Phononic and photonic properties of shape-engineered silicon nanoscale pillar arrays.

We report the results of Brillouin-Mandelstam spectroscopy and Mueller matrix spectroscopic ellipsometry of the nanoscale 'pillar with the hat' periodic silicon structures, revealing intriguing phononic and photonic-phoxonic-properties. It has been theoretically shown that periodic structures with properly tuned dimensions can act simultaneously as phononic and photonic crystals, strongly affecting the light-matter interactions. Acoustic phonon states can be tuned by external boundaries, either as a result of phonon confinement effects in individual nanostructures, or as a result of artificially induced external periodicity, as in the phononic crystals. The shape of the nanoscale pillar array was engineered to ensure the interplay of both effects. The Brillouin-Mandelstam spectroscopy data indicated strong flattening of the acoustic phonon dispersion in the frequency range from 2 GHz to 20 GHz and the phonon wave vector extending to the higher-order Brillouin zones. The specifics of the phonon dispersion dependence on the pillar arrays' orientation suggest the presence of both periodic modulation and spatial localization effects for the acoustic phonons. The ellipsometry data reveal a distinct scatter pattern of four-fold symmetry due to nanoscale periodicity of the pillar arrays. Our results confirm the dual functionality of the nanostructured shape-engineered structure and indicate a possible new direction for fine-tuning the light-matter interaction in the next generation of photonic, optoelectronic, and phononic devices.

Volume measurements and fluorescent staining indicate an increase in permeability for organic cation transporter substrates during apoptosis.

Extensive membrane blebbing is one of the earliest observable changes in HeLa cells stimulated with apoptosis inducers. Blebbing caused by actinomycin D or camptothecin, but not by anti-Fas antibody, is accompanied by an almost 10% volume increase as measured by transmission-through-dye microscopy. When the experiment is carried out in DMEM medium, the swelling appears to result from activation of amiloride-sensitive channels. Low-sodium choline-, but not N-methyl(-)D-glucamine-based, medium, also supports swelling during the blebbing phase of apoptosis; this indicates that the membrane becomes permeable to choline as well. Because choline can enter the cells through organic cation transporters (OCT), we tested three fluorescent dyes (2-[4-(dimethylamino)styryl]-1-methylpyridinium iodide, rhodamine 123 and ethidium bromide) that have been reported to utilize OCT for cell entry. Intact HeLa cells are poorly permeable for these fluorophores, and initially they accumulate on the plasma membranes. Blebbing results in an enhanced penetration of these dyes into the cell interior, as was demonstrated both by direct observation and by FRET. The increased membrane permeability is specific for OCT substrates; the other tested cationic dyes apparently cross the membrane by other routes and exhibit a markedly different behavior. Our results reveal a previously unknown feature of apoptosis and the utility of cationic dyes for studying membrane transport.

Dynamic Adsorption of Albumin on Nanostructured TiO(2)Thin Films.

Spectroscopic ellipsometry was used to characterize the optical properties of thin (<5 nm) films of nanostructured titanium dioxide (TiO(2)). These films were then used to investigate the dynamic adsorption of bovine serum albumin (BSA, a model protein), as a function of protein concentration, pH, and ionic strength. Experimental results were analyzed by an optical model and revealed that hydrophobic interactions were the main driving force behind the adsorption process, resulting in up to 3.5 mg/m(2) of albumin adsorbed to nanostructured TiO(2). The measured thickness of the adsorbed BSA layer (less than 4 nm) supports the possibility that spreading of the protein molecules on the material surface occurred. Conformational changes of adsorbed proteins are important because they may subsequently lead to either accessibility or inaccessibility of bioactive sites which are ligands for cell interaction and function relevant to physiology and pathology.