Linear Solvation Energy Relationships in the Determination of Specificity and Selectivity of Stationary Phases

The retention of fifty structurally different compounds has been studied using linear solvation energy relationships. Investigations were performed with the use of six various stationary phases with two mobile phases (50/50 % v/v methanol/water and 50/50 % v/v acetonitrile/water). Packing materials were home-made and functionalized with octadecyl, alkylamide, cholesterol, alkyl-phosphate and phenyl molecules. This is the first attempt to compare all of these stationary phases synthesized on the same silica gel batch. Therefore, all of them may be compared in more complex and believable way, than it was performed earlier in former investigations. The phase properties (based on Abraham model) were used to the classification of stationary phases according to their interaction properties. The hydrophilic system properties s, a, b indicate stronger interactions between solute and mobile phase for most of the columns. Both e and v cause greater retention as a consequence of preferable interactions with stationary phase by electron pairs and cavity formation as well as hydrophobic bonds. However, alkyl-phosphate phase has different retention properties, as it was expressed by positive sign of s coefficient. It may be concluded that most important parameters influencing the retention of compounds are volume and hydrogen bond acceptor basicity. The LSER coefficients showed also the dependency on the type of organic modifier used as a mobile phase component.

     

Influence of selected mobile phase properties on the TLC retention behavior of ziprasidone and its impurities

ABSTRACT

Influence of nine different solvents, either alone or in a mixture, on the retention behavior of ziprasidone and its five impurities were examined by normal-phase thin-layer chromatography. Migration distances of the examined compounds obtained under the examined chromatographic conditions were correlated with calculated mobile phase properties, such as Snyder polarity and Hansen solubility. Linear or second-order polynomial relationships with high correlation coefficients were established between investigated variables. The obtained mathematical functions and statistical results indicated that selected mobile phase properties can be used for the prediction of the retention behavior of ziprasidone and its five impurities.     

Unusual Temperature-Retention Dependences Observed for Several Benzodiazepines in RP-HPLC Using Different Mobile Phase Compositions

Non-linear van’t Hoff plots were observed for several benzodiazepines over the usual temperature interval used in RP-LC (10–60 °C), when acetonitrile was added in the mobile phase. Such deviation from linearity was not observed when methanol or isopropanol was added to the mobile phase. Polynomial regressions were applied to fit the experimental data when acetonitrile was used as organic additive in mobile phase. The second-order polynoms may allow finding out the maximum retention depending on temperature, which can be within or out of the normal temperature range used in RP mechanism. A thermodynamic model deriving from the partition of two or more tautomers of the same analyte was proposed to explain this deviation from linearity of van’t Hoff plots.

     

On the Determination of the Hold-Up Time in Reversed Phase Liquid Chromatography

Abstract

The determination of the hold-up time in reversed phase liquid chromatography has been studied extensively for the mobile phase system methanol-water. Hold-up times obtained by static methods, linearization of homologous series and so-called “unretained compounds” are discussed and mutually compared. Several n-alkyldimethylsilyl bonded phases have been used for this investigation.

A rough estimate of the hold-up time can be obtained by using components of the mobile phase or highly concentrated salt solutions, but only for mobile phase compositions around 60% (v/v) methanol. Hold-up times accurate to 1% can be obtained over the complete range of mobile phase compositions from the linearization of net retention times of homologous series.     

“PRISMA” Model for Computer-Aided HPLC Mobile Phase Optimization Based on an Automatic Peak Identification Approach

Abstract

The tripartite “PRISMA” optimization model, as part of the “PRISMA” system, includes all possible solvent combinations between 1–4 solvents, with a possible fifth one as modifier. The solvent composition is characterized by the solvent strength (S_T) and the selectivity points (P_S).

