Preparation and Evaluation of Paclitaxel-Loaded PEGylated Niosomes Composed of Sorbitan Esters.

Niosomes are non-ionic surfactant (NIS)-based bilayer vesicles and, like liposomes, have great potential as drug-delivery systems. Our previous study revealed that polyethylene glycol (PEG) niosomes using different sorbitan ester (Span) surfactants (sorbitan monoester, Span 20, 40, 60, 80; sorbitan triester, Span 65) distributed within tumors similarly to PEG liposomes. The aim of this study was to encapsulate efficiently an anti-cancer drug, paclitaxel (PTX) into Span PEG niosomes, and evaluate PTX release profiles and anti-tumor efficacy of PTX-loaded Span PEG niosomes. Niosome sizes ranged between 100-150 nm, and the PTX encapsulation efficiency was more than 50%. All niosomes examined, in the presence of serum, yielded sustained PTX-release profiles. PTX release at 24 and 48 h from Span 80 PEG niosomes was significantly the highest among the other Span PEG niosomes examined. In C26 tumor-bearing mice, PTX-loaded Span 40 PEG niosomes (the lowest PTX release in vitro) suppressed tumor growth while PTX-loaded Span 80 PEG niosomes (the highest PTX release in vitro) did not. Thus, we succeeded in the control of PTX release from Span PEG niosomes by modifying the component of niosomes, and it influenced the effects of drugs loaded into niosomes. This demonstrates that the excellent NIS physicochemical properties of Spans make them an ideal candidate for anti-cancer drug-carrier niosomes.

Pressure Dependence of Rate Coefficients of Unimolecular and Chemical Activation Reactions Connected to the Potential Energy Wells of Si2H2Cl4, Si2Cl6, and Si2Cl4 via Rice-Ramsperger-Kassel-Marcus Calculations.

Rate coefficients for elementary reactions connected to the potential energy wells of Si2H2Cl4, Si2Cl6, and Si2Cl4, which are important Si2 species in chemical vapor deposition (CVD) processes that use chlorosilanes as silicon source gases, were determined through the Rice-Ramsperger-Kassel-Marcus theory under various conditions of temperature and pressure. The optimized structures and vibrational frequencies of the reactants, products, and transition state were obtained using (U)B3LYP/6-31+G(d,p), and the single-point energies of the optimized structures were recalculated using the coupled cluster method with single and double excitations plus triple perturbation (U)CCSD(T) with complete basis set extrapolation. Many of the unimolecular decomposition channels and chemical activation reactions investigated in this work were found to be in the fall-off regime under subatmospheric to moderately high-pressure conditions so that it is expected that accurate modeling of the gas phase in the chlorosilane CVD reactor requires careful determination of the rate coefficients as functions of temperature and pressure for the conditions of interest, instead of using high-pressure limit rate coefficients. The rate coefficients determined here were expressed through Chebyshev coefficients and also modified Arrhenius parameters to be used in simulations of systems under a wide range of temperature and pressure conditions.