Contributions to reversed-phase column selectivity. II. Cation exchange.

The contribution of cation exchange to solute retention for type-B alkylsilica columns (made from high-purity silica) has been examined in terms of the hydrophobic-subtraction (H-S) model of reversed-phase column selectivity. The relative importance of cation exchange in the separation of ionized bases by reversed-phase chromatography (RPC) varies with (a) column acidity (values of the column cation-exchange capacity C), (b) mobile-phase pH and buffer concentration, and (c) the nature of the buffer cation. The effects of each of these separation variables on cation retention were examined. The contribution of cation exchange (and other ionic interactions) to solute retention is represented in the H-S model by properties of the solute (κ') and column (C), respectively. Values of κ' for 87 solutes have been examined as a function of solute molecular structure, and values of C for 167 type-B alkylsilica columns have been related to various column properties: ligand length (e.g., C(8) vs. C(18)) and concentration (µmol/m(2)), pore diameter (nm), and end-capping. These results contribute to a more detailed picture of the retention of cationic solutes in RPC as a function of separation conditions. While previous work suggests that the ionization of type-B alkylsilica columns is generally negligible with mobile-phase pH<7 (as a result of which cation exchange then becomes insignificant), the present study provides evidence for cation exchange (and presumably silanol ionization) at a pH as low as 3 for most columns.

Anion-exchange behavior of several alkylsilica reversed-phase columns.

Some alkylsilica columns carry a positive charge at low pH, as determined by anion-exchange with nitrate ion. In the present study, the relative positive charge for 14 alkylsilica columns was measured for a mobile-phase pH 3.0. All but 3 of these columns were found to carry a significant positive charge under these conditions. The relative positive charge on these columns was found to correlate approximately with two other column characteristics: relative cation-exchange behavior as measured by the hydrophobic-subtraction model (values of C-2.8), and slow equilibration of the column to changes in the mobile-phase-as evidenced by a slow change in the retention of anionic and cationic solutes with time. The origin of this positive charge may arise from the bonding process, with incorporation of some cationic entity into the stationary phase.

Characterization and applications of reversed-phase column selectivity based on the hydrophobic-subtraction model.

A total of 371 reversed-phase columns have now been characterized in terms of selectivity, based on five solute-column interactions (the hydrophobic-subtraction model). The present study illustrates the use of these data for interpreting peak-tailing and column stability. New insights are also provided concerning column selectivity as a function of ligand and silica type, and the selection of columns for orthogonal separations is re-examined. Some suggestions for the quality control of reversed-phase columns during manufacture are offered.

Relevance of pi-pi and dipole-dipole interactions for retention on cyano and phenyl columns in reversed-phase liquid chromatography.

Previous work suggests that pi-pi interactions between certain solutes and both phenyl and cyano columns can contribute to sample retention and the selectivity of these two column types versus alkylsilica columns. Recent studies also suggest that dipole-dipole interactions are generally unimportant for retention on cyano columns. The present study presents data for 44 solutes, three columns and two different mobile phases that were selected to further test these conclusions. We find that pi-pi interactions can contribute to retention on both cyano and phenyl columns, while dipole-dipole interactions are likely to be significant for the retention of polar aliphatic solutes on cyano columns. When acetonitrile/water mobile phases are used, both pi-pi and dipole-dipole interactions are suppressed, compared to the use of methanol/water.

Column selectivity in reversed-phase liquid chromatography. VII. Cyanopropyl columns.

Eleven cyanopropyl ("cyano") columns were characterized by means of a relationship developed originally for alkyl-silica columns. Compared to type-B alkyl-silica columns (i.e., made from pure silica), cyano columns are much less hydrophobic (smaller H), less sterically restricted (smaller S*), and have lower hydrogen-bond acidity (smaller A). Because sample retention is generally much weaker on cyano versus other columns (e.g., C8, C18), a change to a cyano column usually requires a significantly weaker mobile phase in order to maintain comparable values of k for both columns. For this reason, practical comparisons of selectivity between cyano and other columns (i.e., involving different mobile phases for each column) must take into account possible changes in separation due to the change in mobile phase, as well as change in the column.

