Determination of delta 9-tetrahydrocannabinol in human blood and saliva by high-performance liquid chromatography with amperometric detection

A rapid, sensitive and selective determination of delta 9-tetrahydrocannabinol (THC) in human plasma, serum and saliva was developed with high-performance liquid chromatography with electrochemical detection. Initially, samples were deproteinized, followed by a one step liquid-liquid extraction. Samples were measured by high-performance liquid chromatography with electrochemical detection with 4-dodecylresorcinol as the internal standard. The minimal detectable limit for THC in biological samples was ca. 1 ng/ml with a signal-to-noise ratio greater than 3, corresponding to an on-column sensitivity for THC of ca. 0.5 ng. The detector was operated at + 0.90 V vs. Ag/AgCl and exhibited linearity over a concentration range of 1-150 ng/ml with correlation coefficients of the standard curves greater than 0.99.     

Assay for codeine, morphine and ten potential urinary metabolites by gas chromatography--mass fragmentography

A mass fragmentography (MF) assay is described for ten potential, minor urinary metabolites of codeine (C) and morphine (M). Samples were hydrolyzed, extracted, derivatized with Tri-Sil Z and analyzed by methane chemical ionization (CI)-MF. The method is sensitive to ca. 0.01 microgram/ml for all compounds with the exception of normorphine (NM) which was difficult to extract with chloroform. The sensitivity of the MF assay for NM was only ca. 0.10 microgram/ml. Various solvent systems were investigated for optimization of extraction efficiency of all metabolites. A separate method for the extraction of NM is reported which utilizes a solid buffer--solvent combination, i.e., potassium carbonate--isopropanol. This latter method provided the best overall recovery of NM (39.0 +/- 3.4%). Gas chromatographic (GC) retention times of C, M and metabolites are reported for three liquid phases (3%) on Gas-Chrom Q (100-120 mesh). Resolution of metabolites (as trisilyl derivatives) was best on Silar-5CP and this phase was used in metabolic studies of C and M. GC resolution was not complete for all compounds; however, selection of specific ions for monitoring by MF provided the required specificity for all compounds except the 6 alpha- and 6 beta-hydroxy isomers. CI spectra for all metabolites are reported. The MF assay was used for urinary analysis of samples from guinea pigs that received single doses of C (15 mg/kg) or M (8 mg/kg). Following C administration 6 alpha- and 6 beta-hydrocodol, 6 alpha, beta-hydromorphol (undifferentiated), HM and M were measured. Following M administration only 6 alpha, beta-hydromorphol was found. The amount of total metabolite as percent dose for each component was calculated as less than 1%.     

Slow decoherence and the radiative decay limit in rare-earth-doped crystals for coherent optical storage

We analyze the material requirements for recording, storage, and processing of optically encoded information using coherent optical transients in resonant solids. We introduce new figures of merit (FOM’s) that explicitly account for the ratio between the rate of the decoherence and the rate of the spontaneous radiative decay. Highest FOM values are achieved when the decoherence rate approaches the fundamental limit set by spontaneous emission under the condition that the total transition oscillator strength is concentrated between a single pair of energy levels. We analyze FOM’s of some of the most promising rare-earth-doped crystals at cryogenic temperatures.     

Diphenylamin als qualitatives Reagens auf Zink

Ohne Zusammenfassung     

Investigating material trends and lattice relaxation effects for understanding electron transfer phenomena in rare-earth-doped optical materials

Rare-earth-doped insulators and semiconductors play an important role in a wide range of modern optical technologies. Knowledge of the relative energies of rare-earth ions’ localized electronic states and the band states of the host crystal is important for understanding the properties of these materials and for determining the potential material performance in specific applications such as lasers, phosphors, and optical signal processing. Current understanding of the systematic variations of electron binding energies in these materials is reviewed with analysis of how lattice relaxation affects the results obtained from different experimental techniques. Detailed examples are presented for rare-earth-doped YAG and LaF₃ material systems. A method for predicting the chemical shift of the 4f electrons of rare-earth impurities from the host crystal’s photoemission spectrum is also demonstrated. Furthermore, a simple model is presented that predicts host-dependent trends in the binding energies of the rare-earth ion states in materials ranging from the elemental metals to the ionic fluorides. By understanding the systematic changes in the relative energies for different states, different ions, and different host materials, insight is gained into electron transfer transitions, valence stability, and luminescence quenching that can accelerate the development of materials for optical applications.