Microfluidic electrochemical device for real-time culturing and interference-free detection of Escherichia coli.

Bacterial contamination and infection is a major health concern today leading to the significance of its detection. Being lab-based bacterial culturing processes, the present approaches are time consuming and require trained skillset. An economical, and miniaturized lab-on-chip device, capable of simultaneous detection of bacterial growth, could be a benchmarking tool for monitoring the bacterial contamination. Herein, the microfluidic-based electrochemical device for a fast, susceptible, detection of Escherichia coli was developed. The device could aid incubator free bacteria culturing in the ambient atmosphere and simultaneously monitor and detect the growth electrochemically. A three-electrode system, integrated with a reservoir and a portable thermostat temperature controller was fabricated and assembled. To achieve this, three-electrodes were embedded on the microfluidic device by screen-printing carbon paste, and the working electrode was enhanced by graphitized mesoporous carbon. Cyclic voltammetry response was noted as the function of concentration and growth of Escherichia Coli in the reservoir. The device gave a linear bacterial concentration range of 0.336 × 1012 to 40 × 1012 CFU mL-1, detection limit of 0.35 CFU mL-1 and the quantification limit of 1.05 CFU mL-1 which was less than the maximum allowable limit. The developed platform was further used to detect and continuously monitor the bacterial growth in the real sample (mango juice) for a period of 36 h. Finally, the interference from other common bacteria on the electrode selectivity was also investigated. Such approach in being further modified for specific sensing of bacteria in patients suffering from different diseases such as corneal ulcers, Diarrhea, tuberculosis, leprosy, and syphilis.

Application of perfluoropolyether elastomers in microfluidic drug metabolism assays.

Recently, increasing attention has been paid to liver-on-a-chip models for both pharmacokinetics and toxicity (ADMET) screenings. Although polydimethylsiloxane (PDMS) is the most popular material for the fabrication of microfluidic devices, its extensive sorption of hydrophobic drugs limits its applications. Therefore, we investigated a chemically repellent material, perfluoropolyether (PFPE) elastomer, as an alternative to PDMS. Primary rat hepatocytes cultured in the PFPE microfluidic device were polygonal or cuboidal in shape and had one or two prominent nuclei, as when cultured in 96-well plates. When hepatocytes were cultured in the PFPE microfluidic device and exposed to dynamic flow, the production of albumin and urea increased 3.94- and 1.72-fold, respectively, compared with no dynamic flow. Exposure to dynamic flow did not result in obvious changes in the expression of cytochrome P450, but increased the metabolic activity of hepatocytes compared to under static conditions. PFPE devices did not absorb midazolam, which was extensively absorbed by PDMS devices. However, the sorption of bufuralol could not be avoided even with PFPE devices. Solvent swelling experiments highlighted much better chemical repellency with PFPE than with PDMS. Hansen solubility parameters and sphere radius were estimated from the solvent swelling experiments. The relative energy distance (RED) of bufuralol to PFPE was much smaller than that of other three drugs tested, reasonably explaining the high sorption of bufuralol to PFPE. Although sorption into PFPE cannot be completely avoided, PFPE microfluidic devices may provide a better performance in ADMET evaluation than PDMS.

A label-free microfluidic biosensor for activity detection of single microalgae cells based on chlorophyll fluorescence.

Detection of living microalgae cells is very important for ballast water treatment and analysis. Chlorophyll fluorescence is an indicator of photosynthetic activity and hence the living status of plant cells. In this paper, we developed a novel microfluidic biosensor system that can quickly and accurately detect the viability of single microalgae cells based on chlorophyll fluorescence. The system is composed of a laser diode as an excitation light source, a photodiode detector, a signal analysis circuit, and a microfluidic chip as a microalgae cell transportation platform. To demonstrate the utility of this system, six different living and dead algae samples (Karenia mikimotoi Hansen, Chlorella vulgaris, Nitzschia closterium, Platymonas subcordiformis, Pyramidomonas delicatula and Dunaliella salina) were tested. The developed biosensor can distinguish clearly between the living microalgae cells and the dead microalgae cells. The smallest microalgae cells that can be detected by using this biosensor are 3 µm ones. Even smaller microalgae cells could be detected by increasing the excitation light power. The developed microfluidic biosensor has great potential for in situ ballast water analysis.