Comparison of conventional microparticulate and a monolithic reversed-phase column for high-efficiency fast liquid chromatography of basic compounds

The effect of mobile phase flow on column efficiency for a neutral compound together with weak and strong bases was compared for conventional microparticulate (3/3.5 microm and 5 microm) silica RP columns and a monolithic silica RP. For benzene, the minimum plate height (Hmin) at optimum flow-rate (mu(opt)) for weak bases was similar for the 5 microm and the monolith phases. However, the monolith generated much flatter Van Deemter curves, such that at high flow-rate (5 ml min(-1)) the plate height was nearly 3.5 times lower on the monolith. For weak bases analysed in unbuffered mobile phases, and stronger bases with acid phosphate buffer, increased tailing was obtained on the monolith compared with the conventional phases. Nevertheless, Van Deemter plots on the monolith still showed some advantages over particulate phases, even when asymmetry factor was included in the calculation of the plate height. However, at pH 7 considerable tailing of strong bases was found using the monolith; it is not clear whether this results from unique features of the monolith structure, or whether it is due merely to usual problems of silica activity. Van Deemter plots for conventional phases may be improved considerably by operating the column at elevated temperatures. At pH 3, these improvements are influenced to a considerable extent by increases in Dm, as shown by measurements of Dm using the Taylor-Aris procedure. However, at pH 7.0, improvements are much too substantial to be explainable wholly on this basis.     

Rationalisation of unusual changes in efficiency and retention with temperature shown for bases in reversed-phase high-performance liquid chromatography at intermediate pH

Despite the possibility of poorer peak shapes, analysis of pharmaceuticals and other bases using reversed-phase high-performance liquid chromatography (RP-HPLC) at intermediate pH gives useful increases in retention, selectivity and column loading capacity compared with low pH. Retention times of some bases showed anomalous increases with column temperature. Peak shapes for bases improved significantly at elevated temperature (up to 70 degrees C), with the weakest bases studied (pKa approximately 8) giving greater improvement than the strongest bases (pKa approximately 10). In contrast, quaternary ammonium compounds showed reduced retention with increasing column temperature (normal behaviour) and only modest improvements in peak shape. Considering these results, and pKa measurements of the bases made using capillary electrophoresis, it appears that increases in retention and improvement in efficiency may be influenced significantly by reduction in the pKa of bases with temperature, leading to reduction in protonation. It is less likely that efficiency improvements are due to the speeding up of the kinetics of silanol ion exchange, at least in the temperature range studied here.     

Effect of temperature and flow-rate on analysis of basic compounds in high-performance liquid chromatography using a reversed-phase column

The peak shape and retention of some basic probes together with a neutral reference compound were investigated as a function of temperature and flow-rate using a reversed-phase HPLC column at both pH 3.0 and pH 7.0. The retention of bases often showed an anomalous increase with temperature; retention mechanisms are complex as shown by studies of the effect of buffer cation concentration on retention. Considerable improvements in column efficiency for bases may result from operation at elevated temperature. Improvements did not seem attributable either to incidental changes in the retention factor, or (in this particular study where low sample masses were utilised) to the influence of sample load. The optimum flow-rate for highest efficiency is generally lower for basic compounds than neutrals, and due to the steepness of the Van Deemter curves obtained, high flow-rates appear to be particularly detrimental in the chromatography of basic compounds.     

Choosing an equivalent replacement column for a reversed-phase liquid chromatographic assay procedure

The column selectivity parameters (H, S*, A, B and C) described in the preceding paper [L.R. Snyder, A. Maule, A. Heebsch, R. Cuellar, S. Paulson, J. Carrano, L. Wrisley C.C. Chan, N. Pearson, J.W. Dolan, J.J. Gilroy, J. Chromatogr. A 1057 (2004) 49-57] can be used to compare columns in terms of selectivity. A detailed procedure for such column comparisons is presented here, and evaluated by its use in finding suitable replacement columns for 12 different routine separations performed in five different pharmaceutical analysis laboratories.     

