Buoyancy-driven convection offers a novel and greatly simplified mechanism for generating continuous nonpulsatile flow fields and performing thermally activated biochemical reactions. In this paper, we build on our previous work by constructing a multiwell device incorporating an array of 35-microL cylindrical cavities to perform polymerase chain reaction (PCR) amplification of a 191-base pair fragment associated with membrane channel proteins M1 and M2 of the influenza-A virus in as little as 15 min with performance comparable to conventional thermocyclers. We also describe entirely new adaptations of convective flows by conducting a series of coordinated flow visualization and computational studies to explore the design of closed-loop systems to execute tunable thermocycling, pumping, and mixing operations in a format suitable for integration into miniaturized biochemical analysis systems. Using 15-microL convective flow loops, we are able to perform PCR amplification of the same 191-base pair fragment associated with the influenza-A virus, as well as a 295-base pair segment of the human beta-actin gene in a format offering an enhanced degree of control and tunability. These convective flow devices can be further scaled down to nanoliter volumes and are ideally suited as a platform for a new generation of low-power, portable microfluidic DNA analysis systems.
A new method to embed branched 3D microvascular fluidic networks inside plastic substrates by harnessing electrostatic discharge phenomena is introduced. This nearly instantaneous process reproducibly generates highly branched tree‐like microchannel architectures that bear remarkable similarity to naturally occurring vasculature. This method can be applied to a variety of polymers, and may help enable production of organ‐sized tissue scaffolds containing embedded vasculature.
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