At a constant S_T the correlation between the P_S and the retention data (horizontal function) can be described by a quadratic function. For constant P_S the solvent strengths and retention data correlate (vertical function) with a logarithmic function. These correlations are used to formulate a mathematical model for the dependence of retention times (capacity factor) on the mobile phase composition. Unknown compounds are estimated in the mathematical model from a sequence of standard chromatograms after having identified individual peaks by an automatic procedure. Only retention times, relative peak areas, and information about the mobile phase compositions are required as input for the identification approach. The approach involves a combination of statistical methods which exploit both the basic properties of retention data and the mathematical relation between retention data, selectivity points, and solvent strength as derived from the “PRISMA” model. Diagnostic information for checking the identification is generated as a by-product. The mathematical model completed by the estimated constants predicts the expected retention times for each possible mobile phase combination. Peak start and peak end times are predicted in a way similar to the retention times, once the identification has been performed. The most important aspects of a chromatogram can thus be predicted for arbitrary mobile phases.

The separation quality of predicted chromatograms is assessed by the chromatographic response function (CRF). The optimal mobile phase combination is that which theoretically generates the chromatogram with the maximal CRF value. This optimal composition is found by a simple mathematical procedure, which maximises the CRF in dependence upon the mobile phase combination. The optimum found is a local one if the starting set of chromatograms contains no variation of the solvent strength, and a global one if, in the set of starting chromatograms, the solvent strength is varied in a suitable way. Recommendations for the starting position are given.

Twelve measurements are necessary for a local optimum, and 15 for the global one. To increase the accuracy, six measurements at three different solvent strength levels are proposed. Generally the highest and the lowest solvent strength level differ by ±(5)% from the middle level.

This strategy is also relevant when modifiers are used in constant amounts. The chromatographic behavior of substances to be separated can be predicted with 1% accuracy from correlations of k' values and selectivity points. Based on these relationships, an automatical mobile phase optimization strategy for isocratic separations is suggested with the “PRISMA” model.     

The Effect of Binary Solvent Composition and Polarity on Separations in Reversed Phase Thin Layer and High Performance Liquid Chromatography

Abstract

The effect of the solvent's composition and polarity on separation in reversed phase thin layer and high performance liquid chromatography is discussed. These results show that retention times cannot be predicted merely from the polarity of the binary mobile phase. Although organic modifiers with the same physico-chemical properties and from the same solvent group were used, the retention times obtained using binary mobile phases having the same polarity, were different. It was also observed that normal chain carbon alcohols gave retention times different from those with a branched chain (n-propanol vs. iso-propanol), and the longer the alcohol chain the higher the R_f value. The results also show that not only the organic modifier used is important but the solute mixture used.     

The Use Of Soft Acid Metal Salts Of Carboxylic Acids For Retention Of Hydrophilic Peptides In Reversed-Phase High Performance Liquid Chromatography

Abstract

The effect of various soft acid cation acetate salts on the retention of the peptides Phe-(Gly)_n, where n=1–4, and on phenylalanine, indicates a correlation between the softness character of the cation of the acetate salt used in the mobile phase and retention in reversed-phase high performance liquid chromatography. Inorganic soft acid cation salts did not exhibit the same increased retention properties. By using silver(I) valerate or silver(I) octanoate as ion-pairing reagents in the mobile phase for RP-HPLC, static retention of peptides was achieved.     

The Utility of Cyclodextrin in Mobile Phase for High-Performance Liquid Chromatographic Separation of Isomeric Estrogens

Abstract

Cyclodextrin was used as a component of mobile phase for the separation of isomeric estrogens by reversed-phase high-performance liquid chromatography. The positional isomers of catechol and guaiacol estrogens were distinctly resolved by the addition of β-cyclodextrin in the mobile phase. The separation of estriol 16- and 17-glucuronides requires usually a prolonged time. The use of β-cyclodextrin in the mobile phase, however, reduced the retention time considerably.

The effect of β-cyclodextrin concentration in the mobile phase on the detector response was also investigated. The response of a fluorescence detector was raised with an increasing concentration of β-cyclodextrin, while that of an electrochemical detector was significantly depressed.     

Separation of Cyclodextrins Using Cyclodextrin Bonded Phases

Abstract

Two different cyclodextrin bonded phases (α and β) were used for the separation of α-, β-and γ-cyclodextrins. The β-cyclodextrin phase was found to be, in general, more effective at resolving the cyclodextrins than the α-cyclodextrin bonded phase. Acetonitrile/water mixtures were used as mobile phases. The effect of mobile phase composition on retention and resolution is examined. The elution order was found to be size dependent. The results are discussed in terms of the overall retention mechanism.     

