n real-time traffic-related predictors but also according to various combinations of environmental conditions.Metabolomics, which consists of the comprehensive analysis of metabolites within a biological system, has been playing a growing role in the implementation of personalized medicine in modern healthcare. A wide range of analytical approaches are used in metabolomics, notably mass spectrometry (MS) combined to liquid chromatography (LC), gas chromatography (GC), or capillary electrophoresis (CE). However, none of these methods enable a comprehensive analysis of the metabolome, due to its extreme complexity and the large differences in physico-chemical properties between metabolite classes. In this context, supercritical fluid chromatography (SFC) represents a promising alternative approach to improve the metabolome coverage, while further increasing the analysis throughput. SFC, which uses supercritical CO2 as mobile phase, leads to numerous advantages such as improved kinetic performance and lower environmental impact. This chromatographic technique has gained a significant interest since the introduction of advanced instrumentation, together with the introduction of dedicated interfaces for hyphenating SFC to MS. Moreover, new developments in SFC column chemistry (including sub-2 µm particles), as well as the use of large amounts of organic modifiers and additives in the CO2-based mobile phase, significantly extended the application range of SFC, enabling the simultaneous analysis of a large diversity of metabolites. Over the last years, several applications have been reported in metabolomics using SFC-MS - from lipophilic compounds, such as steroids and other lipids, to highly polar compounds, such as carbohydrates, amino acids, or nucleosides. With all these advantages, SFC-MS is promised to a bright future in the field of metabolomics.A feasible LC-MS/MS method with reliable stabilizers consisted of sodium fluoride, ascorbic acid and formic acid was developed and validated for the determination of clevidipine and its primary metabolite (H152/81) in human plasma. Sodium fluoride existing in the vacutainer tubes was used to inhibit esterase activity to protect the clevidipine from hydrolysis as soon as blood was collected. Ascorbic acid and formic acid were added to the separated plasma samples to avoid the oxidation and further hydrolysis of clevidipine and H152/81. The further sample preparation was accomplished through a single step liquid-liquid extraction (LLE) by ethyl acetate. The chromatography separation was carried out on an ACE Excel 3 μm SuperC18 (2.1 × 50 mm, id, ACE, United Kingdom) column with gradient elution using 10 mM ammonium acetate water solution and methanol as the mobile phase. Detection was performed in the negative ion electrospray ionization mode using multiple reaction monitoring (clevidipine m/z 454.1 → 234.0; clevidipine-d7 m/z 461.1 → 240.1; H152/81 m/z 354.0 → 208.0; H152/81-13CD3 m/z 358.0 → 212.0). The method exhibited good linearity over the concentration ranges of 0.100 to 40.0 ng/mL for clevidipine and 5.00 to 400 ng/mL for H152/81. The intra- and inter-batch precision and accuracy of clevidipine and H152/81 were all within the acceptable criteria. The method was successfully applied to a pharmacokinetic study of clevidipine and H152/81 in healthy Chinese volunteers following 8 mg/h intravenous infusion of clevidipine butyrate injectable emulsion for 0.5 h. The results showed that clevidipine was rapidly eliminated with a short half-life time of 0.244 ± 0.125 h and a maximum concentration of 25.2 ± 7.09 ng/mL. H152/81 was detectable in the plasma samples up to 48.5 h with a half-life time of 10.7 ± 2.30 h and a maximum plasma concentration of 301 ± 38.1 ng/mL.The analysis of the fatty acid profile of triglycerides has long played a central role in the evaluation and classification of edible vegetable oils. However, the range of analytical procedures available to evaluate these profiles remains limited and are typically based on transesterification of the triglyceride fatty acid residues to methyl esters, followed by capillary gas-liquid chromatography (GC) coupled with flame ionization or mass spectrometry detection. Although robust and long-proven, these analytical methods tend to entail long chromatographic runs and are relatively insensitive.  https://www.selleckchem.com/products/gyy4137.html  In order to expand the range of available techniques for the analysis of the fatty acid profile of triglycerides in vegetable oils, we report herein a novel method based upon a rapid and straightforward transesterification of the triglycerides with dimethylaminoethanol under alkaline conditions, followed by a "dilute-and-shoot" analysis by ultra-performance liquid chromatography coupled with electrospray tandem mass spectrometry. The chromatographic analysis is accomplished in 1.5 min, affording a high throughput of samples compared to techniques based upon GC approaches. The method performance was assessed intra- and inter-day with 10 representative saturated and unsaturated fatty acids ranging from C8 to C18 and afforded fatty acid profile accuracies of 93-108% and imprecisions of only 0.3-2.0%. The limit of quantification of the method, estimated as the minimum amount of derivatized oil sample capable of affording less than 20% accuracy and precision error was determined to be approximately 0.5 pg on-column, making this new method potentially valuable for fields where high sensitivity, precision, and accuracy may be required, such as in toxicology studies, forensics, archeology, or art analysis.Bio-affinity chromatography is used in the study of drug-receptor interactions. A stepwise frontal analysis (SFA) method was developed based on frontal analysis (FA). A high expression alpha 1A adrenergic receptor (α1A AR) cell membrane chromatography (CMC) method was then developed and combined with SFA to investigate the affinity of three model α1A AR-binding drugs towards α1A AR. Equilibrium dissociation constant (Kd) values for drug-receptor interactions were determined by FA and SFA; results showed that these methods were highly consistent. The results demonstrate that the CMC/SFA method is a time-saving and less wasteful method than traditional method for the evaluation of drug-receptor binding characteristics, and could be used to study the interactions between drugs and membrane receptors.