Isolation of a Low Number of Sperm Cells from Female DNA in a Glass-PDMS-Glass Microchip via Bead-Assisted Acoustic Differential Extraction.

We report an improved separation method for the isolation of sperm cells from dilute, "large volume" samples containing female DNA using bead-assisted acoustic trapping. In an enclosed glass-PDMS-glass (GPG) resonator, we exploit a three-layer microfluidic architecture to generate "trapping nodes" in ultrasonic standing waves. We investigate the dependence of trapping efficiency on particle concentration for both sperm cells and polymeric beads. After determination of the critical concentration of polymeric beads required to seed the trapping event, sperm cells in dilute solution are trapped as a result of the enhanced secondary radiation force (SRF). Sperm-cell-containing samples with volumes up to 300 µL and cell concentrations as low as ∼10 cells/µL are amenable to effective trapping in the presence of an abundance of female DNA in solution. Complete processing of samples is accomplished with separation of the female and male fractions within 15 min. We demonstrate that the collected fractions are amenable to subsequent DNA extraction, short tandem repeat PCR, and the generation of STR profiles for the isolated sperm cells.

Enhanced recovery of spermatozoa and comprehensive lysis of epithelial cells from sexual assault samples having a low cell counts or aged up to one year.

Differential extraction (DE) is the most common method for processing sexual assault samples, allowing for the simultaneous recovery of sperm and epithelial cells from the swab with the separation of sperm cells from epithelial cell DNA by exploiting the differences in the cell membrane susceptibility to detergents. However, sperm cell recovery when using DE is generally 40-50% [1], which can reduce the probability of obtaining a STR profile of the semen contributor, especially if the sample is aged or has a low number of sperm cells. Here, we present a novel buffer, containing SDS and ProK that, when used as an initial incubation buffer, enhances sperm cell recovery to as high as 90%, representing a 200-300% increase over conventional DE buffer. Adjusting the incubation time and temperature provided high, reproducible sperm cell yields. Sample vortexing and replacement of SDS with sodium octyl sulfate (SOS), another sulfate-based anionic detergent, did not provide any further enhancement of the sperm cell recoveries. Furthermore, the one-step buffer provided up to a 300% increase in recovery over the conventional DE buffer when used on samples aged up to one year. STR analysis of samples containing 500 or more sperm cells treated with this buffer showed comparable results (i.e., full STR profiles; 16 of 16 loci) to those obtained using a conventional DE buffer. Finally, when the sample contained only 400 sperm cells (recovered in 100µL volume, then extracted), substantially more STR loci (14 of 16) were generated using the novel buffer in comparison to the conventional DE buffer (4 of 16 loci). This work demonstrates that this buffer may be useful as an alternative for the initial sample incubation step in differential extraction, particularly for aged or samples known to have a low number of sperm cells.

A thermally responsive phospholipid pseudogel: tunable DNA sieving with capillary electrophoresis.

In an aqueous solution the phospholipids dimyristoyl-sn-glycero-3-phosphocholine (DMPC) and 1,2-dihexanoyl-sn-glycero-3-phosphocholine (DHPC) self-assemble to form thermo-responsive non-Newtonian fluids (i.e., pseudogels) in which small temperature changes of 5-6 °C decrease viscosity dramatically. This characteristic is useful for sieving-based electrophoretic separations (e.g., of DNA), as the high viscosity of linear sieving additives, such as linear polyacrylamide or polyethylene oxide, hinders the introduction and replacement of the sieving agent in microscale channels. Advantages of utilizing phospholipid pseudogels for sieving are the ease with which they are introduced into the separation channel and the potential to implement gradient separations. Capillary electrophoresis separations of DNA are achieved with separation efficiencies ranging from 400,000 to 7,000,000 theoretical plates in a 25 µm i.d. fused silica capillary. Assessment of the phospholipid pseudogel with a Ferguson plot yields an apparent pore size of ~31 nm. Under isothermal conditions, Ogston sieving is achieved for DNA fragments smaller than 500 base pairs, whereas reptation-based transport occurs for DNA fragments larger than 500 base pairs. Nearly single base resolution of short tandem repeats relevant to human identification is accomplished with 30 min separations using traditional capillary electrophoresis instrumentation. Applications that do not require single base resolution are completed with faster separation times. This is demonstrated for a multiplex assay of biallelic single nucleotide polymorphisms relevant to warfarin sensitivity. The thermo-responsive pseudogel preparation described here provides a new innovation to sieving-based capillary separations.

Ultrafast amplification of DNA on plastic microdevices for forensic short tandem repeat analysis.

The majority of microfluidic devices used as a platform for low-cost, rapid DNA analysis are glass devices; however, microchip fabrication in glass is costly and laborious, enhancing the interest in polymeric substrates, such as poly (methyl methacrylate) (PMMA), as an inexpensive alternative. Here, we report amplification in PMMA polymerase chain reaction (PCR) microchips providing full short tandem repeat profiles (16 of 16 loci) in 30-40 min, with peak height ratios and stutter percentages that meet literature threshold requirements. In addition, partial profiles (15 of 16 loci) were generated using an ultrafast PCR method in 17.1 min, representing a ~10-fold reduction in reaction time as compared to current amplification methods. Finally, a multichamber device was demonstrated to simultaneously amplify one positive, one negative, and five individual samples in 39 min. Although there were instances of loci dropout, this device represents a first step toward a microfluidic system capable of amplifying more than one sample simultaneously.

