Ultrafast STR Separations on Short-Channel Microfluidic Systems for Forensic Screening and Genotyping.

There are situations in which it is important to quickly and positively identify an individual. Examples include suspects detained in the neighborhood of a bombing or terrorist incident, individuals detained attempting to enter or leave the country, and victims of mass disasters. Systems utilized for these purposes must be fast, portable, and easy to maintain. DNA typing methods provide the best biometric information yielding identity, kinship, and geographical origin, but they are not portable and rapid. This study details the development of a portable short-channel microfluidic device based on a modified Agilent 2100 bioanalyzer for applications in forensic genomics. The system utilizes a denaturing polymer matrix with dual-channel laser-induced fluorescence and is capable of producing a genotype in 80 sec. The device was tested for precision and resolution using an allelic ladder created from 6 short tandem repeat (STR) loci and a sex marker (amelogenin). The results demonstrated a precision of 0.09-0.21 bp over the entire size range and resolution values from 2.5 to 4.1 bp. Overall, the results demonstrate the chip provides a portable, rapid, and precise method for screening amplified short tandem repeats and human identification screening.

Rapid direct PCR for forensic genotyping in under 25 min.

In this paper, a rapid thermal cycling procedure is combined with a direct amplification from a paper punch, permitting a high-speed amplification of a 7-locus multiplex that requires no extraction step. When coupled with a short 1.8 cm microfluidic electrophoresis system, the entire procedure from paper punch to genotype can be completed in under 25 min. The paper describes selection and optimization of enzyme, direct amplification conditions, the reproducibility of the procedure, and concordance with standard forensic genotyping methods. The procedure utilizes a small high-speed thermal cycler and microfluidic device along with a small laptop and is highly portable. Overall, this technique should provide a useful and reliable procedure for rapid determination of identity of individuals retained at checkpoints as well as a quick method for preliminary identification of individuals at remote locations following mass disasters.

Direct loading of polymer matrices in plastic microchips for rapid DNA analysis: a comparative study.

We report the design and performance validation of microfluidic separation technologies for human identification using a disposable plastic device suitable for integration into an automated rapid DNA analysis system. A fabrication process for a 15-cm long hot-embossed plastic microfluidic devices with a smooth semielliptical cross section out of cyclic olefin copolymer is presented. We propose a mixed polymer solution of 95% w/v hydroxyethylcellulose and 5% w/v polyvinylpyrrolidone for a final polymer concentration of 2.5 or 3.0% to be used as coating and sieving matrix for DNA separation. This formulation allows preparing the microchip without pretreatment in a single-loading step and provides high-resolution separation (≈1.2 bp for fragments <200 bp), which is superior to existing commercial matrices under the same conditions. The hot-embossed device performance is characterized and compared to injection-molded devices made out of cyclic olefin copolymer based on their respective injector geometry, channel shape, and surface charges. Each device design is assessed by fluorescence videomicroscopy to evaluate the formation of injection plugs, then by comparing electropherograms for the separation of a DNA size standard relevant to human identification.

The development of mini pentameric STR loci for rapid analysis of forensic DNA samples on a microfluidic system.

There is increasing interest in developing methods for portable DNA analysis in mass disasters and criminal identification. Currently most forensic STR DNA analysis is performed by CE; however, these instruments are not portable and require long sample run times. One potential solution is the development of microfluidic systems for DNA typing. Unfortunately, fairly long (ca. 20 cm) separation channels are usually required for the proper resolution of multiplexed STR loci used in human identification. Commercially available systems like the Agilent 2100 Bioanalyzer have a small footprint and utilize chips with shorter channels and reduced resolution. Such portable systems might be valuable for evidence screening in remote locations. However, due to their lower resolution, most standard 4 base STR loci and their inherent 2 base variants will not resolve on such systems. In this paper, we discuss the development of reduced length pentameric (5 base) STR amplicons. Pentameric STRs have fewer variant alleles and are easier to separate due to the wider spacing between alleles. By incorporating novel denaturing sieving polymers in a short microfluidic channel, we demonstrate efficient separations on these chips. Such an approach can serve as a useful tool for rapid microfluidic DNA typing.