Linear Solvation Energy Relationships in the Determination of Specificity and Selectivity of Stationary Phases

The retention of fifty structurally different compounds has been studied using linear solvation energy relationships. Investigations were performed with the use of six various stationary phases with two mobile phases (50/50?% v/v methanol/water and 50/50?% v/v acetonitrile/water). Packing materials were home-made and functionalized with octadecyl, alkylamide, cholesterol, alkyl-phosphate and phenyl molecules. This is the first attempt to compare all of these stationary phases synthesized on the same silica gel batch. Therefore, all of them may be compared in more complex and believable way, than it was performed earlier in former investigations. The phase properties (based on Abraham model) were used to the classification of stationary phases according to their interaction properties. The hydrophilic system properties s, a, b indicate stronger interactions between solute and mobile phase for most of the columns. Both e and v cause greater retention as a consequence of preferable interactions with stationary phase by electron pairs and cavity formation as well as hydrophobic bonds. However, alkyl-phosphate phase has different retention properties, as it was expressed by positive sign of s coefficient. It may be concluded that most important parameters influencing the retention of compounds are volume and hydrogen bond acceptor basicity. The LSER coefficients showed also the dependency on the type of organic modifier used as a mobile phase component.     

Correlation of HPLC Retention Data of Triazines with the Inhibition of DHFR from L1210 Cells: Development of New Chromatographic Adsorption Parameter in QSAR

Abstract

The use of chromatographic retention measurements for quantitative structure—activity relationships (QSAR) was investigated by the development of an adjusted logarithmic retention factor. Retention data of 15 triazine derivatives, which inhibit dihydrofolate reductase were measured by HPLC on octyl-silica and silica gel columns. From these data two parameters were calculated. First, the intercept of the plot of the logarithmic retention factor versus acetonitrile concentration was calculated from the reversed-phase retention measurements (log k'o) and, second, the difference between the logarithmic retention factor at high ammonium salt concentration and low ammonium salt concentration in the mobile phase was calculated from retention measurements on the silica gel column. The first parameter represents hydrophobic properties and the second parameter characterizes adsorption properties of the triazine derivatives. The results show a correlation between the two above mentioned parameters and the inhibition of L1210/71 cell growth.     

Sample Solvent as Analyte in High Performance Liquid Chromatography

Abstract

Solvents vary in their behavior in high performance liquid chromatography (HPLC). Water and methanol, among others, are widely used in the mobile phase as well as solvents for the solute. Few reports indicate that the solvent used for the solute can behave as an analyte. Normally, it is generally accepted that the solute solvent, a non-constituent of the mobile phase will be the first eluent. However, a solvent which is a component of the sample can show up as an unexpected peak with its own identity. This solvent may show a similar retention time as some of the unknown components of the sample. This indicates that in some cases the quantitative results may be the sum of the absorptivity of the solute and solvent used for the sample. It is assumed that some solvents show no absorption in the ultraviolet region at which the analysis is being conducted. Depending on the mobile phase composition some solvents can be detected at the wavelengts or wavelengths used for analysis. Water, ethylacetate, and methanol showed absorption at 210 nm when present in the sample being analyzed with a mobile phase of acetonitrile-methanol using a C₁₈ column. These solvents overlapped or showed retention times the same as estriol and testosterone.     

