Poster Sessions AP13: Novel Techniques and Technologies. A simple and sensitive HPLC‐method for simultaneous monitoring of oxidative stress indices and monoamine metabolites

Studies of the antioxidant defense system and the monoamine metabolic pathways are often complicated by cumbersome analytical methods, which require separate and multistep extraction and chemical reaction procedures. Thus, measurements of multiple parameters are limited in relatively small biological samples. High performance liquid chromatography (HPLC) coupled with a Coulometric Multi‐Electrode Array System (CMEAS) provides us a convenient and most sensitive tool to measure low molecular weight, redox‐active compounds in biological sample. The deproteinized sample was analyzed on a HPLC coupled with a 16‐channel CMEAS, which incremented from 60 to 960 mV in 60 mV steps. Each sample was run on a single column (Meta‐250, 4.6 × 250 mm) under a 150‐minute complex gradient that ranged from 0% B (A: 1.1% pentane sulfonic acid) to 20% B (B: 0.1 m lithium acetate in mixture of methanol, acetonenitrile and isopropanol), with a flow rate of 0.5 mL/min. We have developed an automated procedure to simultaneously measure various antioxidant, oxidative stress marker, and monoamine metabolites in a single column with binary gradient. No other chemical reactions are necessary. In order to reduce the running time and yet achieve a reproducible retention time by the autosampler injection, our gradient elution profile was modified to produce a shorter equilibration time and to compensate for the initial contamination of mobile phase B following the first injection. Without the use of two columns in series and peak suppresser/gradient mixer, we have simplified the previously published method to measure over 20 different antioxidants, oxidative stress markers and monoamine metabolites simultaneously in biological samples.     

Comparison of ion-pair and amide-based column reversed-phase liquid chromatography for the separation of thiamine-related compounds

Two reversed-phase chromatographic methods for the separation of thiamine and related compounds are compared. The first procedure is based on the ion-pair technique using an octadecylsilica column, while the second uses a new amide-based stationary phase, which avoids the need to form ion-pairs, leading to narrower peaks and a simpler mobile phase. Analyses were performed by gradient elution and a photo-diode array was used for detection. Specificity was demonstrated by the retention characteristics, UV spectra and by comparing the peak purity index with commercial standards. The procedures were applied to the determination of thiamine-related compounds in pharmaceutical preparations and urine. No preliminary sample treatment was required.     

Theory-guided efficient strategy to maximize speed and resolution in rapid gradient LC-MS/MS bioanalysis

Reversed-phase gradient LC-MS/MS bioanalytical methods of 5-100% organic solvent in a 1-3 min gradient time are common in today's bioanalytical laboratory. The goal of this work was to develop a theory-guided systematic strategy for maximizing resolution and speed in rapid gradient LC-MS/MS bioanalysis. We studied the effect of gradient time (t(G)), initial and final eluent strength (% B=% organic), and flow rate (F) on the separation of multiple critical pairs (R(s)) and peak capacity (n(c)) in a gradient elution of a mixture of five structurally related compounds. By optimizing the gradient time t(G), the initial and final percentages of the organic component of the mobile phase, comparable resolution and peak capacity could be achieved in a shorter run time. More importantly, we demonstrated that higher flow rates improved resolution, peak capacity and reduced run time in rapid gradient separations on a 5 μm particle column. A straightforward mathematical explanation of the phenomenon was provided applying basic resolution equations in gradient elution theory. A systematic approach to execute a rapid gradient LC-MS/MS bioanalytical method to shorten run time and improve resolution is proposed, taking into consideration not only the analytes of interest but also potential matrix effects from the dosing vehicle and biological matrix.     