From sample to PCR product in under 45 minutes: a polymeric integrated microdevice for clinical and forensic DNA analysis.

The extraction and amplification of DNA from biological samples is laborious and time-consuming, requiring numerous instruments and sample handling steps. An integrated, single-use, poly(methyl methacrylate) (PMMA) microdevice for DNA extraction and amplification would benefit clinical and forensic communities, providing a completely closed system with rapid sample-in-PCR-product-out capability. Here, we show the design and simple flow control required for enzyme-based DNA preparation and PCR from buccal swabs or liquid whole blood samples with an ~5-fold reduction in time. A swab containing cells or DNA could be loaded into a novel receptacle together with the DNA liberation reagents, heated using an infrared heating system, mixed with PCR reagents for one of three different target sets under syringe-driven flow, and thermally-cycled in less than 45 min, an ~6-fold reduction in analysis time as compared to conventional methods. The 4 : 1 PCR reagents : DNA ratio required to provide the correct final concentration of all PCR components for effective amplification was verified using image analysis of colored dyes in the PCR chamber. Novel single-actuation, 'normally-open' adhesive valves were shown to effectively seal the PCR chamber during thermal cycling, preventing air bubble expansion. The effectiveness of the device was demonstrated using three target sets: the sex-typing gene Amelogenin, co-amplification of the ß-globin and gelsolin genes, and the amplification of 15 short tandem repeat (STR) loci plus Amelogenin. The use of the integrated microdevice was expanded to the analysis of liquid blood samples which, when incubated with the DNA liberation reagents, form a brown precipitate that inhibits PCR. A simple centrifugation of the integrated microchips (on a custom centrifuge), mobilized the precipitate away from the microchannel entrance, improving amplification of the ß-globin and gelsolin gene fragments by ~6-fold. This plastic integrated microdevice represents a microfluidic platform with potential for evolution into point-of-care prototypes for application to both clinical and forensic analyses, providing a 5-fold reduction from conventional analysis time.

Label-free DNA quantification via a 'pipette, aggregate and blot' (PAB) approach with magnetic silica particles on filter paper.

Reliable measurement of DNA concentration is essential for a broad range of applications in biology and molecular biology, and for many of these, quantifying the nucleic acid content is inextricably linked to obtaining optimal results. In its most simplistic form, quantitative analysis of nucleic acids can be accomplished by UV-Vis absorbance and, in more sophisticated format, by fluorimetry. A recently reported new concept, the 'pinwheel assay', involves a label-free approach for quantifying DNA through aggregation of paramagnetic beads in a rotating magnetic field. Here, we describe a simplified version of that assay adapted for execution using only a pipet and filter paper. The 'pipette, aggregate, and blot' (PAB) approach allows DNA to induce bead aggregation in a pipette tip through exposure to a magnetic field, followed by dispensing (blotting) onto filter paper. The filter paper immortalises the extent of aggregation, and digital images of the immortalized bead conformation, acquired with either a document scanner or a cell phone camera, allows for DNA quantification using a noncomplex algorithm. Human genomic DNA samples extracted from blood are quantified with the PAB approach and the results utilized to define the volume of sample used in a PCR reaction that is sensitive to input mass of template DNA. Integrating the PAB assay with paper-based DNA extraction and detection modalities has the potential to yield 'DNA quant-on-paper' devices that may be useful for point-of-care testing.

An enzyme-based DNA preparation method for application to forensic biological samples and degraded stains.

Extraction of DNA from forensic samples typically uses either an organic extraction protocol or solid phase extraction (SPE) and these methods generally involve numerous sample transfer, wash and centrifugation steps. Although SPE has been successfully adapted to the microdevice, it can be problematic because of lengthy load times and uneven packing of the solid phase. A closed-tube enzyme-based DNA preparation method has recently been developed which uses a neutral proteinase to lyse cells and degrade proteins and nucleases [14]. Following a 20 min incubation of the buccal or whole blood sample with this proteinase, DNA is polymerase chain reaction (PCR)-ready. This paper describes the optimization and quantitation of DNA yield using this method, and application to forensic biological samples, including UV- and heat-degraded whole blood samples on cotton or blue denim substrates. Results demonstrate that DNA yield can be increased from 1.42 (±0.21)ng/µL to 7.78 (±1.40)ng/µL by increasing the quantity of enzyme per reaction by 3-fold. Additionally, there is a linear relationship between the amount of starting cellular material added and the concentration of DNA in the solution, thereby allowing DNA yield estimations to be made. In addition, short tandem repeat (STR) profile results obtained using DNA prepared with the enzyme method were comparable to those obtained with a conventional SPE method, resulting in full STR profiles (16 of 16 loci) from liquid samples (buccal swab eluate and whole blood), dried buccal swabs and bloodstains and partial profiles from UV or heat-degraded bloodstains on cotton or blue denim substrates. Finally, the DNA preparation method is shown to be adaptable to glass or poly(methyl methacrylate) (PMMA) microdevices with little impact on STR peak height but providing a 20-fold reduction in incubation time (as little as 60 s), leading to a ≥1 h reduction in DNA preparation time.