Paul Rainville

Ion-pair reversed-phase high-performance liquid chromatography analysis of oligonucleotides:: Retention prediction

An ion-pair reversed-phase HPLC method was evaluated for the separation of synthetic oligonucleotides. Mass transfer in the stationary phase was found to be a major factor contributing to peak broadening on porous C18 stationary phases. A small sorbent particle size (2.5 microm), elevated temperature and a relatively slow flow-rate were utilized to enhance mass transfer. A short 50 mm column allows for an efficient separation up to 30mer oligonucleotides. The separation strategy consists of a shallow linear gradient of organic modifier, optimal initial gradient strength, and the use of an ion-pairing buffer. The triethylammonium acetate ion-pairing mobile phases have been traditionally used for oligonucleotide separations with good result. However, the oligonucleotide retention is affected by its nucleotide composition. We developed a mathematical model for the prediction of oligonucleotide retention from sequence and length. We used the model successfully to select the optimal initial gradient strength for fast HPLC purification of synthetic oligonucleotides. We also utilized ion-pairing mobile phases comprised of triethylamine (TEA) buffered by hexafluoroisopropanol (HFIP). The TEA-HFIP aqueous buffers are useful for a highly efficient and less sequence-dependent separation of heterooligonucleotides.

Comprehensive investigation of the influence of acidic, basic, and organic mobile phase compositions on bioanalytical assay sensitivity in positive ESI mode LC/MS/MS.

The sensitivity and accuracy of a bioanalytical method is critical in defining the pharmacokinetic (PK) parameters of a potential new chemical entity (NCE). Inhaled therapeutics and low dose NCEs present one of the most significant analytical challenges to the bioanalyst, due to their low systemic concentration. The sensitivity of a bioanalytical LC/MS/MS based assay can be influenced by multiple parameters, including: mobile phase composition, extraction efficiency and chromatographic performance. In this work, we discuss the influence of acidic (pH 3), and basic (pH 10) aqueous mobile phases in conjunction with the two most common organic modifiers used in HPLC, acetonitrile and methanol, on the assay sensitivity of twenty-four probe pharmaceuticals in solvent and biological fluid extract. The study showed that when the test probe pharmaceuticals were analyzed with basic aqueous mobile phases compared to standard acidic conditions the following results were observed: increases in chromatographic peak area ranging from 1.2 to 9.6 fold for twenty-one of the test compounds as well as increased signal-to-noise for greater than seventy percent of the compounds. This observed increase in the MS response was not necessarily related to the later elution of the analyte in a higher organic composition under basic conditions. This was demonstrated as seven out of the twenty-four (approximately thirty percent) of the probe pharmaceuticals tested, eluted earlier, or with the same retention time, under basic conditions, and still produced a greater signal-to-noise when analyzed under these basic conditions. Also observed were decreases in chromatographic peak width, and increases in the retention time of very hydrophilic pharmaceutical compounds. The effect of the mobile phase combinations on the retention and MS response of the choline-containing phospholipids present in precipitated plasma was also investigated, as these analytes are a major source of interference when developing a bioanalytical assay.

Addressing the analytical throughput challenges in ADME screening using rapid ultra‐performance liquid chromatography/tandem mass spectrometry methodologies

High-throughput ADME screening for compound drug development properties has become an essential part of the modern drug discovery process, allowing more informed decisions to be made on the best compounds to take forward in the discovery/development process. This however is a time-consuming process requiring multiple tests to be performed, demanding a significant amount of liquid chromatography/mass spectrometry (LC/MS) instrument time. This article focuses on the use of sub-2 microm porous particle LC coupled to tandem quadrupole MS/MS mass spectrometry for the rapid screening of ADME properties. Using this approach analysis times from 30 s to 1 min were achievable allowing analysis times to be cut by 80%. The use of the small particles coupled to high flow rates allowed for sufficient resolution, even with very short analysis time, to resolve the analytes of interest from similar compounds that would interfere with the assay. The use of dedicated, intelligent, software packages allowed for the user-free generation of MS/MS conditions and the processing of the data.

