Synthesis of acceptor bonded phases for donor-acceptor liquid chromatography

Summary The synthesis of several electron-acceptor stationary phases has been reviewed the materials evaluated for their capacity to separate polyaromatic hydrocarbons (PAHs). Chemically bonded phases were obtained by the same procedure; the organosilane moiety is monofunctional and the HPLC behaviour is compared under identical conditions. Examples of PAHs separations are given.Presentedat the 13th International Symposium on Polynuclear Aromatic Hydrocarbons, Bordeaux, October 1–4, 1991.     

Cholesteric bonded stationary phases for high-performance liquid chromatography: a comparative study of the chromatographic behavior

The properties of four cholesteric bonded stationary phases differing in the nature of the spacer and the end-capping were assessed using simple chromatographic tests based on the retention of nonpolar compounds and of planar or nonplanar probe solutes. All cholesteric columns showed a hydrophobicity close to that of conventional octadecyldimethylsilyl (ODS) materials. Non-end-capped cholesteric bonded phases showed greater selectivity than ODS ones and both end-capped cholesteric bonded phases exhibit behavior intermediate between that of the non-end-capped original material and that of the ODS bonded phase.     

Selectivity studies on branched and linear alkyl bonded stationary phases in reversed-phase liquid chromatography

Summary Reversed-phase liquid chromatographic retention characteristics for the sixteen acyclic C₁−C₅ N-alkylbenzamide congeners were measured on various branched and linear, alkyl bonded hydrocarbon stationary phases. Retention factors, k′, were determined in acetonitrile-water mobile phase compositions on ethyl, n-octyl, n-dodecyl, n-octadecyl, 1-ethyladamantyl, 4-butyloctyl, and 2,4,4-trimethylpentyl stationary phases. Statistical analysis of the two main effects investigated — type of stationary phase and percentage of organic modifier (acetonitrile) in the mobile phase — described greater than ninety percent of the variability in the data for most of the comparisons. Selectivity effects due to variation in the mobile phase dominated the results.     

The allyl bonded stationary phase. II. Conversions to new phases for gas chromatography

Summary The presence of the double bond on the allyl moiety has been utilized as a site for addition reactions which could produce new stationary phases. Bromination and hydrobromination reactions have been employed to prove the feasibility of making modifications to the allyl bonded phase. Both retention volumes and thermodynamic parameters for the solutes studied change upon conversion to one of the brominated phases. Sample size studies are consistent with a bonded phase adsorption mechanism. FTIR spectra also confirm the modifications which have occurred on the allyl bonded material.     

Multidentate phenyl-bonded phases in high-performance liquid chromatography

Summary New multidentate phenyl-bonded phases (MPBPs) were synthesized and evaluated the chromatographic retention behaviour with polycyclic aromatic hydrocarbons as sample probes in high-performance liquid chromatography. The new MPBPs show different retention characteristics from the previously synthesized MPBP, designated TP. Nevertheless, the results indicate that the retention mechanism is still the same as the TP phase: the size and shape of the solute molecule can be recognized by a cavity-like space formed by the methyl groups and phenyl rings of MPBPs.Dedicated to Professor Leslie S. Ettre on the occasion of his 70th birthday.     

Chemically bonded multifunctional stationary phases for high-performance liquid chromatography

Summary A new class of stationary phases for high-performance liquid chromatography (HPLC) are described which simulate in their retention chracteristics ion-pair separations. The phases consist of mixtures of chemically dissimilar ligands chemically bonded to silica supports. These phases are largely reversed-phase in nature, but also contain significant ion-exchange properties, at levels similar to those demonstrated to occur in ionpairing. By bonding both ionic and hydrophobic groups in the correct proportions, mixed retention mechanisms are created, resulting in unique selectivities, while retaining the excellent stabilities and efficiencies characteristic of bonded phases. The ratio of hydrophobic to ionic character can be controlled during the synthesis, and is used as a tool to vary the stationary phase, rather than only the mobile phase, to effect the separation desired. The synthesis and behavior of both anionic and cationic/reversed-phase materials are described, and are applied to the simultaneous separation of nucleosides and nucleotides, and to the separation of the catecholamines.Presented at the 14th International Symposium on Chromatography London, September, 1982.     

