The effect of ellagic acid on photodynamic therapy in leukemia cells.

Ellagic acid (EA) is a naturally phenolic acid presented in different foods. It has a variety of biological activities including antioxidant, anti-inflammatory, anti-microbiological and anti-cancer properties. On account of its antioxidant activity, EA might protect cancer cells from free radical damage in photodynamic therapy (PDT) during which reactive oxygen species (ROS) production was stimulated leading to irreversible tumor cell injury.

Research on the effect of formononetin on photodynamic therapy in K562 cells.

At the present time, many cancer patients combine some forms of complementary and alternative medicine therapies with their conventional therapies. The most common choice of these therapies is the use of antioxidants. Formononetin is presented in different foods.

Fabrication of nanopores for biomacromolecule detection.

Nanopores embedded in a thin membrane with diameter below 10 nm are suitable for the biomacromolecule detection. For such purpose, in this study, we developed a technique of how to obtain small nanopores in silicon nitride films using a focused-ion-beam (FIB) system. By changing the process parameters, such as the beam current, the film thickness of the membrane and the ion beam exposure time, the diameter of the nanopore can be tuned.

Nanofluidic channel fabrication and manipulation of DNA molecules.

Confining DNA molecules in a nanofluidic channel, particularly in channels with cross sections comparable to the persistence length of the DNA molecule (about 50 nm), allows the discovery of new biophysical phenomena. This sub-100 nm nanofluidic channel can be used as a novel platform to study and analyze the static as well as the dynamic properties of single DNA molecules, and can be integrated into a biochip to investigate the interactions between protein and DNA molecules. For instance, nanofluidic channel arrays that have widths of approximately 40 nm, depths of 60 nm, and lengths of 50 mum are created rapidly and exactly by a focused-ion beam milling instrument on a silicon nitride film; and the open channels are sealed with anodic bonding technology.

The morphology of DNA solution in an open fluidic channel studied by non-contact AFM.

The morphologies of pure buffer solution and DNA-containing solution in an open fluidic channel with rectangle cross section (1 microm in width and 150 nm in depth) have been explored using non-contact AFM. A remarkable feature is that a uniform nano-scale trench (approximately 15 nm deep and 14 microm long) on the surface of the DNA solution has been observed. The presence of two neighboring stretched DNA molecules near the solution surface may be responsible for the configuration of the nanotrench.