Development of a high-performance liquid chromatography retention index scale for toxicological drug screening

An efficient and practical analytical method for correcting HPLC retention data has been produced using an HPLC diode-array UV detector system. The system is based on retention indices (RI) and is to be used primarily for the identification of toxicologically relevant drugs involved in clinical and forensic toxicology. The RI correction method was chosen as it provided a slightly greater degree of reproducibility than using relative retention time (RRT), particularly for acidic and neutral drugs. Development of the system involved the establishment of the optimal chromatographic conditions and extensive studies of the stability of the system. An acetonitrile gradient elution was used with RI values determined by interpolation from a series of specifically chosen basic and acidic/neutral marker drugs which eluted at regular intervals to produce a linear RI scale. It was found that two separate RI scales were required for basic and acidic/neutral drugs. The use of multiple drug markers as primary retention index standards had not been previously applied to HPLC general drug screening and comparison with a recently published database suggests that the system may also provide improved selectivity.     

High performance liquid chromatography of nucleotides. Major methods and their development

The separation of mono- and oligonucleotides possibilities by means of high performance ion-exchange, reversed-phase, so-called "ion-pair" and adsorption chromatography are studied. The influence of the eluent composition (solvent, salt) and pH on the retention, selectivity and resolution in reversed-phase and ion-exchange chromatography is investigated. The model of the hydrophobic-pair ion-exchange mechanism of ion-pair chromatography is considered. The conditions for analysis and preparative isolation of a desired component are optimized for selectivity, resolution and throughput. The methods for prediction of the optimal gradient elution program reasonable resolution at the desired retention time and for choosing the guard-column packing material are proposed. A design of the gradient for system and the version of slurry packing method for HPLC prolonged life-time columns are improved. The automatized analytical technique for determination of the oligonucleotide monomeric composition with two coupled microcolumns is described, that involves enzymatic digestion of an oligonucleotide followed by ion-exchange separation of the hydrolysate.     

Porous graphitic carbon shows promise for the rapid chromatographic analysis of polar drug metabolites

A rapid and simple HPLC method has been developed and used to separate the polar metabolic conjugates of AZT, chloramphenicol, and β-estradiol based upon the use of porous graphitic carbon. The HPLC system is sufficiently selective to resolve the polar drug conjugates from their parent compounds and from endogenous material present in urine. The compounds are separated, without the need for sample pretreatment or gradient elution, on a porous graphitic carbon (Hypercarb) column using aqueous trifluoroacetic acid modified with tetrahydrofuran as the mobile phase. Porous graphitic carbon exhibits a novel mechanism of retention towards these very polar substances, which are unretained under reversed-phase conditions on alkyl-bonded silica phases.     

Measurement of opioid peptides with combinations of reversed phase high performance liquid chromatography, radioimmunoassay, radioreceptorassay, and mass spectrometry

Novel state-of-the-art mass spectrometric methods have been developed and are now used to identify and to quantify enkephalins and other neuropeptides in biological tissue extracts. As the first step, RP-HPLC gradient elution is performed of a Sep-Pak treated peptide-rich fraction from a tissue extract, and the eluent is monitored by a variety of post-HPLC detectors. In an effort to maximize the structural information that can be obtained from the analysis, UV (200 nm) provides the analog absorption trace; receptorassay analysis (RRA) data of all (90) fractions that are collected are used to construct the profile of opioid-receptoractive peptides; radioimmunoassay (RIA) of selected HPLC fractions at retention times corresponding to the retention time of standards, or in some special cases of all 90-fractions, provides immunoreactivity information; and fast atom bombardment mass spectrometry (FAB-MS) in two modes - corroboration of the (M+H)+ of the expected peptide, or MS/MS to monitor an amino acid sequence-determining fragment ion unique to that peptide in the selected ion monitoring (SIM) mode - provides structural information. As a demonstration of the level of quantification sensitivity that can be attained by these novel MS methods, FAB-MS-MS-SIM of solutions of synthetic leucine enkephalin was sensitive to the 70 femtomole level. This paper discusses RIA versus RRA data, and recent MS measurements of peptides in human tissues.     

