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Chemistry75%

Selected Abstracts

In Vivo Time-Course Changes in Ethanol Levels Sampled With Subcutaneous Microdialysis

ALCOHOLISM, Issue 3 2008
Eric A. Engleman
Background:, The objective of this study was to determine time-course changes in in vivo ethanol (EtOH) concentrations using a novel subcutaneous (s.c.) microdialysis sampling technique. The hypothesis to be tested was that EtOH concentrations in the s.c. fluid would reflect blood EtOH concentrations. If this is the case, then s.c. microdialysis could allow a more detailed analysis of changes in in vivo levels of EtOH under different drinking paradigms. Methods:, Adult male and female Wistar rats and male alcohol-preferring (P) rats were used in this study. A loop-style microdialysis probe was designed for s.c. applications. After initial in vitro characterization, probes were implanted under the skin between the shoulder blades. Animals were allowed to recover 4 to 24 hours prior to microdialysis collection (2.0 ,l/min flow rate with isotonic saline). In vivo microdialysis experiments were then conducted to determine (i) the extraction fraction (or clearance) using EtOH no-net-flux (NNF) coupled with the alcohol clamp method, (ii) the dose,response and time-course effects after systemic EtOH administration and to compare with blood EtOH levels, and (iii) the time-course changes in EtOH levels during and after an EtOH drinking episode. Results:, In vivo probe recovery (extraction fraction) obtained using the alcohol clamp method was 69 ± 3%, and was comparable to the in vitro recovery of 73 ± 2%. For the EtOH dose,response experiment, rats injected i.p. with 0.5, 1.0, or 2.0 g/kg EtOH showed a clear dose,response effect in the s.c. dialysate samples. Peak concentrations (70, 123, and 203 mg%, respectively) were reached by 15 minutes after injection. In an experiment comparing levels of EtOH in s.c. dialysis and arterial blood samples in rats administered 1.0 g/kg EtOH, similar time-course changes in in vivo EtOH concentrations were observed with both i.g. and i.p. EtOH administration. In P rats drinking 15% EtOH during a 1-hour scheduled access period, EtOH levels in s.c. microdialysates rose rapidly over the session and peaked at approximately 50 mg% at 60 to 80 minutes. Conclusions:, Overall, these experiments indicate that s.c. EtOH and blood EtOH concentrations follow a similar time course. Moreover, s.c. microdialysis can be useful as an experimental approach for determining detailed time-course changes in in vivo EtOH concentrations associated with alcohol drinking episodes. [source]

Near-critical carbon dioxide extraction and liquid chromatography determination of UV filters in solid cosmetic samples: A green analytical procedure

JOURNAL OF SEPARATION SCIENCE, JSS, Issue 17 2005
Amparo Salvador
Abstract Near-critical carbon dioxide extraction of four UV filters used as sunscreens in lipsticks and makeup formulations is reported. Extraction parameters were optimized. Efficient recoveries were obtained after 15 min of dynamic extraction with a 80:20 CO2/ethanol mixture at 300 atm and 54°C, using a 1.8 mL/min flow rate. Extracts were collected in ethanol, and appropriately diluted with ethanol and 1% acetic acid to obtain a 70:30 v/v ethanol/1% acetic acid solution. The four UV filters were determined by LC with gradient elution using ethanol/1% acetic acid as mobile phase. The accuracy of the analytical procedure was estimated by comparing the results with those obtained by methods based on classical extraction. The proposed method only requires the use of CO2, ethanol and acetic acid avoiding the use of more toxic organic solvents, thus it could be considered as both operator and environment friendly. [source]

An isocratic fluorescence HPLC assay for the monitoring of l -asparaginase activity and l -asparagine depletion in children receiving E. colil -asparaginase for the treatment of acute lymphoblastic leukaemia

BIOMEDICAL CHROMATOGRAPHY, Issue 2 2009
Christa E. Nath
Abstract A novel assay for the determination of l -asparaginase activity in human plasma is described that is based on the HPLC quantitation of l -aspartic acid produced during enzyme incubation. Methods for monitoring l -asparagine depletion are also described. Chromatography of l -aspartic acid, l -asparagine and l -homoserine (the internal standard) involved derivatization with o -pthaldialdehyde, then separation from other amino acids on a Phenomenex Luna C18 column using a 1 mL/min flow rate and a mobile phase consisting of di-potassium hydrogen orthophosphate propionate buffer, pH 6, with 10% methanol and 10% acetonitrile. Fluoresence detection was at excitation/emission wavelengths of 357/455 nm. Under these conditions l -aspartic acid, l -asparagine and l -homoserine had retention times of 3.5, 9.8 and 17.7 min, respectively. The l -asparaginase assay was linear from 0.1 to 10 U/mL activity and interday precision and accuracy were less than 13%. The limit of quantitation was approximately 0.03 U/mL. The assay utility was established in 12 children who received E. colil -asparaginase as treatment for acute lymphoblastic leukaemia. Copyright © 2008 John Wiley & Sons, Ltd. [source]

Determination of the Optimal Conditions for Synthesis of Silver Oxalate Nanorods

CHEMICAL ENGINEERING & TECHNOLOGY (CET), Issue 10 2008
M. Pourmortazavi
Abstract In this study, an orthogonal array design (OAD), OA9, was employed as a statistical experimental method for the controllable, simple and fast synthesis of silver oxalate nanorods. Ultrafine silver oxalate rods were synthesized by a precipitation method involving the addition of silver ion solution to the oxalate reagent. The effects of reaction conditions, i.e., silver and oxalate concentrations, flow rate of reagent addition and temperature, on the diameter of the synthesized silver oxalate rods were investigated. The effects of these factors on the width of the silver oxalate rods were quantitatively evaluated by the analysis of variance (ANOVA). The results showed that silver oxalate nanorods can be synthesized by controlling the silver concentration, flow rate and temperature. Finally, the optimum conditions for the synthesis of silver oxalate nanorods by this simple and fast method were proposed. The results of ANOVA showed that 0.001,mol/L silver ion concentration, 40,mL/min flow rate for the addition of the silver reagent to the oxalate solution and 0,°C temperature are the optimum conditions for producing silver oxalate nanorods with 107 ± 45,nm width. [source]