Synthesis of an N-butylpyrrolidine phase using the allyl bonded stationary phase as an intermediate

Summary The versatility of the allyl phase is exploited by using it as an intermediate in the production of a weak anion exchange material that would be difficult to synthesize directly using organochlorosilane reagents. The stability of the allyl phase under the severe reaction conditions (170° and 140 atm of CO) of aminomethylation also is demonstrated. The product N-butylpyrrolidine phase is characterized spectroscopically by ESCA and DRIFT which also indicate a high conversion (greater than 90 %) of the allyl phase. In addition, the carbon-nitrogen ratio of the product phase supports a high yield. Chromatographic characterization is done by the retention indices of the alkylarylketone homologous series and by capacity factor (k′) determinations for inorganic anions and amino acids.     

High-performance liquid chromatographic investigation of the enantioselectivity and mechanism of chiral recognition of new cholic acid-based stationary phases

Summary To elucidate the mechanism of chiral recognition of cholic acid-based stationary phases, four new cholic acid derivatives, with differently substituted carbamate or three acetoxy groups, were bonded to a hydrosilyl-modified silica gel. Their capacity to discriminate between enantiomers was evaluated in normal-phase high-performance liquid chromatography. The results were compared with those from equivalent separations on trihydroxy- and 3α-phenylcarbamate-substituted cholic acid-based bonded phases. The influence of mobile phase composition of the separation of the enantiomers of amino alcohols was shown. Different mechanisms of chiral discrimination are discussed, highlighting the influence of the nature of the carbamate on enantioselectivity.     

High-performance liquid chromatography of nucleic acid constituents: Chromatographic examination of novel stationary phases

Summary Silica-bonded stationary phases were developed for the separation of nucleic acid constituents and their properties investigated with homologous oligoriboadenylic acids in electrostatic interaction chromatography and with alkylbenzenes in reversed-phase chromatography. Analysis of retention data confirmed the stratified molecular structure of the surface which consist of a layer of propyl chains anchoredvia siloxane bridges to the silica surface proper and of polar moieties attached to the hydrocarbonaceous functions. The polar top layer contains weak cationic and/or hydrophobic binding sites, is strongly hydrated in contact with aqueous eluents and bars the access by large biopolymers to the hydrocarbonaceous sublayer. In reversed-phase chromatography of small non polar molecules with hydro-organic eluents, however, this layer is accessible and engenders a retentive behavior typical for weak hydro-carbonaceous bonded phases. As a result the stationary phases, depending on the nature of the sample and the mobile phase, exhibit the properties of "soft" phases for the chromatography of biopolymers under mild elution conditions and those of "hard" phases for the separation of small non-polar molecules under conditions generally employed in reversed-phase chromatography. The retention of nucleic acid constituents on most of the stationary phases investigated subject to a dual mechanism as a result of the interplay of electrostatic and hydrophobic interactions between the eluites and the binding sites on the stationary phase surface. Siliceous stationary phases having surface morphology described above are suitable for the separation of nucleic acid constituents having widely ranging molecular weights up to 3 × 10⁶ Daltons provided the support has appropriate pore dimensions. This is demonstrated by the separation of mixtures arising from digesting t-RNA^pha or polyadenylic acids as well as those of ribosomal RNA’s and different forms of the plasmid pBR322 DNA. Presented at the 15th International Symposium on Chromatography, Nürnberg, October 1984     

Silanol group effect of alkylnitrile (cyano) bonded phase in high-performance liquid chromatography

Summary When a cyano bonded phase is used together with a nonaqueous eluent, it is universal that the silanol groups which remain at the surface of the silica gel after bonding affect the retention of solutes. With solutes containing such atoms as N, S and O, hydrogen bond may form between the solute and the residual silanol group, leading to dual retention mechanism. Based on the understanding of retention mechanism, methods were developed to separate metal-diethyldithiocarbamate (DDTC) chelates and crown ethers on cyano bonded phase, the mobile phase being a nonaqueous solvent containing triethylamine (TEA). The work was supported by the National Science Foundation of China.     

