Polymer based biosensor for rapid electrochemical detection of virus infection of human cells.

The demand in the field of medical diagnostics for simple, cost efficient and disposable devices is growing. Here, we present a label free, all-polymer electrochemical biosensor for detection of acute viral disease. The dynamics of a viral infection in human cell culture was investigated in a micro fluidic system on conductive polymer PEDOT:TsO microelectrodes by electrochemical impedance spectroscopy and video time lapse microscopy. Employing this sensitive, real time electrochemical technique, we could measure the immediate cell response to cytomegalovirus, and detect an infection within 3h, which is several hours before the cytopathic effect is apparent with conventional imaging techniques. Atomic force microscopy and scanning ion conductance microscopy imaging consolidate the electrochemical measurements by demonstrating early virus induced changes in cell morphology of apparent programmed cell death.

Integrated microfluidic tmRNA purification and real-time NASBA device for molecular diagnostics.

We demonstrate the first integrated microfluidic tmRNA purification and nucleic acid sequence-based amplification (NASBA) device incorporating real-time detection. The real-time amplification and detection step produces pathogen-specific response in < 3 min from the chip-purified RNA from 100 lysed bacteria. On-chip RNA purification uses a new silica bead immobilization method. On-chip amplification uses custom-designed high-selectivity primers and real-time detection uses molecular beacon fluorescent probe technology; both are integrated on-chip with NASBA. Present in all bacteria, tmRNA (10Sa RNA) includes organism-specific identification sequences, exhibits unusually high stability relative to mRNA, and has high copy number per organism; the latter two factors improve the limit of detection, accelerate time-to-positive response, and suit this approach ideally to the detection of small numbers of bacteria. Device efficacy was demonstrated by integrated on-chip purification, amplification, and real-time detection of 100 E. coli bacteria in 100 microL of crude lysate in under 30 min for the entire process.

Static and dynamic acute cytotoxicity assays on microfluidic devices.

Static and dynamic acute toxicity assays of cells were performed on microfluidic devices where materials were hydraulically transported. Static assays were performed by incubating cells with an agent in a microchip reservoir and optically interrogating the cells after hydrodynamic focusing at a cross intersection. Dynamic assays were performed on a microchip with a 25-cm-long spiral channel where the cells were mixed with an agent and optically monitored 0.1, 12, and 22 cm from the point of mixing. The incubation time was determined by the time needed for cells to transit from the mixing location to the point of detection. Cell viability was determined using the ratio of fluorescence signals from membrane permeant (calcein) and membrane impermeant (propidium iodide) stains. The model system used in this study was the viability of Jurkat cells in the presence of the agent Triton X-100). An average LC50 value of 138 microM for Triton X-100 was obtained for an incubation period of 7-12 min using the static assay. LC50 values obtained with the dynamic assay for 25- and 47-s incubation times were 290 and 250 microM Triton X-100, respectively. Higher LC50 values for the dynamic assay were expected due to the shorter incubation times.