Highly sensitive restriction enzyme assay and analysis: a review.

Biological assays at the single molecule level are crucial to fundamental studies of DNA-protein mechanisms. In order to cater for high throughput applications, one area of immense research potential is single-molecule bioassays where miniaturized devices are developed to perform rapid and effective biological reactions and analyses. With the success of various emerging technologies for engineering miniaturized structures down to the nanoscale level, supported by specialized equipment for detection, many investigations in the field of life science that were once thought impossible can now be actively explored.

Loop-mediated isothermal amplification of a single DNA molecule in polyacrylamide gel-based microchamber.

Loop-mediated isothermal amplification (LAMP) is an original nucleic acid amplification method established by Notomi et al. LAMP is performed under isothermal condition, employing only a basic reaction protocol and minimal supporting electronics. These requirements prove to be viable for exploring the avenues to down-scale this biological reaction for Lab-on-a-chip application.

An integrated system for enzymatic cleavage and electrostretching of freely-suspended single DNA molecules.

A novel polyacrylamide gel-based femtolitre microchamber system for performing single-molecule restriction enzyme assay on freely-suspended DNA molecules and subsequent DNA electrostretching by applying an alternating electric field has been developed. We attempted the integration by firstly initiating restriction enzyme reaction on a fluorescent-stained lambdaDNA molecule, encapsulated in a microchamber, using magnesium as an external trigger. Upon complete digestion, the cleaved DNA fragments were electrostretched to analyze the DNA lengths optically.

Studies on the temperature distribution of a thick film transcutaneous oxygen sensor and its thermal influences on oxygen measurement.

The partial pressures of gases, namely oxygen and carbon dioxide, in the arterial blood are important parameters for doctors to determine the respiratory conditions of patients. Currently in practice, there are a number of ways to measure these parameters, one of which is transcutaneous blood gas monitoring. This technique is a popular noninvasive measurement method for obtaining fast and relatively accurate responses.