Effect of substrate thermal resistance on space-domain microchannel

A Bejan; A Dodge; A Manz; A Savitzky; B Giordano; C Gundry; C Wittwer; C Wittwer; David J. Kinahan; H Mao; H Nagai; I Schneegass; K Ririe; L Zhou; M Chabert; M Hernandez; M Kopp; Mark R. D. Davies; MG Herrmann; MN Kashid; N Crews; P Bernard; P Haugland; SO Sundberg; Tara M. Dalton

research

Effect of substrate thermal resistance on space-domain microchannel

Authors: A Bejan
A Dodge
A Manz
A Savitzky
B Giordano
C Gundry
C Wittwer
C Wittwer
David J. Kinahan
H Mao
H Nagai
I Schneegass
K Ririe
L Zhou
M Chabert
M Hernandez
M Kopp
Mark R. D. Davies
MG Herrmann
MN Kashid
N Crews
P Bernard
P Haugland
SO Sundberg
Tara M. Dalton
Publication date: 4 March 2009
Publisher: 'Springer Science and Business Media LLC'
Doi

Abstract

In recent years, Fluorescent Melting Curve Analysis (FMCA) has become an almost ubiquitous feature of commercial quantitative PCR (qPCR) thermal cyclers. Here a micro-fluidic device is presented capable of performing FMCA within a microchannel. The device consists of modular thermally conductive blocks which can sandwich a microfluidic substrate. Opposing ends of the blocks are held at differing temperatures and a linear thermal gradient is generated along the microfluidic channel. Fluorescent measurements taken from a sample as it passes along the micro-fluidic channel permits fluorescent melting curves to be generated. In this study we measure DNA melting temperature from two plasmid fragments. The effects of flow velocity and ramp-rate are investigated, and measured melting curves are compared to those acquired from a commercially available PCR thermocycler