Implementation of microfluidic sandwich ELISA for superior detection of plant pathogens.

Rapid and economical screening of plant pathogens is a high-priority need in the seed industry. Crop quality control and disease surveillance demand early and accurate detection in addition to robustness, scalability, and cost efficiency typically required for selective breeding and certification programs. Compared to conventional bench-top detection techniques routinely employed, a microfluidic-based approach offers unique benefits to address these needs simultaneously. To our knowledge, this work reports the first attempt to perform microfluidic sandwich ELISA for Acidovorax citrulli (Ac), watermelon silver mottle virus (WSMoV), and melon yellow spot virus (MYSV) screening. The immunoassay occurs on the surface of a reaction chamber represented by a microfluidic channel. The capillary force within the microchannel draws a reagent into the reaction chamber as well as facilitates assay incubation. Because the underlying pad automatically absorbs excess fluid, the only operation required is sequential loading of buffers/reagents. Buffer selection, antibody concentrations, and sample loading scheme were optimized for each pathogen. Assay optimization reveals that the 20-folds lower sample volume demanded by the microchannel structure outweighs the 2- to 4-folds higher antibody concentrations required, resulting in overall 5-10 folds of reagent savings. In addition to cutting the assay time by more than 50%, the new platform offers 65% cost savings from less reagent consumption and labor cost. Our study also shows 12.5-, 2-, and 4-fold improvement in assay sensitivity for Ac, WSMoV, and MYSV, respectively. Practical feasibility is demonstrated using 19 real plant samples. Given a standard 96-well plate format, the developed assay is compatible with commercial fluorescent plate readers and readily amendable to robotic liquid handling systems for completely hand-free assay automation.

Quality control of next-generation sequencing library through an integrative digital microfluidic platform.

We have developed an automated quality control (QC) platform for next-generation sequencing (NGS) library characterization by integrating a droplet-based digital microfluidic (DMF) system with a capillary-based reagent delivery unit and a quantitative CE module. Using an in-plane capillary-DMF interface, a prepared sample droplet was actuated into position between the ground electrode and the inlet of the separation capillary to complete the circuit for an electrokinetic injection. Using a DNA ladder as an internal standard, the CE module with a compact LIF detector was capable of detecting dsDNA in the range of 5-100 pg/µL, suitable for the amount of DNA required by the Illumina Genome Analyzer sequencing platform. This DMF-CE platform consumes tenfold less sample volume than the current Agilent BioAnalyzer QC technique, preserving precious sample while providing necessary sensitivity and accuracy for optimal sequencing performance. The ability of this microfluidic system to validate NGS library preparation was demonstrated by examining the effects of limited-cycle PCR amplification on the size distribution and the yield of Illumina-compatible libraries, demonstrating that as few as ten cycles of PCR bias the size distribution of the library toward undesirable larger fragments.

Microchip electrophoresis of DNA following preconcentration at photopatterned gel membranes.

Rapid separation of nucleic acids by microchip electrophoresis could streamline many biological applications, but conventional chip injection strategies offer limited sample stacking, and thus limited sensitivity of detection. We demonstrate the use of photopatterned polyacrylamide membranes in a glass microfluidic device, with or without fixed negative charges, for preconcentration of double-stranded DNA prior to electrophoretic separation to enhance detection limits. We compared performance of the two membrane formulations (neutral or negatively charged) as a function of DNA fragment size, preconcentration time, and preconcentration field strength, with the intent of optimizing preconcentration performance without degrading the subsequent electrophoretic separation. Little size-dependent bias was observed for either membrane formulation when concentrating dsDNA > 100 bp in length, while the negatively charged membrane more effectively blocks passage of single-stranded oligonucleotide DNA (20-mer ssDNA). Baseline resolution of a six-band dye-labeled ladder with fragments 100-2000 bp in size was obtained in <120 s of separation time, with peak efficiencies in the range of 2000-15,000 plates/cm, and detection limits as low as 1 pM per single dye-labeled fragment. The degree of preconcentration is tunable by at least 49-fold, although the efficiency of preconcentration was found to have diminishing returns at high field and/or long times. The neutral membrane was found to be more robust than the negatively charged membrane, with approximately 2.5-fold larger peak area during the subsequent separation, and less decrease in resolution upon increasing the preconcentration field strength.

Integrated capillary electrophoresis microsystem for multiplex analysis of human respiratory viruses.

We developed a two-layer, four-channel polymerase chain reaction (PCR)-capillary electrophoresis microdevice that integrates nucleic acid amplification, sample cleanup and concentration, capillary electrophoretic separation, and detection for multiplex analysis of four human respiratory viral pathogens, influenza A, influenza B, coronavirus OC43, and human metapneumovirus. Biotinylated and fluorescently labeled double-stranded (ds) deoxyribonucleic acid (DNA) amplification products are generated in a 100 nL PCR reactor incorporating an integrated heater and a temperature sensor. After amplification, the products are captured and concentrated in a cross-linked acrylamide gel capture matrix copolymerized with acrydite-functionalized streptavidin-capture agents. Thermal dehybridization releases the fluorescently labeled DNA strand for capillary electrophoresis injection, separation, and detection. Using plasmid standards containing the viral genes of interest, each target can be detected starting from as few as 10 copies/reactor. When a two-step reverse transcription PCR amplification is employed, the device can detect ribonucleic acid (RNA) analogues of all four viral targets with detection limits in the range of 25-100 copies/reactor. The utility of the microdevice for analyzing samples from nasopharyngeal swabs is demonstrated. When size-based separation is combined with four-color detection, this platform provides excellent product discrimination, making it readily extendable to higher-order multiplex assays. This portable microsystem is also suitable for performing automated assays in point-of-care diagnostic applications.

