The purpose of our research is to develop evolutionary nanomaterials with enhanced and combined properties.
Those evolutionary nanoparticles can be used in nano-bio interface as a novel tool to find new discoveries in biology.
Moreover, they can provide novel approaches for imaging probes and therapy in current medicine.
The main purpose is to develop futuristic inorganic nanoparticle which has a totally new design concept. In contrast to the previously reported nanoparticles
mainly fabricated by trial and error or by serendipity, our nanoparticle, called as "evolutionary" nanoparticle, is constructed by the systematic and rational
design which makes it to be susceptible to the outer environment or stimulation so that it can be transformed into new shape and structure. The resulting
nanoparticle exhibits excellent performance in energy storage or catalytic activity compared to other previously reported materials. Moreover the nanoparticles
can be used in medical application for imaging or cancer therapy. In order to examine the various properties of these evolutionary nanoparticles, we have
basic equipments such as ARM, TEM, SEM, VSM, XRD, ICP, TGA, NMR, FT-IR, and AFM.
In the Nanomedicine group, researchers have focused on developing novel nanomaterials with
specific function such as imaging agents or therapeutic agents. Due to the property of transformation
of nanomaterials, they can change external physical stimulation to another form of stimulation such as
magnetism, mechanical force or thermal energy. Simultaneously, in order to apply those nanomaterials in
in vivo systems, researchers have developed diverse strategies to evade immune defense system in our body
and minimize unwanted side effects. In order to examine the biodistribution and effects of nanomaterials in biological
systems, we have our own animal facility for in vivo effect of those nanomaterials. We also have essential equipments
such as MRI, optical microscope (confocal, TIRF, etc.), magnetic hyperthermia, FACS, HPLC, FPLC, DLS, and PL.