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Evaluation of Sieving Polymers for Fast, Reproducible Electrophoretic Analysis of Short Tandem Repeats (STR) in Capillaries

NCJ Number
210774
Journal
Journal of Forensic Sciences Volume: 50 Issue: 4 Dated: July 2005 Pages: 842-848
Author(s)
Joan M. Bienvenue M.S.; Kate L. Wilson B.S.; James P. Landers Ph.D.; Jerome P. Ferrance Ph.D.
Date Published
July 2005
Length
7 pages
Annotation
This study assessed commercially available polymeric sieving matrixes for STR analysis, with attention to the feasibility of incorporation into a microdevice.
Abstract
Efficient capillary electrophoretic STR analysis requires the rapid, reproducible, and robust separation of DNA fragments with reasonable capillary longevity. This is currently done by using proprietary commercial polymeric sieving matrixes specifically developed for this separation. Although effective, these matrixes are costly and do not provide adequate resolution of STR DNA fragments in capillaries with shorter effective separation lengths. This requires additional time to achieve the separation and minimize the potential extrapolation to other miniaturized platforms. For these reasons, other commercially available polymeric separation matrixes are being systematically evaluated for use in microdevices. The current report describes the evaluation of polyethylene oxide (PEO) for the separation of STR fragments in capillaries, with a view toward use in the microchip platform and as a possible alternative to commercially available sieving matrixes. Accurate, reproducible separation of single base pair differences is reported using a low-viscosity, denaturing solution of low-molecular-weight PEO in short capillaries. In addition, the effects of capillary temperature, buffer composition, polymer weight and concentration, and capillary length are described. Resolution was found to be better than results obtained with the use of conventional commercial polymers, with significantly shorter run times. The feasibility and demonstration of inclusion of this separation matrix in a typical microdevice are also discussed. 6 figures and 35 references