Column selectivity in reversed-phase liquid chromatography. VIII. Phenylalkyl and fluoro-substituted columns.

As reported previously, five solute-column interactions (hydrophobicity, steric resistance, hydrogen-bond acidity and basicity, ionic interaction) quantitatively describe column selectivity for 163 alkyl-silica, polar-group and cyano columns. In the present study, solute retention and column selectivity for 11 phenyl and 5 fluoro-substituted columns were compared with alkyl-silica columns of similar ligand length. It is concluded that two additional solute-column interactions may be significant in affecting retention and selectivity for the latter columns: (a) dispersion interactions of varying strength as a result of significant differences in bonded-phase polarizability or refractive index and (b) pi-pi interactions in the case of phenyl columns and aromatic solutes. These 16 phenyl and fluoro columns were also characterized in terms of hydrophobicity, steric resistance, hydrogen-bond acidity and basicity, and ionic interaction.

Slow equilibration of reversed-phase columns for the separation of ionized solutes.

Reversed-phase columns that have been stored in buffer-free solvents can exhibit pronounced retention-time drift when buffered, low-pH mobile phases are used with ionized solutes. Whereas non-ionized compounds exhibit constant retention times within 20 min of the beginning of mobile phase flow, the retention of ionized compounds can continue to change (by 20% or more) for several hours. If mobile phase pH is changed from low to high and back again, an even longer time may be required before the column reaches equilibration at low pH. The speed of column equilibration for ionized solutes can vary significantly among different reversed-phase columns and is not affected by flow rate.

Chromatography in analytical biotechnology.

Recent advances in biochromatography have focused on improvements in the design of stationary supports for liquid chromatography. During the past year, the innovative use of columns packed with small non-porous particles has significantly improved the efficiency of chromatographic separations. Bioseparations that previously took hours are now possible in only a few minutes.

Involvement of glutathione in 1-naphthylisothiocyanate (ANIT) metabolism and toxicity to isolated hepatocytes.

1-Naphthylisothiocyanate (ANIT) is a model compound which causes cholestasis in laboratory animals. Various biochemical and morphological changes including biliary epithelial and parenchymal cell necrosis occur in the liver of animals treated with ANIT. Although the mechanism(s) for these effects is not understood, a role for glutathione (GSH) in toxicity has been implicated. The possible role of GSH in hepatocellular toxicity caused by ANIT was investigated in this study. Treatment of freshly isolated rat hepatocytes with ANIT caused a concentration- and time-dependent depletion of cellular GSH that preceded lactate dehydrogenase (LDH) leakage. Analysis of the incubation medium indicated that the majority of the cellular GSH which was lost was present extracellularly as GSH or as a GSH-releasing compound. Mixing ANIT with GSH at pH 7.5 yielded a compound that was characterized by HPLC and fast atom bombardment-mass spectrometry (FAB-MS) S-(N-naphthyl-thiocarbamoyl)-L-glutathione (GS-ANIT). When dissolved in aqueous solutions at neutral pH, 95% of GS-ANIT dissociated to yield free ANIT and GSH. Under conditions designed to maximize formation and stability of GS-ANIT, GS-ANIT was found in the extracellular medium of hepatocytes treated with ANIT. Treatment of hepatocytes with the GS-ANIT caused GSH depletion and LDH leakage similar to that observed with equimolar amounts of ANIT. These data suggest that ANIT depletes hepatocytes of GSH through a reversible conjugation process. Such a process may play a role in the toxicity of ANIT.

Identification of the reactive glutathione conjugate S-(2-chloroethyl)glutathione in the bile of 1-bromo-2-chloroethane-treated rats by high-pressure liquid chromatography and precolumn derivatization with o-phthalaldehyde.

