Luke P. Lee (Advisor)

The goal of this project is to develop a sensitive, label-free detection technology for biomolecular interactions using a format that can be made highly parallel and disposable. Nanogap sensors enable direct detection, without the need for fluorescent labeling, by using dielectric (or impedence) spectroscopy.

Project end date: 08/01/06

The local field enhancement associated with the plasmonic resonance in metallic nanostructures has attracted intense research interest for its role in a number of useful optical phenomena such as surface-enhanced Raman scattering. In reality, the surface plasmon resonance, or the collective oscillation of the nanostructure's electrons, inevitably relax some of its energy through phonon and generates heat. Some nanostructures turned out to be especially efficient in such photothermal energy conversion and found applications in thermotherapy of cancer and optically triggered drug...

Intercellular communication between contact neighboring cells can cause change in morphology, gene expression and cell growth. Incomplete cell-cell communication is correlated with most forms of cancer. Many research efforts have been made to disclosure the molecular process through cell contact for regulating oncogenesis, but the answer is still poorly known. The technologies which can manipulate the time and location of the cell-contact are the exigencies in the field. Here we design a microfluidic device to trap specific number of cells in the array. For example, in two-cell trap...

We are developing a novel soft state biochemical pulse generating microfluidic device is constructed from poly(dimethylsiloxane) for the kinetic analysis of single cells. Hydrodynamic cell trapping via lateral microfluidic junctions allows the trapping of single cells from a bulk suspension. Microfluidic injection sites adjacent to the cell-trapping channels enable the pulsed delivery of nano-liter volumes of biochemical reagent.

Project end date: 02/20/07