Fast and direct determination of catechol-3, 6-bis(methyleiminodiacetic acid) prototype in beagle dog plasma using liquid chromatography tandem mass spectrometry: A simplified and high throughput in-vivo method for the metal chelator.

It is usually somewhat difficult to analyze the metal chelators, especially in complex biological matrix, because of the interference of metal ions in both the matrix and analyzing system. In this study, an innovative and simple bioanalytical method was established and validated for the quantification of a newly developed uranium chelator catechol-3, 6-bis (methyleiminodiacetic acid) (CBMIDA) in beagle dog plasma. Different analytical columns and mobile phase were tested for effective chromatography resolution and sensitive and reproducible response of CBMIDA and the internal standard. An Agilent Zorbax SB AQ column was chosen. Excessive peak tailing, peak asymmetry, low recovery, and poor reproducibility, which are generally observed in chromatographic analysis of metal chelators, were overcome by the use of a pulse gradient method and addition of ethylene diamine tetraacetic acid (EDTA) to the mobile phase at 8 µg mL-1, enabling good peak shape, low matrix interference, high precision and good linearity for CBMIDA quantification in beagle dog plasma. Plasma sample pretreatment was performed by a simple, high throughput protein precipitation step with 2.5 mM EDTA methanol solution in a 96-well protein precipitation plate without complexing with the metal ions, and the sample was directly analyzed by electrospray ionization mass spectrometry. By shifting the analysis target from the metal complex to metal chelator itself, the method has an advantage over the existing method for determination of EDTA and diethylenetriaminepentaacetic acid owing to increased sample throughput and apparent simplicity. The assay was validated in accordance with the United States Food and Drug Administration guidelines and successfully applied to the pharmacokinetic study of CBMIDA in beagles after intramuscular injection of CBMIDA at different doses. The method was sensitive enough for the detection of CBMIDA concentration at 4 elimination half-times. The experimental strategies presented herein may be helpful for the measurement of other radionuclide chelators in biological matrices.

High-Throughput Determination of Sodium Danshensu in Beagle Dogs by the LCMS/MS Method, Employing Liquid-Liquid Extraction Based on 96-Well Format Plates.

Sodium Danshensu (sodium d-(+)-ß-(3,4-dihydroxyphenyl) lactate), one of the water-soluble ingredients in Salvia miltiorrhiza, exhibits potent relaxation of the coronary artery and anticoagulation effection. A high-throughput, rapid, and sensitive method combining liquid chromatography with electrospray ionization tandem mass spectrometry to determine the sodium danshensu in beagle dog plasma was developed and validated, using gallic acid as an internal standard (IS). Acidified plasma samples were extracted using 96-well liquid-liquid extraction, and were eluted on a CNW Athena C18 column (3 µm, 2.1 × 100 mm) by using a gradient mobile phase system of methanol and water (containing 0.2% formic acid). The mass spectrometric detection was achieved using negative ion electrospray ionization mode and monitoring the precursor→production combinations of m/z 197→135 for sodium danshensu and 169→125 for IS, in multiple reaction monitoring modes. Good linearity was achieved, and the linear range was 10-1000 ng/mL (R² > 0.996) with a quantification limit of 10 ng/mL for sodium danshensu in beagle dog plasma. The intra- and inter-day precision (RSD) ranged from 2.1% to 9.0%. The accuracy (RE) was between -8.6% and 5.7% at all quality control levels. The validated method was successfully applied to the pharmacokinetics study of sodium danshensu in beagle dog plasma after intravenous injection and oral administration of sodium danshensu.

Rotational dynamics of confined C60 from near-infrared Raman studies under high pressure.

Peapods present a model system for studying the properties of dimensionally constrained crystal structures, whose dynamical properties are very important. We have recently studied the rotational dynamics of C(60) molecules confined inside single walled carbon nanotube (SWNT) by analyzing the intermediate frequency mode lattice vibrations using near-infrared Raman spectroscopy. The rotation of C(60) was tuned to a known state by applying high pressure, at which condition C(60) first forms dimers at low pressure and then forms a single-chain, nonrotating, polymer structure at high pressure. In the latter state the molecules form chains with a 2-fold symmetry. We propose that the C(60) molecules in SWNT exhibit an unusual type of ratcheted rotation due to the interaction between C(60) and SWNT in the "hexagon orientation," and the characteristic vibrations of ratcheted rotation becomes more obvious with decreasing temperature.

High-pressure structural transitions of Sc2O3 by X-ray diffraction, Raman spectra, and ab initio calculations.

The high-pressure behavior of scandium oxide (Sc(2)O(3)) has been investigated by angle-dispersive synchrotron powder X-ray diffraction and Raman spectroscopy techniques in a diamond anvil cell up to 46.2 and 42 GPa, respectively. An irreversible structural transformation of Sc(2)O(3) from the cubic phase to a monoclinic high-pressure phase was observed at 36 GPa. Subsequent ab initio calculations for Sc(2)O(3) predicted the phase transition from the cubic to monoclinic phase but at a much lower pressure. The same calculations predicted a second phase transition at 77 GPa from the monoclinic to hexagonal phase.

Synthesis of high-density nanocavities inside TiO2-B nanoribbons and their enhanced electrochemical lithium storage properties.

Single crystalline TiO2-B nanoribbons with high-density nanocavities were successfully synthesized via a simple hydrothermal route. The as-prepared TiO2-B nanoribbons exhibited a large Brunauer, Emmett, and Teller (BET) surface area of about 305 m(2)/g because of the high-density nanocavities inside the thin nanoribbons. Electrochemical measurements indicated that the TiO2-B nanoribbons with dense nanocavities showed discharge specific capacity higher than those of TiO2-B nanotubes and nanowires. It was found that the dense nanocavities have an important influence on the electrochemical lithium intercalation properties.