Analysis of carboxylic acids by gas chromatography of acetonyl esters. Application to aromatic,dicarboxylic and higher fatty acids

Summary The gas chromatographic analysis of the acetonyl esters of aromatic, dicarboxylic and higher fatty acids is reported and discussed together with their electron impact and chemical ionisation mass spectra. An improved method for the preparation of acetonyl esters is discussed.     

Mn site substitution of La0.67Ca0.33MnO3 with closed shell ions: Effect on magnetic transition temperature

Mn site is substituted with closed shell ions (Al, Ga, Ti, Zr and a certain combination of Zr and Al) and also with Fe and Ru ions carrying the magnetic moment (S=5/2 and 2 respectively) at a fixed concentration of 5 at %. Substitution did not change either the crystal symmetry or the oxygen stoichiometry. All substituents were found to suppress both the metal-insulator and ferromagnetic transition temperatures (T _p(ρ) and T _C, respectively) to varied extents. Two main contributions identified for the suppression are the lattice disorder arising due to difference in the ionic radii between the substituent (r _M) and the Mn³⁺ ion (r _Mn ³⁺) and in the case of the substituents carrying a magnetic moment, the type of magnetic coupling between the substituent and that of the neighboring Mn ion.     

Estimation of the extent of the water-rich layer associated with the silica surface in hydrophilic interaction chromatography

The possible presence of a mobile phase layer rich in water on the surface of silica columns used under conditions typical in hydrophilic interaction chromatography was investigated by the injection of a small hydrophobic solute (benzene) using acetonitrile-water mobile phases of high organic content. Benzene does not partition into this layer and is thus partially excluded from the pores of the phase up to a water content of about 30%, after which hydrophobic retention of the solute on siloxane bonds is observed. In 100% acetonitrile, the retention volume of benzene was smaller than that estimated either by pycnometry or by calculation from the basic physical parameters of the column. This result might be attributable to the larger size of the benzene molecule: the elution volume of a molecule is the pore volume minus a surface layer half the diameter of the analyte molecule. However, some influence of strongly adsorbed water that remains on the surface of the phase even after extensive purging with dry acetonitrile cannot be entirely discounted. The results suggest that about 4-13% of the pore volume of a silica phase is occupied by a water-rich layer when using acetonitrile-water containing 95-70% (v/v) acetonitrile.     

Is hydrophilic interaction chromatography with silica columns a viable alternative to reversed-phase liquid chromatography for the analysis of ionisable compounds?

The separation of acidic, neutral and particularly basic solutes was investigated using a bare silica column, mostly under hydrophilic interaction chromatography (HILIC) conditions with water concentrations >2.5% and with >70% acetonitrile (ACN). Profound changes in selectivity could be obtained by judicious selection of the buffer and its pH. Acidic solutes had low retention or showed exclusion in ammonium formate buffers, but were strongly retained when using trifluoroacetic acid (TFA) buffers, possibly due to suppression of repulsion of the solute anions from ionised silanol groups at the low (s)(s)pH of TFA solutions of aqueous ACN. At high buffer pH, the ionisation of weak bases was suppressed, reducing ionic (and possibly hydrophilic retention) leading to further opportunities for manipulation of selectivity. Peak shapes of basic solutes were excellent in ammonium formate buffers, and overloading effects, which are a major problem for charged bases in RPLC, were relatively insignificant in analytical separations using this buffer. HILIC separations were ideal for fast analysis of ionised bases, due to the low viscosity of mobile phases with high ACN content, and the favourable Van Deemter curves which resulted from higher solute diffusivities.     

High Sensitivity Negative Ion GC-MS Method for Detection of Estrogens in Urine

A sensitive negative chemical ionization (NCI) gas-chromatography/mass spectrometry (GC/MS) method for the detection of estrogens is described. After hydrosis and clean-up by C₁₈ ODS solid phase extraction (SPE) cartridge, the extracts obtained were derivatized with heptafluorobutyric anhydride and analyzed in the negative ion mode by GC/MS. Stability of derivatives was good. Selected ion monitoring (SIM) mode was applied to increase the sensitivity and, when possible, the higher m/z ions were selected to improve identification. The detection limit of the HFB esters in NCI using SIM was below 10 femtograms.