Selectivity of IMAC columns in trypsin inhibitor purification

The properties of an adsorbent and the parameters in an adsorption process affect the resolution of chromatographic purifications. This is reflected in the elution profile, which shows the relative affinity of different proteins for a specific adsorbent. In the work presented here, elution profiles for trypsin inhibitor were used to study the effects of the concentration of trypsin inhibitor, ionic strength of the protein solution, slope of the elution gradient, and the regeneration treatment of the chromatography column on the selectivity of the adsorbent Cellufine Chelate-Cu(II)(ida). Cytochrome c was used as a reference protein. Variations in the concentrations of trypsin inhibitor and in the ionic strength of the buffered solution did not have any effects on the elution profile. On the other hand, changes in the slope of the pH gradient used for elution caused shifting of the elution peaks toward lower values of the elution volume, resulting in the best strategy to modify the elution profile of the system. Finally, using a constant slope pH gradient of elution, the variation of the selectivity of the adsorbent for trypsin inhibitor when subjected to cleaning treatments with 0.5 N NaOH was studied. Appropriate cleaning practices used in industry were followed. The adsorbent showed only a slight tendency for resolution loss in the order of 2 x 10(-4) days(-1). The results presented here show a good stability of the adsorbent when compared to other biospecific adsorbents commonly used.     

Highly multiplexed targeted proteomics using precise control of peptide retention time

Large-scale proteomics applications using SRM analysis on triple quadrupole mass spectrometers present new challenges to LC-MS/MS experimental design. Despite the automation of building large-scale LC-SRM methods, the increased numbers of targeted peptides can compromise the balance between sensitivity and selectivity. To facilitate large target numbers, time-scheduled SRM transition acquisition is performed. Previously published results have demonstrated incorporation of a well-characterized set of synthetic peptides enabled chromatographic characterization of the elution profile for most endogenous peptides. We have extended this application of peptide trainer kits to not only build SRM methods but to facilitate real-time elution profile characterization that enables automated adjustment of the scheduled detection windows. Incorporation of dynamic retention time adjustments better facilitate targeted assays lasting several days without the need for constant supervision. This paper provides an overview of how the dynamic retention correction approach identifies and corrects for commonly observed LC variations. This adjustment dramatically improves robustness in targeted discovery experiments as well as routine quantification experiments.     

Crystallization and properties of myeloperoxidase from normal human leukocytes

Myeloperoxidase was purified from normal human leukocytes in a crystalline state. Two types of crystals were obtained by the batchwise and dialysis crystallization methods, one of which had a bipyramidal shape belonging to the orthorhombic system. Three multiple forms of human myeloperoxidase were separated from the crystalline enzyme by CM-Sepharose chromatography with sodium chloride gradient elution. These three multiple forms were found to have very similar enzymatic, spectroscopic, and chemical properties. However, slight differences were observed in their amino acid compositions and the molecular weights of their large subunits determined by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. Hemi-myeloperoxidase was prepared from holo-myeloperoxidase by reduction with dithiothreitol and modification with iodoacetamide, and the molecular shapes of the holo- and hemi-enzymes were determined by analytical ultracentrifugation. The axial ratios were calculated to be 2.4-3.5 for the holo-enzyme and 2.9-3.1 for the hemi-enzyme. These results suggest that the shapes of the two enzymes are more spherical in solution than the proposed structural model previously reported.     

Rapid protein separation and diffusion coefficient measurement by frit inlet flow field-flow fractionation.

In this study three flow field-flow fractionation (flow FFF) channels are utilized for the separation of proteins and for the simultaneous measurement of their translational diffusion coefficients, D. One channel has a traditional sample inlet, whereas the other two incorporate a frit inlet design that permits more convenient and rapid sample introduction. The dependence of retention time on D, which leads to differential elution and the opportunity to measure D for protein peaks purified by the flow FFF process, is described theoretically and examined experimentally. Factors affecting band broadening, resolution, and optimization are also examined. The separation of proteins is achieved in the time range 4-20 min. Partial resolution is achieved in multiple runs requiring 2 min each. Values of D calculated from retention times are reported for 15 proteins. These include two protein dimers (bovine serum albumin and gamma-globulin) not ordinarily accessible to measurement. The D values from the three channels are compared with one another and with literature data. Reasonable consistency (within 3-4%) is found. High-speed repetitive runs can be used to acquire multiple values of D in time intervals as short as 1 min.     

