Issue 9, 2008

Quantitative and qualitative analysis of a microfluidic DNA extraction system using a nanoporous AlOx membrane

Abstract

A nanoporous aluminium oxide membrane was integrated into a microfluidic system designed to extract hgDNA (human genomic DNA) from lysed whole blood. The effectiveness of this extraction system was determined by passing known concentrations of purified hgDNA through nanoporous membranes with varying pore sizes and measuring the amount of hgDNA deposited on the membrane while also varying salt concentration in the solution. DNA extraction efficiency increased as the salt concentration increased and nanopore size decreased. Based on these results, hgDNA was extracted from whole blood while varying salt concentration, nanopore size and elution buffer to find the conditions that yield the maximum concentration of hgDNA. The optimal conditions were found to be using a low-salt lysis solution, 100 nm pores, and a cationic elution buffer. Under these conditions the combination of flow and ionic disruption were sufficient to elute the hgDNA from the membrane. The extracted hgDNA sample was analysed and evaluated using PCR (polymerase chain reaction) to determine whether the eluted sample contained PCR inhibition factors. Eluted samples from the microfluidic system were amplified without any inhibition effects. PCR using extracted samples was demonstrated for several genes of interest. This microfluidic DNA extraction system based on embedded membranes will reduce the time, space and reagents needed for DNA analysis in microfluidic systems and will prove valuable for sample preparation in lab-on-a-chip applications.

Graphical abstract: Quantitative and qualitative analysis of a microfluidic DNA extraction system using a nanoporous AlOx membrane

Article information

Article type
Paper
Submitted
19 Mar 2008
Accepted
03 Jun 2008
First published
17 Jul 2008

Lab Chip, 2008,8, 1516-1523

Quantitative and qualitative analysis of a microfluidic DNA extraction system using a nanoporous AlOx membrane

J. Kim and B. K. Gale, Lab Chip, 2008, 8, 1516 DOI: 10.1039/B804624G

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