A comparison of temperature and mobile phase composition effects for bonded liquid crystal and polymeric stationary phases in HPLC

Summary Using two polycyclyic aromatic hydrocarbons as solutes, a comparison is made between a bonded liquid crystal stationary phase and a conventional polymeric C-18 phase. The bonded nematic liquid crystal phase was the silanized form of 4-[4-(allyloxy)benzoyl-oxy]biphenyl and the polymeric phase was Vydac 201TP. Both phases display shape and planarity selectivity as indicated by the results of the variable temperature and mobile phase composition studies. The slot theory of retention can be used to explain these results. However, the liquid crystal phase is more sensitive to molecular geometry, probably due to its more ordered structure on the surface. Variable temperature experiments which compare retention during both heating and cooling provides additional support for this conclusion. With the polymeric bonded C-18 phase, each solute had identical retention at the same temperature during both the heating and cooling cycles. On the bonded liquid crystal phase, measurable differences in retention were observed at identical temperatures depending on whether the column was heated or cooled. This effect is attributed to a degree of partially reversible disordering which occurs as the column temperature was increased. However, conditioning with the appropriate mobile phase can restore the original retention characteristics of the bonded liquid crystal phase.     

Synthesis of a propyldimethylphenylsilane stationary phase using the allyl bonded phase as an intermediate

Summary A propyldimethylphenylsilane stationary phase was prepared by a hydrosilylation reaction on the double bond of an allyl bonded phase intermediate. The carbon load on the silica was between 8.8–9.0%. Evaluation of the material by FTIR indicated high conversion of the double bond by the hydrosilylation reaction. The bonded material displayed reversedphase properties as determined by the retention behavior of alkylarylketones but it was less hydrophobic than either C-8 or C-18. The stability at both low and high pH was excellent. Separations of pharmaceutical compounds, a mixture of anilines, and a mixture of dopamine and epinephrine were satisfactory.     

Polysiloxane-encapsulated stationary phase for reversed-phase high-performance liquid chromatography

Summary Silica beads of 6-μm average diameter were silanized with methylvinyldiethoxysilane and then subjected to encapsulation with poly(methylvinylsiloxane). The resulting product is a new stationary phase for reversed-phase high performance liquid chromatography (RP-HPLC) which has superior ability for the separation of polar, non-polar and basic compounds. The chromatographic peaks are symmetric. Its stability has been studied; after continuous use for three months the carbon content and chromatographic behaviour of the phase were unchanged. on to the silica surface to given an uniform organic film. Material prepared in this way has both good chromatographic behaviour and superior selectivity. Because contact of the silica matrix with the mobile phase is avoided, the alkali-resisting ability of the stationary phase is increased. The non-specific adsorption of alkaline solutes on to the silica surface is also avoided because of the complete coverage of surface silanol groups. Reports of stationary phases encapsulated with polystyrene [6], polybutadiene [I] and octadecylsiloxane polymers have recently appeared in the literature [3]. In this paper we report the encapsulation of poly-(methylvinylsiloxane) (analogous to the phase SE-31 often used in GC) on to a silica matrix previously modified with methylvinyldiethoxysilane. The resulting phase has superior performance in reversed-phase HPLC.     

Synthesis and characterization of a new type of chemically bonded liquid crystal stationary phase for HPLC

Summary Two commercially available liquid crystals, 4-cyano-4′-n-pentyl-1,1′-bipheny and 4-cyano-4′-n-pentoxy-1,1′-bipheny, are bonded to a silica hydride surface via hydrosilation in the presence of a free radical iniator, t-butyl peroxide. Elemental analysis, diffuse reflectance Fourier trans-form infrared spectroscopy, and¹³C and²⁹Si CP-MAS NMR spectroscopy are used to confirm the success of the bonding reaction. The¹³C CP-MAS spectra suggest a difference in the bonded phase morphology of the two materials. Static hydrolytic stability tests indicate these materials do not degrade significantly in both acidic and basic solutions. Chromatographic tests confirm that these two bonded phase behave differently with respect to their retention of PAHs, alkyl-substituted benzenes and benzodiazepines.     