Rapid analysis of the interactions between drugs and human serum albumin (HSA) using high-performance affinity chromatography (HPAC)

This study used a combination of zonal elution and frontal affinity chromatography on immobilized human serum albumin (HSA) high-performance affinity chromatography (HPAC) column to examine the association constants of various compounds that have been studied by equilibrium dialysis or ultra filtration. A standard plot was generated from retention factors of reference compounds using zonal elution chromatography against association constants of reference compounds using frontal affinity chromatography. The linear relationship was established (r2=0.9993) between retention factors and association constants of reference compounds. This standard plot was later used for rapid determination of association constants of various drugs which show low to medium binding affinity to HSA. Association constants of those drugs from this study were compared to that of more generally used methods (i.e., equilibrium dialysis or ultra filtration) from literature and resulted in a relatively high correlation (r2=0.945) value. This combination of zonal elution and frontal affinity chromatography method for determining association constants showed several advantages against traditional methods. Depending on drugs of interest, an association constant of drug to HSA can be measured as fast as 1.5 min. Other notable advantages include an ease of automation and its ability to distinguish association constants of chiral compounds at the same time. The same approach could be used for studying interaction of other drugs and proteins and should further improve overall drug screening process.     

Evaluation of differences between dual salt‐pH gradient elution and mono gradient elution using a thermodynamic model: Simultaneous separation of six monoclonal antibody charge and size variants on preparative‐scale ion exchange chromatographic resin

The efficiencies of mono gradient elution and dual salt‐pH gradient elution for separation of six mAb charge and size variants on a preparative‐scale ion exchange chromatographic resin are compared in this study. Results showed that opposite dual salt‐pH gradient elution with increasing pH gradient and simultaneously decreasing salt gradient is best suited for the separation of these mAb charge and size variants on Eshmuno^® CPX. Besides giving high binding capacity, this type of opposite dual salt‐pH gradient also provides better resolved mAb variant peaks and lower conductivity in the elution pools compared to single pH or salt gradients. To have a mechanistic understanding of the differences in mAb variants retention behaviors of mono pH gradient, parallel dual salt‐pH gradient, and opposite dual salt‐pH gradient, a linear gradient elution model was used. After determining the model parameters using the linear gradient elution model, 2D plots were used to show the pH and salt dependencies of the reciprocals of distribution coefficient, equilibrium constant, and effective ionic capacity of the mAb variants in these gradient elution systems. Comparison of the 2D plots indicated that the advantage of opposite dual salt‐pH gradient system with increasing pH gradient and simultaneously decreasing salt gradient is the noncontinuous increased acceleration of protein migration. Furthermore, the fitted model parameters can be used for the prediction and optimization of mAb variants separation in dual salt‐pH gradient and step elution. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 34:973–986, 2018     

Gradient elution reversed-phase chromatographic isolation of individual glycerophospholipid molecular species

We describe a gradient elution reversed-phase high-performance liquid chromatographic approach for isolation of individual glycerophospholipid molecular species which greatly improves resolution and reduces run time compared to isocratic techniques. Separations were optimized and elution order and retention time data established by synthesizing 37 different homogeneous phospholipids comprising the major alkylacyl, diacyl and plasmalogen molecular species in samples derived from mammalian sources. Empirical equations which predict the elution order of individual species were derived. The method was validated with the use of complex mixtures of choline and ethanolamine glycerophospholipid species from isolated rabbit cardiomyocytes and porcine endothelial cells.     

Analysis and retention behaviour in high-performance liquid chromatography of terpenic plant constituents (Sideritis spp.) with pharmacological interest

Terpenoids are natural products with an important pharmacological interest, which are present in a number of medicinal plants. The species of Sideritis genus are valuable due to their high content in those compounds and they have been used in the Mediterranean area in folk medicine as anti-inflammatory and anti-ulcer agents. The present study describes a gradient elution reversed-phase method that uses diode array detection to determine ten pharmacologically active diterpenoids occurring in 12 species of Sideritis. First, we studied the chromatographic behaviour of standard diterpenoids to analyse the variation on retention time and the chromatographic properties with the mobile phase. Standard calibration curves were generated by plotting the area of peaks against a concentration range of the compounds. Second, the validated method was applied to the analyses of hexanic and methanolic extracts from 12 species of Sideritis, which were collected from different areas of Spain. Finally, we established for this plant a relationship between their use in folk medicine and their diterpenoid content.     

