Multiplex STR amplification sensitivity in a silicon microchip

The demand for solutions to perform forensic DNA profiling outside of centralized laboratories is increasing. We here demonstrate highly sensitive STR amplification using a silicon micro-PCR (mu PCR) chip. Exploiting industry-standard semiconductor manufacturing processes, a device was fabricated that features a small form factor thanks to an integrated heating element covering three parallel micro-reactors with a reaction volume of 0.5 mu l each. Diluted reference DNA samples (1 ng-31 pg) were amplified on the mu PCR chip using the forensically validated AmpFISTR Identifier Plus kit, followed by conventional capillary electrophoresis. Complete STR profiles were generated with input DNA quantities down to 62 pg. Occasional allelic dropouts were observed from 31 pg downward. On-chip STR profiles were compared with those of identical samples amplified using a conventional thermal cycler for direct comparison of amplification sensitivity in a forensic setting. The observed sensitivity was in line with kit specifications for both mu PCR and conventional PCR. Finally, a rapid amplification protocol was developed. Complete STR profiles could be generated in less than 17 minutes from as little as 125 pg template DNA. Together, our results are an important step towards the development of commercial, mass-produced, relatively cheap, handheld devices for on-site testing in forensic DNA analysis

Integrated modular microfluidic system for forensic Alu DNA typing

Driven by the numerous applications of genome-related research, fully integrated microfluidic systems have been developed that have advanced the capabilities of molecular and, in particular, genetic analyses. A brief overview on integrated microfluidic systems for DNA analysis is given in Chapter 1 followed by a report on micro-capillary electrophoresis (µCE) of Alu elements with laser-induced fluorescence (LIF) detection, in which the monomorphic Alu insertions on the X and Y chromosomes were utilized to detect male DNA in large female DNA background (Y: X = 1:19) without cell sorting prior to the determination. The polymorphic Alu loci with known restricted geographical distribution were used for ethnicity determination. A valveless integrated microsystem that consists of three modules is discussed as well: (1) A solid-phase extraction (SPE) module microfabricated on polycarbonate, for DNA extraction from whole cell lysates (extraction bed capacity ~209 ±35.6 ng/cm² of total DNA). (2) A continuous-flow polymerase chain reaction (CFPCR) module fabricated in polycarbonate (Tg ~150 ºC) in which selected gene fragments were amplified using biotin and fluorescently-labeled primers accomplished by continuously shuttling small packets of PCR reagents and template through isothermal zones. (3) µCE module fabricated in poly(methylmethacrylate), which utilized a bioaffinity selection and purification bed (2.9-µL) to preconcentrate and purify the PCR products generated from the CFPCR module prior to µCE. Biotin-labeled CFPCR products were hydrostatically pumped through the streptavidin-modified bed where they were extracted onto the surface of the poly(methylmethacrylate) micropillars (50-µm width; 100-µm height; total surface area of ~117 mm²). This SPE process demonstrated high selectivity for biotinylated amplicons and utilized the strong streptavidin/biotin interaction (Kd =10-15M) to generate high recoveries. The SPE selected CFPCR products were thermally denatured and single stranded DNA released for size-based separations and LIF detection. The multiplexed SPE-CFPCR-µCE yielded detectable fluorescence signal (S/N≥3; LOD ~75 cells) for Alu DNA amplicons for gender and ethnicity determinations with a separation efficiency of ~1.5 x105 plates/m. Compared to traditional cross-T injection procedures typically used for µCE, the affinity preconcentration and injection procedure generated signal enhancements of 17-40 fold, critical for CFPCR thermal cyclers due to Taylor dispersion associated with their operation

Miniature RT–PCR system for diagnosis of RNA-based viruses

This paper presents an innovative portable chip-based RT–PCR system for amplification of specific nucleic acid and detection of RNA-based viruses. The miniature RT–PCR chip is fabricated using MEMS (Micro-electro-mechanical-system) techniques, and comprises a micro temperature control module and a PDMS (polydimethylsiloxane)-based microfluidic control module. The heating and sensing elements of temperature control module are both made of platinum and are located within the reaction chambers in order to generate a rapid and uniform thermal cycling. The microfluidic control module is capable of automating testing process with minimum human intervention. In this paper, the proposed miniature RT–PCR system is used to amplify and detect two RNA-based viruses, namely dengue virus type-2 and enterovirus 71 (EV 71). The experimental data confirm the ability of the system to perform a two-step RT–PCR process. The developed miniature system provides a crucial tool for the diagnosis of RNA-based viruses

Advances in Microfluidics and Lab-on-a-Chip Technologies

Advances in molecular biology are enabling rapid and efficient analyses for effective intervention in domains such as biology research, infectious disease management, food safety, and biodefense. The emergence of microfluidics and nanotechnologies has enabled both new capabilities and instrument sizes practical for point-of-care. It has also introduced new functionality, enhanced sensitivity, and reduced the time and cost involved in conventional molecular diagnostic techniques. This chapter reviews the application of microfluidics for molecular diagnostics methods such as nucleic acid amplification, next-generation sequencing, high resolution melting analysis, cytogenetics, protein detection and analysis, and cell sorting. We also review microfluidic sample preparation platforms applied to molecular diagnostics and targeted to sample-in, answer-out capabilities

Configurable and Up-Scalable Microfluidic Life Science Platform for Cell Based Assays by Gravity Driven Sequential Perfusion and Diffusion

