Synthesis and anticancer activity evaluation of η(5)-C5(CH3)4R ruthenium complexes bearing chelating diphosphine ligands.

The complexes [RuCp*(PP)Cl] (Cp* = C5Me5; [], PP = dppm; [], PP = Xantphos), [RuCp(#)(PP)Cl] (Cp(#) = C5Me4(CH2)5OH; [], PP = dppm; [], PP = Xantphos) and [RuCp*(dppm)(CH3CN)][SbF6] [] were synthesized and evaluated in vitro as anticancer agents. Compounds gave nanomolar IC50 values against normoxic A2780 and HT-29 cell lines, and were also tested against hypoxic HT-29 cells, maintaining their high activity. Complex yielded an IC50 value of 0.55 ± 0.03 µM under a 0.1% O2 concentration.

Effects of draining cochlear fluids on stapes displacement in human middle-ear models.

Displacement-frequency characteristics of the stapes footplate were measured in five human temporal bones before and after draining the vestibule. Measurements were made in the 0.125-8 kHz range at 80 dB input sound pressure level, using a laser Doppler vibrometer. A circuit model was also used to predict stapes displacement. The temporal bone studies show a slight decrease in stapes footplate displacement at low frequency, and little change above 1 kHz. The displacement change is not as great as that found by other investigators or predicted by the model. There is little difference in stapes motion in temporal bones when the inner ear is intact or drained.

An anatomically shaped incus prosthesis for reconstruction of the ossicular chain.

An anatomically shaped incus replica prosthesis has been designed to reconstruct the ossicular chain. A series of in vitro studies on human temporal bones evaluated the acoustic performance of this prosthesis and compared it with a Causse partial ossicular replacement prosthesis (PORP). Pure tones in the frequency range 0. 125-8 kHz stimulated the tympanic membrane at sound pressure levels of 80, 90 and 100 dB. Measurements of the stapes footplate velocity were made with a laser interferometer. The acoustic function of the ossicular chain reconstructed with the incus replica prosthesis was found to be within 10 dB of that of the original intact ossicular chain, when both the upper and lower joints of the implant were rigidly fixed in place. It was shown that a rigid mechanical contact between the ossicular prosthesis and ossicles is a prerequisite for effective sound transmission. The anatomically shaped incus prosthesis gave a 15-dB improvement on the PORP at frequencies below 1.5 kHz.