Measurement of double-strand breaks in Chinese hamster cell DNA by neutral filter elution: calibration by 125I decay

We labeled the DNA of Chinese hamster lung V79 cells with 125I in the form of iododeoxyuridine and subsequently measured the elution of the DNA through polycarbonate filters at pH 9.6 and pH 7.2. Since decay of incorporated 125I produces predominantly double-strand breaks (DSB) in DNA at a rate close to one DSB per 125I decay, this measurement provides an absolute calibration for the assay of DSBs by neutral filter elution. Neutral elution profiles are not first order with respect to elution time; thus we have examined the relationships between accumulated 125I decays and several functions of retention of DNA on the filter at various times during the elution process. At both pH 9.6 and pH 7.2 there were linear relationships between accumulated decays and certain retention functions. The retention function most closely correlated to 125I decays for both pH values was the logarithm of the ratio of the retention of control DNA to that of 125I-labeled DNA, both evaluated at the 9th fraction (13.5 h of elution). The linear relationship between this ratio and 125I decays allows DSB induction to be determined directly from retention values. The calibration was used to measure DSBs induced by X rays.     

Optical resolution of some biologically active compounds by chiral liquid chromatography on BSA-silica (resolvosil) columns

Optical resolution on the analytical scale of a number of racemic pharmaceuticals and some other biologically active compounds has been studied using immobilized bovine serum albumin (BSA) as the stationary phase. For some of the compounds the elution order was determined by the use of optically enriched fractions obtained from a preceding passage of a sample through a preparative column containing microcrystalline triacetylcellulose (MCTA). The reversal in the sign of optical rotation shown in the polarimetric elution profile from the latter, combined with the integrated peak area ratio obtained on resolution on the analytical column, gave directly the order of elution. For one of the benzothiadiazines studied (bendroflumethiazide), increasing the pH of the mobile phase produced opposite effects on the retention of the two enantiomers, leading to a large effect on the separation factor. For many of the compounds studied, high separation factors (α > 2) could be achieved.     

An approach towards method development for untargeted urinary metabolite profiling in metabonomic research using UPLC/QToF MS

The application of LC-MS for untargeted urinary metabolite profiling in metabonomic research has gained much interest in recent years. However, the effects of varying sample pre-treatments and LC conditions on generic metabolite profiling have not been studied. We aimed to evaluate the effects of varying experimental conditions on data acquisition in untargeted urinary metabolite profiling using UPLC/QToF MS. In-house QC sample clustering was used to monitor the performance of the analytical platform. In terms of sample pre-treatment, results showed that untreated filtered urine yielded the highest number of features but dilution with methanol provided a more homogenous urinary metabolic profile with less variation in number of features and feature intensities. An increased cycle time with a lower flow rate (400mul/min vs 600mul/min) also resulted in a higher number of features with less variability. The step elution gradient yielded the highest number of features and the best chromatographic resolution among three different elution gradients tested. The maximum retention time and mass shift were only 0.03min and 0.0015Da respectively over 600 injections. The analytical platform also showed excellent robustness as evident by tight QC sample clustering. To conclude, we have investigated LC conditions by studying variability and repeatability of LC-MS data for untargeted urinary metabolite profiling.     

High-performance liquid chromatographic separation and measurement of various biogenic compounds possibly involved in the pathomechanism of Parkinson’s disease

The work presented here describes an optimised, reversed-phase high-performance liquid chromatographic (RP-HPLC) method for separating 46 biogenic compounds, which, as neurotoxins or as their precursors or derivatives, may be relevant in the pathomechanism of Parkinson’s disease. In some cases, the physico–chemical properties of these substances are very similar, in other cases they differ greatly. In order to facilitate their detection in one chromatographic run, ion-pair chromatography was uniquely combined with a gradient elution. A diode array or a dual wavelength detector was used in combination with a fluorescence detector to verify the identity of the compounds.