Enantioseparation of Some New 1-(2-Naphthyl)-1-ethanol Ester Derivatives by HPLC on Chiralcel OD

The direct enantiomeric resolution of racemic 2-(1H-imidazole-1-yl)-1-naphthalene-2-yl)ethanol esters, 1-(naphthalene-2-yl)ethanol esters, and 1-(1-hydroxynaphthalene-2-yl)-2-(1H-imidazole-1-yl)ethanol on silica-based cellulose tris(3,5-dimethylphenylcarbamate) (Chiralcel OD) column is described. The separations were performed using mobile phases which consist of alcohol (methanol, ethanol or 2-propanol)/n-hexane in various proportions. The effect of structural features of the solutes along with the nature and concentration of alcohol in the mobile phase on the discrimination between the enantiomers was examined for different mobile phase compositions. The results suggest that not only the structure and concentration of alcohol in the mobile phase, but also the subtle structural differences in racemates can have a pronounced effect on enantiomeric separation and retention. Baseline separations were obtained for 2-(1H-imidazole-1-yl)-1-naphthalene-2-yl)ethanol esters carrying imidazole ring in addition to ester functional group in their structures. The α values of the resolved enantiomers of 2-(1H-imidazole-1-yl)-1-naphthalene-2-yl)ethanol esters were in the range of 1.49–1.62 while the R _s values varied from 4.20 to 6.75 when methanol/n-hexane (70:30 v/v) was used as mobile phase.

     

Large Volume Injection of Biological Samples Dissolved in a Non-Eluting Solvent: A Way to Increase Sensitivity and a Means of Automating Drug Determination Using Hplc

Abstract

The injected volume of a sample dissolved in the mobile phase of an HPLC system must be maintained as small as possible so as to minimize the loss in efficiency. Generally this requirement limits the sensitivity of HPLC methods devoted to trace quantity determinations of drugs in biological fluids. In order to avoid this limitation and to increase the effective sensitivity of HPLC methods for determination of drugs such as antrafenine, nifuroxazide and cipropride, the samples were dissolved in a non-eluting solvent and a large volume (> 100 μl) was injected on to the chromatographic column.

The above-mentioned compounds and their internal standards were dissolved in a series of eluting and non-eluting solvents and increasing volumes (5 to 1000 μl) were injected. Peaks corresponding to injections made in an eluting solvent showed retention times independent of the injection volume but their variances increased with the volume injected. In contrast, peaks corresponding to injections made in a non-eluting solvent, similar to the mobile phase, had a variance independent of the injection volume but their retention times increased linearly with the injection volume. The repeated injection of such non-eluting solvents had no influence on chromatographic behaviour. Peaks corresponding to compounds injected in a non-eluting solvent made with components different from those of the mobile phase had a variance independent of the injection volume but their retention times varied both with the injection volume and with the interval between injection.

The application of non-eluting solvents has been defined theoretically and it has been demonstrated that solutions composed of 25% of the mobile phase diluted with the least eluting of its components act as non-eluting solvents and can be injected in large volume without loss in efficiency. This feature could be used to inject all the samples volume or only part of it, manually or automatically, since any automatic injector can be used with large volumes.

Thus, using the relatively simple procedure of making injections with a non-eluting solvent it is possible to increase both sensitivity and the rate of sample analysis.     

Reversed Phase High Performance Liquid Chromatography Using Carboxylic Acids in the Mobile Phase

Abstract

This report describes the use of different carboxylic acids as mobile phase modifiers. The effect on retention of acid chain length, pH, and eluent composition for a series of phenylalkanols, phenol, and the amines aniline, N-methylaniline, and benzylamine is discussed. The retention of both neutral and positively charged compounds is influenced by the dissociation equilibrium of the carboxylic acid in the mobile phase. By using l-pentanol to coat excess exposed silanol groups on the reversed phase column used, the inflection in the retention of both neutral and charged solutes as pH is changed occurs at the pK_a of the acid in the mobile phase. In addition, by using an acid and amine with the same or similar pK_a values, selective ion-pairing of this pair over others with dissimilar pK_a values can be promoted. Application of this technique to the selective retention of amino acids and peptides was unsuccessful.     

Reversed-Phase Systems for the Separation of Coumarins and Furocoumarins by Thin-Layer and High-Performance Liquid Chromatography

Abstract

The retention behaviour of eleven derivatives of counarin was investigated by reversed-phase (RP) thin-layer and high performance liquid chromatography. The linear relationships between log k'or R_M values and the content of organic modifier in the aqueous mobile phase obtained for wide composition ranges indicate that the plots can be used to determine R_Mw and log k_w values by extrapolation to pure water. The effects of individual substituants on the retention and the correlation between TLC and HPLC data was analysed.     