Comparison of the quantification of a therapeutic protein using nominal and accurate mass MS/MS

BACKGROUND The quantification of proteins and peptides in in vivo samples is a critical part of supporting the drug development process for biotherapeutics. LC-MS/MS using tandem quadrupole mass spectrometers is well established as the technology of choice for the quantification of small-molecule drugs and their metabolites in biological fluid. The application of accurate mass MS for quantification in a DMPK environment has attracted considerable interest in recent years. MATERIALS & METHODS In this article we describe and compare the application of LC-high-resolution MS and LC-selected reaction monitoring (SRM) for the quantification of a therapeutics proteins. RESULTS The accurate mass instrumentation showed acceptable linearity and sensitivity to quantify the protein therapeutic to the level of 10 ng/ml. The accurate mass instrument was operated in accurate mass SRM using high resolution (SRM-HR), the assay was demonstrated to be linear over three orders of magnitude. By narrowing the mass window from 100 mDa to 40 mDa and then to 20 mDa the assay specificity was significantly improved, hence increasing the S/N and improving the assay sensitivity. CONCLUSION The high-resolution instrument was demonstrated to be reproducible over the course of the assay. The accurate mass method sensitivity was determined to be within one order of magnitude of that obtained with a tandem quadrupole MS/MS assay.

A rapid ultra-performance liquid chromatography/tandem mass spectrometric methodology for the in vitro analysis of Pooled and Cocktail cytochrome P450 assays

Drug-drug interaction evaluations of new pharmaceutical candidates are critical to preventing drug withdrawal and are routinely determined through the use of cytochrome P450 assays. The measurement of the effect of test compounds on the metabolism of known substrates allows for the determination of specific CYP450 isoenzyme inhibition and calculation of IC50 values. A sensitive, high-throughput ultra-performance liquid chromatography/tandem mass spectrometric (UPLC/MS/MS) method is presented for the evaluation of CYP450 inhibition. The assay was performed using a cocktail of probe substrates and the results were compared to those obtained with the more time-consuming methodology utilizing individual substrates. The use of a high-resolution, sub-2 microm particle, LC system allowed for a high-throughput assay of just 1 min. The extra resolution of the UPLC/MS/MS system allowed for the complete resolution of the analytes, with a fast switching MS for comprehensive data collection. The CYP450 inhibition results obtained using the substrate cocktail approach were found to be essentially identical to those obtained using individual substrates.

Sub one minute inhibition assays for the major cytochrome P450 enzymes utilizing ultra‐performance liquid chromatography/tandem mass spectrometry

The measurement of cytochrome P450 (CYP450) isoenzyme inhibition is often done during evaluation of new chemical entities in drug discovery. Typical assay protocol consists of multiple CYP450 probe substrates incubated with selected drug candidates and CYP450. Results of the assay, the amount of probe substrate metabolite formed with respect to control, are used to determine the level of interaction. Liquid chromatography utilizing columns packed with sub-2-micron particles have been shown to provide up to 8X faster analysis time and 3X increases in sensitivity over traditional high-performance liquid chromatography (HPLC). The work presented here shows the development of a high-throughput, sub-2-micron particle LC method coupled with tandem quadrupole mass spectrometry for the rapid analysis of six CYP450 probe substrate metabolites in 30s.

Ultra high resolution SFC–MS as a high throughput platform for metabolic phenotyping: Application to metabolic profiling of rat and dog bile☆

Ultra high resolution SFC-MS (on sub-2μm particles) coupled to mass spectrometry has been evaluated for the metabolic profiling of rat and dog bile. The selectivity of the SFC separation differed from that seen in previous reversed-phase UPLC-MS studies on bile, with the order of elution for analytes such as e.g., the bile acids showing many differences. The chromatography system showed excellent stability, reproducibility and robustness with relative standard deviation of less than 1% for retention time obtained over the course of the analysis. SFC showed excellent chromatographic performance with chromatographic peak widths in the order of 3s at the base of the peak. The use of supercritical fluid carbon dioxide as a mobile phase solvent also reduced the overall consumption of organic solvent by a factor of 3 and also reduced the overall analysis time by a factor of 30% compared to reversed-phase gradient LC. SFC-MS appear complementary to RPLC for the metabolic profiling of complex samples such as bile.