Microfluidics has the potential to significantly change the way modern biology is performed, but for this potential to be realized several on-chip integration and operation challenges have to be addressed. Critical issues are addressed in this work by first demonstrating an integrated microfluidic tmRNA purification and real time nucleic acid sequence based amplification (NASBA) device. The device is manufactured using soft lithography and a unique silica bead immobilization method for the nucleic acid micro purification column. The integrated device produced a pathogen-specific response in < 3 min from the chip-purified RNA. Further enhancements in the device design and operation that allow the on-chip integration of mammalian cell handling and culturing produced a novel integrated NASBA array. This system demonstrated for the first time that it is possible to combine on a single micro-device cell culture and real time NASBA. In order to expand the cell based assay capabilities of the integrated NASBA array and simplify the device operation novel hydrodynamics and cell sedimentation within trench structures and gravity driven sequential perfusion and diffusion mechanisms were developed. These mechanisms were characterized and implemented within an iCell array device. iCell array can completely integrate cell based assays with bio-analytical read-out. The device is highly scalable and can enable the configurable on-chip integration of procedures such as adherent and non-adherent cell-culture, cellstimulation, cell-lysis, cell-fixing, protein-immunoassays, bright field and fluorescent microscopic monitoring, and real time detection of nucleic acid amplification. The device uses on-board gravity driven flow control which makes it simple and economical to operate with dilute samples (down to 5 cells per reaction), low reagent volumes (50 nL per reaction), highly efficient cell capture (100% capture rates) and single cell protein and gene expression sensitivity. The key results from this work demonstrate a novel technology for versatile, fully integrated microfluidic array platforms. By multiplexing this integrated functionality, the device can be used from routine applications in a biology laboratory to high content screenings

Point-of-Need DNA Testing for Detection of Foodborne Pathogenic Bacteria

Foodborne pathogenic bacteria present a crucial food safety issue. Conventional diagnostic methods are time-consuming and can be only performed on previously produced food. The advancing field of point-of-need diagnostic devices integrating molecular methods, biosensors, microfluidics, and nanomaterials offers new avenues for swift, low-cost detection of pathogens with high sensitivity and specificity. These analyses and screening of food items can be performed during all phases of production. This review presents major developments achieved in recent years in point-of-need diagnostics in land-based sector and sheds light on current challenges in achieving wider acceptance of portable devices in the food industry. Particular emphasis is placed on methods for testing nucleic acids, protocols for portable nucleic acid extraction and amplification, as well as on the means for low-cost detection and read-out signal amplification

Single-Molecule Detection of Unique Genome Signatures: Applications in Molecular Diagnostics and Homeland Security

Single-molecule detection (SMD) offers an attractive approach for identifying the presence of certain markers that can be used for in vitro molecular diagnostics in a near real-time format. The ability to eliminate sample processing steps afforded by the ultra-high sensitivity associated with SMD yields an increased sampling pipeline. When SMD and microfluidics are used in conjunction with nucleic acid-based assays such as the ligase detection reaction coupled with single-pair fluorescent resonance energy transfer (LDR-spFRET), complete molecular profiling and screening of certain cancers, pathogenic bacteria, and other biomarkers becomes possible at remarkable speeds and sensitivities with high specificity. The merging of these technologies and techniques into two different novel instrument formats has been investigated. (1) The use of a charge-coupled device (CCD) in time-delayed integration (TDI) mode as a means for increasing the throughput of any single molecule measurement by simultaneously tracking and detecting single-molecules in multiple microfluidic channels was demonstrated. The CCD/TDI approach allowed increasing the sample throughput by a factor of 8 compared to a single-assay SMD experiment. A sampling throughput of 276 molecules s-1 per channel and 2208 molecules s-1 for an eight channel microfluidic system was achieved. A cyclic olefin copolymer (COC) waveguide was designed and fabricated in a pre-cast poly(dimethylsiloxane) stencil to increase the SNR by controlling the excitation geometry. The waveguide showed an attenuation of 0.67 dB/cm and the launch angle was optimized to increase the depth of penetration of the evanescent wave. (2) A compact SMD (cSMD) instrument was designed and built for the reporting of molecular signatures associated with bacteria. The optical waveguides were poised within the fluidic chip at orientation of 90° with respect to each other for the interrogation of single-molecule events. Molecular beacons (MB) were designed to probe bacteria for the classification of Gram +. MBs were mixed with bacterial cells and pumped though the cSMD which allowed S. aureus to be classified with 2,000 cells in 1 min. Finally, the integration of the LDR-spFRET assay on the cSMD was explored with the future direction of designing a molecular screening approach for stroke diagnostics

Development of a Real-Time Microchip PCR System for Portable Plant Disease Diagnosis

Rapid and accurate detection of plant pathogens in the field is crucial to prevent the proliferation of infected crops. Polymerase chain reaction (PCR) process is the most reliable and accepted method for plant pathogen diagnosis, however current conventional PCR machines are not portable and require additional post-processing steps to detect the amplified DNA (amplicon) of pathogens. Real-time PCR can directly quantify the amplicon during the DNA amplification without the need for post processing, thus more suitable for field operations, however still takes time and require large instruments that are costly and not portable. Microchip PCR systems have emerged in the past decade to miniaturize conventional PCR systems and to reduce operation time and cost. Real-time microchip PCR systems have also emerged, but unfortunately all reported portable real-time microchip PCR systems require various auxiliary instruments. Here we present a stand-alone real-time microchip PCR system composed of a PCR reaction chamber microchip with integrated thin-film heater, a compact fluorescence detector to detect amplified DNA, a microcontroller to control the entire thermocycling operation with data acquisition capability, and a battery. The entire system is 25 × 16 × 8 cm(3) in size and 843 g in weight. The disposable microchip requires only 8-µl sample volume and a single PCR run consumes 110 mAh of power. A DNA extraction protocol, notably without the use of liquid nitrogen, chemicals, and other large lab equipment, was developed for field operations. The developed real-time microchip PCR system and the DNA extraction protocol were used to successfully detect six different fungal and bacterial plant pathogens with 100% success rate to a detection limit of 5 ng/8 µl sample