Ion Interaction Chromatographic Separation of Amino Acids Using a Basic-Tetraalkylammonium Salt Mobile Phase

Abstract

A basic mobile phase containing a tetraalkylammonium (R₄N⁺) salt was used to enhance the retention of free amino acids (AA) in their anion form on a polystyrene divinylbenzene copolymeric (Hamilton PRP-1) nonpolar stationary phase adsorbent. Major variables, which can be readily manipulated to alter this retention and resolve complex AA mixtures, are: structure and concentration of R₄N⁺ salt, type and amount of organic modifier in the mobile phase solvent, concentration and selectivity of the counteranion present, and mobile phase pH and ionic strength. Mobile phase gradients based on a pH change, or an ionic strength change and their combination, while all other variables are constant, were evaluated for the separation of complex AA mixtures. Detection was accomplished by absorbance or fluorescence after a post-column ortho-phthalaldehyde reaction.     

System Maps for XTerra MS C18: Effect of Solvent Type on Selectivity in Reversed-Phase Liquid Chromatography

The solvation parameter model is used to establish the contribution of cohesion, dipole-type and hydrogen-bonding interactions to the retention mechanism on an XTerra MS C₁₈ stationary phase with acetonitrile-water, methanol-water and tetrahydrofuran-water mobile phases containing from 10 to 70% (v/v) organic solvent. Solute size and electron lone pair interactions are responsible for retention while dipole-type and hydrogen-bonding interactions result in lower retention. The volume fraction of water in the mobile phase plays a dominant role in the retention mechanism. However, the change in values of the system constants of the solvation parameter model cannot be explained entirely by assuming the principle role of the organic solvent is to act as a diluent for the mobile phase. Selective solvation of the stationary phase by the organic solvent and the ability of the organic solvent to extract water into the stationary phase, and/or the absorption of water-organic solvent complexes by the stationary phase, are important in accounting for the details revealed about the retention mechanism by the solvation parameter model. A qualitative picture of the above solvent effects, compatible with current knowledge of solvent and stationary phase properties, is presented.     

Method for estimating the residual silanol activity of reversed-phase chromatographic adsorbents

The retention of some organic bases on reversed-phase adsorbents was studied as a function of the concentration of KH₂PO₄ in the mobile phase. It was shown that, for some adsorbents, retention decreases with an increase in the salt concentration, while an opposite dependence was observed for the other adsorbents. Such behavior of adsorbates can be explained by the prevailing silanophilic interactions in the former case and hydrophobic interactions in the latter case. The observed dependence can be used to change the chromatographic selectivity in the analysis of complex mixtures containing organic bases and to assess the properties of reversed-phase columns. Diphenhydramine hydrochloride was proposed as a test substance to assess the properties of the columns in the analysis of multicomponent pharmaceutical preparations. It was used in the comparative study of the properties of some adsorbents.     

Combined effects of mobile phase composition and temperature on the retention of homologous and polar test compounds on polydentate C8 column

Combined effects of temperature and mobile phase on the reversed phase chromatographic behavior of alkylbenzenes and simple substituted benzenes were investigated on a Blaze C₈ polydentate silica-based column, showing improved resistance against hydrolytic breakdown at temperatures higher than 60 °C, in comparison to silica-based stationary phases with single attachment sites. For better insight into the retention mechanism on polydentate columns, we determined the enthalpy and entropy of the transfer of the test compounds from the mobile to the stationary phase. The enthalpic contribution dominated the retention at 80% or lower concentrations of methanol in the mobile phase. Entropic effects are more significant in 90% methanol and in acetonitrile–water mobile phases. Anomalies in the effects of mobile phase on the enthalpy of retention of benzene, methylbenzene and polar benzene derivatives were observed, in comparison to regular change in enthalpy and entropy of adsorption with changing concentration of organic solvent and the alkyl length for higher alkylbenzenes. The temperature and the mobile phase effects on the retention are practically independent of each other and – to first approximation – can be described by a simple model equation, which can be used for optimization of separation conditions.