Micro-Total Analysis Systems (µTAS) for use in on-site rapid detection of DNA or RNA are increasingly being developed. Here, amplification of the target sequence is key to increasing sensitivity, enabling single-cell and few-copy nucleic acid detection. The several advantages to miniaturizing amplification reactions and coupling them with sample preparation and detection on the same chip are well known and include fewer manual steps, preventing contamination, and significantly reducing the volume of expensive reagents. To-date, the majority of miniaturized systems for nucleic acid analysis have used the polymerase chain reaction (PCR) for amplification and those systems are covered in previous reviews. This review provides a thorough overview of miniaturized analysis systems using alternatives to PCR, specifically isothermal amplification reactions. With no need for thermal cycling, isothermal microsystems can be designed to be simple and low-energy consuming and therefore may outperform PCR in portable, battery-operated detection systems in the future. The main isothermal methods as miniaturized systems reviewed here include nucleic acid sequence-based amplification (NASBA), loop-mediated isothermal amplification (LAMP), helicase-dependent amplification (HDA), rolling circle amplification (RCA), and strand displacement amplification (SDA). Also, important design criteria for the miniaturized devices are discussed. Finally, the potential of miniaturization of some new isothermal methods such as the exponential amplification reaction (EXPAR), isothermal and chimeric primer-initiated amplification of nucleic acids (ICANs), signal-mediated amplification of RNA technology (SMART) and others is presented.
We describe investigations toward a disposable polymer-based chip for the isolation of eukaryotic mRNA. This work focuses here on the improvement of the fabrication methods for rapid prototyping and the actual application at lowest RNA concentrations with total channel volumes of 3.5 lL. Messenger RNA isolation was achieved using paramagnetic oligo (dT) 25 beads within a microfluidic channel which incorporated a sawtooth microstructured design to aid in mixing. The structures were shown to facilitate mixing beteen two fluids in parallel flow when compared to a channel without structures. The chip was fabricated by means of hot embossing poly(methyl methacrylate) (PMMA) using a copper master. Copper was used as the master material due to its excellent thermal, mechanical, and electroplating properties. Fabrication of the master consisted of the structuring of a polished copper plate using KMPR 1050 as an electroplating mold for forming the microchannel structures. The copper master was found to be much more robust than traditional silicon masters used for prototyping. The use of KMPR enabled the generation of high straight walls in contrast to SU-8 masters. In addition, embossing times were able to be decreased by a factor of 3 due to improved heat conduction and avoidance of a lengthy and delicate de-embossing step.
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