of a commercial microchip‐sequencing instrument. It has been generally assumed that the matrices and wall coatings that have been developed for use in commercial CAE instruments will be able to be implemented directly into microchip devices with little to no change in sequencing performance. Here, we show that sequencing matrices developed specifically for microchip electrophoresis systems can deliver read lengths that are 150–300 bases longer on chip than some of the most widely used polymer‐sequencing matrices available commercially. Additionally, we show that the coating ability of commercial matrices is much less effective in the borosilicate chips used in this study. These results lead to the conclusion that new materials must be developed to make high‐performance microfabricated DNA‐sequencing instruments a reality.

Size-based protein separations by microchip electrophoresis using an acid-labile surfactant as a replacement for SDS.

We demonstrate the use of an acid‐labile surfactant (ALS) as a replacement for SDS for size‐based protein separations in a microfluidic device. ALS is of interest to the proteomic field as it degrades at low pH and hence can be removed to reduce surfactant interference with down‐stream MS. A range of SDS and ALS concentrations were tested as denaturants for microchip electrophoresis to investigate their effects on the separation of proteins from 18 to 116 kDa and to provide a suitable comparison between the two surfactants. The electrophoretic mobilities of the proteins were not significantly affected by the use of ALS instead of SDS. Protein separations with ALS are performed in less than 3 min, which is a significant decrease in the time compared with the previous ALS separations on a slab gel format. We also demonstrate the use of poly‐N‐hydroxyethylacrylamide as a dynamic, hydrophilic chip channel coating that can be applied with a rapid and simple protocol for size‐based protein separation. The results reported here could significantly decrease the time and increase the attainable level of automation and integration of the front‐end protein fractionation required for “top‐down” proteomics.

Thermoresponsive N-alkoxyalkylacrylamide polymers as a sieving matrix for high-resolution DNA separations on a microfluidic chip

In recent years, there has been an increasing demand for a wide range of DNA separations that require the development of materials to meet the needs of high resolution and high throughput. Here, we demonstrate the use of thermoresponsive N‐alkoxyalkylacrylamide polymers as a sieving matrix for DNA separations on a microfluidic chip. The viscosities of the N‐alkoxyalkylacrylamide polymers are more than an order of magnitude lower than that of a linear polyacrylamide (LPA) of corresponding molecular weight, allowing rapid loading of the microchip. At 25°C, N‐alkoxyalkylacrylamide polymers can provide improved DNA separations compared with LPA in terms of reduced separation time and increased separation efficiency, particularly for the larger DNA fragments. The improved separation efficiency in N‐alkoxyalkylacrylamide polymers is attributed to the peak widths increasing only slightly with DNA fragment size, while the peak widths increase appreciably above 150 bp using an LPA matrix. Upon elevating the temperature to 50°C, the increase in viscosity of the N‐alkoxyalkylacrylamide solutions is dependent upon their overall degree of hydrophobicity. The most hydrophobic polymers exhibit a lower critical solution temperature below 50°C, undergoing a coil‐to‐globule transition followed by chain aggregation. DNA separation efficiency at 50°C therefore decreases significantly with increasing hydrophobic character of the polymers, and no separations were possible with solutions with a lower critical solution temperature below 50°C. The work reported here demonstrates the potential for this class of polymers to be used for applications such as PCR product and RFLP sizing, and provides insight into the effect of polymer hydrophobicity on DNA separations.

Rapid Fabrication of Electrophoretic Microfluidic Devices from Polyester, Adhesives and Gold Leaf

In the last decade, the microfluidic community has witnessed an evolution in fabrication methodologies that deviate from using conventional glass and polymer-based materials. A leading example within this group is the print, cut and laminate (PCL) approach, which entails the laser cutting of microfluidic architecture into ink toner-laden polyester sheets, followed by the lamination of these layers for device assembly. Recent success when applying this method to human genetic fingerprinting has highlighted that it is now ripe for the refinements necessary to render it amenable to mass-manufacture. In this communication, we detail those modifications by identifying and implementing a suitable heat-sensitive adhesive (HSA) material to equip the devices with the durability and resilience required for commercialization and fieldwork. Importantly, this augmentation is achieved without sacrificing any of the characteristics which make the PCL approach attractive for prototyping. Exemplary HSA-devices performed DNA extraction, amplification and separation which, when combined, constitute the complete sequence necessary for human profiling and other DNA-based analyses.