Study of UltraHigh Performance Supercritical Fluid Chromatography to measure free fatty acids with out fatty acid ester preparation

Most lipids are best characterized by their fatty acids which may differ in (a) chain length, (b) degree of unsaturation, (c) configuration and position of the double bonds, and (d) the presence of other functionalities. Thus, a fast, simple, and quantitative analytical technique to determine naturally occurring free fatty acids (FFA) in different samples is very important. Just as for saponified acylglycerols, the determination of FFAs has generally been carried out by high resolution gas chromatography (HRGC). The use of an open tubular capillary column coupled with a flame ionization or mass spectrometric detector provides for both high resolution and quantification of FFAs but only after conversion of all free fatty acids to fatty acid methyl esters (FAME) or pentafluorobenzyl esters. Unfortunately, volatilization of labile ester derivatives of mono- and poly-unsaturated FFAs can cause both thermal degradation and isomerization of the fatty acid during HRGC. The employment of a second generation instrument (here referred to as UltraHigh Performance Supercritical Fluid Chromatograph, UHPSFC) with high precision for modified flow and repeated back pressure adjustment in conjunction with sub-2μm various bonded silica particles (coupled with evaporative light scattering, ELSD, and mass spectrometric, MS, detection) for separation and detection of the following mixtures is described: (a) 31 free fatty acids, (b) isomeric FFAs, and (c) lipophilic materials in two real world fish oil samples. Limits of detection for FFAs via UHPSFC/MS and UHPSFC/ELSD versus detection of FAMEs via HRGC/MS are quantitatively compared.

Addressing the challenge of limited sample volumes in in vitro studies with capillary-scale microfluidic LC–MS/MS

Miniaturization of chromatographic separation systems provides a means of greatly increasing sensitivity in LC-MS. In this article, we demonstrate the use of an integrated microfluidic chromatographic device for the LC-MS/MS investigation of the in vitro microsomal metabolism of the model drug propranolol using a sample volume of 1 µl of a 1-µM incubation. With such samples the system was capable of obtaining high-quality MS and MS/MS data from the injection of test drug substance containing sufficient information to correctly derive the structure of the drug metabolites. The analytical column was tolerant to the injection of a large percentage of organic solvent in the sample and still delivered a high-quality separation. The data suggest that these types of micro-LC-MS/MS devices are robust enough for routine applications and well suited to the analysis of small samples. Other potential applications include the generation of pharmacokinetic profiles from the reduced sample volumes obtained from serially bled small rodent studies, or the facilitation of analysis of limited-volume samples from neurological studies.

Investigation of microbore UPLC and nontraditional mobile phase compositions for bioanalytical LC–MS/MS

BACKGROUND The movement towards environmentally friendly or green chemistry solutions has gained more prominence recently in the scientific community. One way in which scientists can address this issue is to limit the use of hazardous chemicals in their everyday processes. Therefore, the focus of this study was on the utilization of microbore-scale chromatography and nontraditional alcoholic mobile phases as an alternative approach to traditional bioanalytical LC-MS/MS assay parameters. RESULTS Replacement of the traditional narrowbore LC column with a microbore format reduced solvent consumption and produced a greater than threefold increase in S/N. The nontraditional alcoholic mobile phases, ethanol or isopropanol, produced either greater peak area counts, or S/N, for over half of the compounds evaluated, compared with the traditional organic mobile phases of acetonitrile and methanol. These nontraditional alcoholic mobile phases also showed improved capability in the removal of plasma phospholipid components from the chromatographic column. The ionizable background detected in each of the organic mobile phases utilized in this study produced a unique background that may or may not interfere with compounds undergoing analysis. CONCLUSION The combination of microbore columns and nontraditional alcoholic mobile phases has been shown to produce effective, alternative method conditions to traditional bioanalytical LC-MS/MS method parameters.