Study on retention behavior of peropyrene-type polycyclic aromatic hydroccrbons with various bonded stationary phases in reversed-phase liquid chromatography

Summary The retention behavior of 15 peropyrene-type polycyclic aromatic hydrocarbons was investigated on various bonded stationary phases in reversed-phase liquid chromatography. On diphenyl and naphthylethyl bonded phases, high correlations were obtained between the molecular polarizability of solutes and their retention. However, very low or no correlations were found on various octadecyl bonded phases. These facts are discussed by using the electrostatic interaction concept between the solutes and the stationary phase. We conclude that these observations are due to two reasons: the difference in the degree of planarity of polycyclic aromatic hydrocarbons and the high ability of planarity recognition of octadecyl bonded phases.     

Analysis of high-performance liquid chromatography bonded stationary phases using thermogravimetry

A thermogravimetric method was developed for determining the C-18 bonded phase content of reversed phase high performance liquid Chromatographic stationary phases. The method yielded data that were comparable to the sum of carbon and hydrogen content. Excellent agreement between the two methods was achieved by heating the stationary phase samples to 150°C in order to remove adsorbed species prior to elemental analysis.This research stemmed from the author's Master's degree research undertaken at California State Polytechnic University Pomona, and conducted at the Getty Conservation Institute (GCI).The author is greatly indebted to the following colleagues at the GCI for their advice during the course of this project: Neville Agnew, Charles Selwitz, Dusan Stulik and David Scott. The HPLC bonded stationary phase samples were prepared by John Streng, California State Polytechnic University, Pomona.     

Effect of temperature on the mechanism of retention of fullerenes in liquid chromatography using various alkyl bonded stationary phases

Summary The temperature-dependency of the separation of fullerenes in liquid chromatography (LC) has been examined using various alkyl bonded stationary phases. It has been found that a maximum retention temperature exists with long alkyl bonded stationary phases, whereas there is no similar effect with the newly synthesized alkyl bonded phases which have two phenyl groups at the base of the bonded phase. The interpretation of the retention behavior of fullerenes in the low temperature region on alkyl bonded stationary phases is discussed using information obtained by CP-MAS solid-state NMR spectroscopy and LC.     

Separation of carotenoids by high-performance liquid chromatography with polymeric and monomeric octadecylsilica stationary phases

Summary In addition to their value in the nutritional context, the carotenoids have other important functions, including some epidemiological significance in disease prevention. With increasing interest in the carotenoids methods for their characterization and quantification in various matrices are essential particularly with regard to epidemiologic studies dealing with diet and health. Since high-performance liquid chromatography (LC) is the most promising analytical method for this purpose, having high reliability, high selectivity and quantification ability, this work presents the evaluation of reversed-phase LC methods using polymeric and monomeric octadecylsilica (ODS) stationary phases for the highly selective separation of carotenoids. It has been found that the polymeric ODS has a better selectivity for carotenoids, taking account of their molecular shape and size recognition, than the monomeric ODS phase and that the former is more suitable than the latter for separations of the carotenoids.     

Factor analysis and experiment design in high-performance liquid chromatography. IX. Silica vs. chemically bonded phases in normal phase-HPLC

Summary The retention of a group of 38 E-s-cis and Z-s-cis chalcones on silica vs. nine polar chemically bonded phases is discussed. It was established that the relatively greatest similarity to silica is observed with the NH₂, DIOL and CN phases, whereas the chargetransfer type phases and the NO₂ one offer a different separation selectivity.     

The effect of hydrocarbon chain length and end-capping on the liquid chromatographic properties of stationary phases containing bonded nitrile groups

Summary Stationary phases containing bonded nitrile groups have been synthesized. The effect of the n-alkyl chain length connecting the nitrile groups to the surface and of the end-capping on the chromatographic properties was studied. The synthesized material was compared with commercial nitrile phases in the separation of isomeric cresols and xylenols.