Polymerase chain reaction-capillary electrophoresis genetic analysis microdevice with in-line affinity capture sample injection.

An integrated polymerase chain reaction (PCR)-capillary electrophoresis (CE) microdevice with an efficient in-line affinity-based injector has been developed for genetic analysis. Double stranded DNA PCR amplicons generated in an integrated 250 nL PCR reactor are captured, purified, and preconcentrated by an oligonucleotide probe immobilized in an in situ polymerized gel matrix followed by thermal release and injection into the CE-separation channel. This in-column injector employs a photopolymerized oligonucleotide-modified acrylamide capture gel to eliminate band broadening and increase the injection efficiency to 100%. The on-chip generated PCR amplicons processed on this microdevice exhibit a 3-5 fold increase in signal intensities and improved resolution compared to our previous T-shaped injector. Multiplex analysis of 191-bp amplicons from Escherichia coli O157 and 256-bp amplicons from E. coli K12 is achieved with a 6-fold increase in resolution. These advances are exploited to successfully detect E. coli O157 in a 500-fold higher background of E. coli K12. This microdevice with in-line affinity capture gel injection provides an improved platform for low-volume, high sensitivity, fully integrated genetic analysis.

Integrated microfluidic bioprocessor for single-cell gene expression analysis.

An integrated microdevice is developed for the analysis of gene expression in single cells. The system captures a single cell, transcribes and amplifies the mRNA, and quantitatively analyzes the products of interest. The key components of the microdevice include integrated nanoliter metering pumps, a 200-nL RT-PCR reactor with a single-cell capture pad, and an affinity capture matrix for the purification and concentration of products that is coupled to a microfabricated capillary electrophoresis separation channel for product analysis. Efficient microchip integration of these processes enables the sensitive and quantitative examination of gene expression variation at the single-cell level. This microdevice is used to measure siRNA knockdown of the GAPDH gene in individual Jurkat cells. Single-cell measurements suggests the presence of 2 distinct populations of cells with moderate (approximately 50%) or complete (approximately 0%) silencing. This stochastic variation in gene expression and silencing within single cells is masked by conventional bulk measurements.

Integrated affinity capture, purification, and capillary electrophoresis microdevice for quantitative double-stranded DNA analysis.

A novel injection method is developed that utilizes a thermally switchable oligonucleotide affinity capture gel to mediate the concentration, purification, and injection of dsDNA for quantitative microchip capillary electrophoresis analysis. The affinity capture matrix consists of a 20 base acrydite modified oligonucleotide copolymerized into a 6% linear polyacrylamide gel that captures ssDNA or dsDNA analyte including PCR amplicons and synthetic oligonucleotides. Double stranded PCR amplicons with complementarity to the capture probe up to 81 bases from their 5' terminus are reproducibly captured via helix invasion. By integrating the oligo capture matrix directly with the CE separation channel, the electrophoretically mobilized target fragments are quantitatively captured and injected after thermal release for unbiased, efficient, and quantitative analysis. The capture process exhibits optimal efficiency at 44 degrees C and 100 V/cm with a 20 microM affinity capture probe (TM = 57.7 degrees C). A dsDNA titration assay with 20 bp fragments validated that dsDNA is captured at the same efficiency as ssDNA. Dilution studies with a duplex 20mer show that targets can be successfully captured and analyzed with a limit of detection of 1 pM from 250 nL of solution (approximately 150,000 fluorescent molecules). Simultaneous capture and injection of amplicons from E. coli K12 and M13mp18 using a mixture of two different capture probes demonstrates the feasibility of multiplex target capture. Unlike the traditional cross-injector, this method enables efficient capture and injection of dsDNA amplicons which will facilitate the quantitative analysis of products from integrated nanoliter-scale PCR reactors.

Liquid/liquid interface polymerized porphyrin membranes displaying size-selective molecular and ionic permeability.

Thin polymeric membranes have been formed by liquid/liquid interfacial copolymerization of a sterically demanding tetraphenylporphyrin derivative having reactive phenol substituents and a second porphyrin having reactive acid chloride groups. The out-of-plane steric demand is created by 3,5-hexoxyphenyl groups positioned at two of the four meso carbons of the porphyrin ring. The bulky substituents were designed to create local pockets and extended pores within the resulting ester-linked copolymer. Quantitative measures of molecular and ionic transport were obtained by placing membranes over microelectrodes and recording voltammetric responses from redox-active probes. The membranes were found to be permeable to small molecules and ions, but blocking toward larger ones, displaying a sharp size cutoff at a probe diameter of ca. 3.5 A. Molecular transport can be modulated by axially ligating pore-blocking moieties to available porphyrin metal centers.