The conjugation of glutathione with 1,2-dihaloethanes leads to the formation of S-(2-haloethyl)glutathione which, following intramolecular cyclization, produces an electrophilic thiiranium ion. The extent to which the formation of the thiiranium ion is responsible for the toxicity associated with 1,2-dihaloethanes has been difficult to determine because of the inherent instability of the compound under physiological conditions. The goal of this study was to attempt to identify a putative precursor of the thiiranium ion, S-(2-chloroethyl)glutathione (CEG), in the bile of rats treated with 1,2-dihaloethanes such as 1-bromo-2-chloroethane (BCE). In order to detect the presence of CEG, a precolumn procedure for derivatizing the amine of CEG with o-phthalaldehyde/2-mercaptoethanol (OPA/MCE) was developed. Studies with a model compound, S-ethylglutathione, indicated that the derivatization reaction between S-ethylglutathione and OPA/MCE proceeded rapidly and under mild conditions. The resulting fluorescent adduct of S-ethylglutathione was detected at low concentrations following separation by reverse-phase HPLC. Derivatization of CEG with OPA/MCE followed by preparative HPLC and mass spectral analysis revealed that the major fluorescent adduct in the reaction mixture was the expected 1-[(2-hydroxyethyl)thio]-2-substituted-isoindole derivative of CEG. Also present in the derivatization reaction mixture were small quantities of S-(2-hydroxyethyl)glutathione, the product of CEG hydrolysis, and a product involving the addition of MCE to CEG. Analysis of the bile samples obtained from bile-cannulated rats treated with BCE showed the presence of a peak corresponding to CEG. Over a 3-h interval, 2% of the BCE administered was excreted into the bile as CEG.

Biliary excretion of a glutathione conjugate of busulfan and 1,4-diiodobutane in the rat.

gamma-Glutamyl-beta-(S-tetrahydrothiophenium)alanyl-glycine, the glutathione-sulfonium conjugate of busulfan and 1,4-diiodobutane, was identified in the bile of rats following intravenous administration of equimolar doses of either compound. The glutathione-sulfonium conjugate was synthesized from 1-bromo-4-chlorobutane and characterized by 1H and 13C NMR and FAB/MS. An HPLC method was developed to identify the conjugate from rat bile by pre-column fluorescent derivatization with o-phthalaldehyde. The biliary excretion of cyclic sulfonium conjugates was quantitated indirectly by measuring the release of tetrahydrothiophene (THT) after treatment of the bile with base. THT release was quantitative and was measured by gas chromatography. With busulfan, peak biliary concentrations of THT-releasing metabolite(s) were reached after 90 min and 26% of the dose of busulfan was recovered in the bile after 8 hr. When diiodobutane was administered, 21% of the dose was recovered, and the peak concentration was reached in 30 min. The decline in THT releasing metabolite(s) was more rapid with 1,4-diiodobutane, and THT was no longer measurable after 3.5 hr compared to 7.5 hr after busulfan administration. These data confirm that busulfan and other 1,4-disubstituted butanes are conjugated with glutathione in vivo.

Glutathione S-transferases catalyzed conjugation of 1,4-disubstituted butanes with glutathione in vitro.

Rat liver glutathione S-transferases catalyzed the conjugation of 1,4-diiodobutane with glutathione in vitro. The reaction followed saturation kinetics and was dependent on the concentration of the enzyme, substrate and glutathione in the incubation media. S-Benzylglutathione inhibited the enzymatic conversion of 1,4-diiodobutane to product. The cyclic sulfonium compound, gamma-glutamyl-beta-(S-tetrahydrothiophenium) alanyl-glycine was identified as the product of this conjugation reaction. This product was stable under physiological conditions in presence of rat liver cytosol but rapidly and quantitatively decomposed at pH greater than or equal to 12 to give tetrahydrothiophene.