Semi-automated, occupationally safe immunofluorescence microtip sensor for rapid detection of Mycobacterium cells in sputum.

An occupationally safe (biosafe) sputum liquefaction protocol was developed for use with a semi-automated antibody-based microtip immunofluorescence sensor. The protocol effectively liquefied sputum and inactivated microorganisms including Mycobacterium tuberculosis, while preserving the antibody-binding activity of Mycobacterium cell surface antigens. Sputum was treated with a synergistic chemical-thermal protocol that included moderate concentrations of NaOH and detergent at 60°C for 5 to 10 min.

Nanotips for single-step preparation of DNA for qPCR analysis.

A single-step concentration and elution method is developed for detection of DNA in buffer, saliva, and blood. A nanotip capturing DNA using an electric field and capillary action is directly dissolved in buffer for qPCR analysis. The concentration yield and the relative parameters are compared with those of a commercial kit.

Immunosensor towards low-cost, rapid diagnosis of tuberculosis.

A rapid, accurate tuberculosis diagnostic tool that is compatible with the needs of tuberculosis-endemic settings is a long-sought goal. An immunofluorescence microtip sensor is described that detects Mycobacterium tuberculosis complex cells in sputum in 25 minutes. Concentration mechanisms based on flow circulation and electric field are combined at different scales to concentrate target bacteria in 1 mL samples onto the surfaces of microscale tips.

Size-selective immunofluorescence of Mycobacterium tuberculosis cells by capillary- and viscous forces.

Rapid, low cost screening of tuberculosis requires an effective enrichment method of Mycobacterium tuberculosis (MTB) cells. Currently, microfiltration and centrifugation steps are frequently used for sample preparation, which are cumbersome and time-consuming. In this study, the size-selective capturing mechanism of a microtip-sensor is presented to directly enrich MTB cells from a sample mixture.

Hybrid nanofibril assembly using an alternating current electric field and capillary action.

Various nanowire (or nanotube)-based devices have been investigated to fulfill future demands on semiconducting devices, nanoscale electromechanical systems, and biosensors. To fabricate such devices, an electric field-induced assembly method has demonstrated a great potential for one dimensional assembly. In this paper, our novel approaches for fabricating hybrid nanofibrils are presented to enhance the multiple functionalities, the production rate and the fibril length.

Bio-mimetic silicone cilia for microfluidic manipulation.

This paper presents a bio-mimetic microfluidic device that mimics the high compliance and the beating frequency of biological cilia in order to achieve bio-compatible manipulation of microfluidics. Because the highly compliant cilia can easily collapse due to interaction energy and surface tension, the major challenge in developing a bio-mimetic device is the manufacturing of highly compliant cilia. An underwater fabrication method is developed to avoid the cilia collapse by lowering the surface energy of the cilia.

Fluid flow-assisted dielectrophoretic assembly of nanowires.

The dielectrophoretic assembly of silicon carbide (SiC) nanowires in a microfluidic flow is shown to enhance the orientation and deposition yield of nanowires. The fluid flow delivers and orients the nanowires in the vicinity of a gap, and they are attracted and deposited by a dielectrophoretic force. Depending upon their lengths, the nanowires are selectively attracted to the gap because the dielectrophoretic force is largest when the lengths are comparable to the gap size.