Columns, reversed HPLC examples

Chiral separations have become of significant importance because the optical isomer of an active component can be considered an impurity. Optical isomers can have potentially different therapeutic or toxicological activities. The pharmaceutical Hterature is trying to address the issues pertaining to these compounds (155). Frequendy separations can be accompHshed by glc, hplc, or ce. For example, separation of R(+) and 5 (—) pindolol was accompHshed on a reversed-phase ceUulose-based chiral column with duorescence emission (156). The limits of detection were 1.2 ng/mL of R(+) and 4.3 ng/mL of 3 (—) pindolol in semm, and 21 and 76 ng/mL in urine, respectively. 

For more specific analysis, chromatographic methods have been developed. Using reverse-phase columns and uv detection, hplc methods have been appHed to the analysis of nicotinic acid and nicotinamide in biological fluids such as blood and urine and in foods such as coffee and meat. Derivatization techniques have also been employed to improve sensitivity (55). For example, the reaction of nicotinic amide with DCCI (AT-dicyclohexyl-0-methoxycoumarin-4-yl)methyl isourea to yield the fluorescent coumarin ester has been reported (56). After separation on a reversed-phase column, detection limits of 10 pmol for nicotinic acid have been reported (57). 

Purification of the activation products (PMs). The methylamine activation product dissolved in methanol is purified by chromatography, first on a column of silica gel using a mixed solvent of chloroform/ethanol, followed by reversed-phase HPLC on a column of divinylbenzene resin (such as Jordi Reversed-Phase and Hamilton PRP-1) using various solvent systems suitable for the target substance (for example, acetonitrile/water containing 0.15% acetic acid). 

Although some normal phase methods have been used, the majority of carotenoid separations reported in the literature were carried out by reversed phase HPLC. Among the Cjg columns employed for determination of complete carotenoid compositions in foods, the polymeric Vydac brand is preferably used for separation of cis isomers. Several examples of different C,g columns and mobile phases are cited in the literature, but not aU carotenoids are baseline separated in most systems. Table 6.2.1 shows some examples employing different brands of Cjg columns." Acetonitrile did not improve selectivity toward separation of carotene isomers in a Vydac 201TP column and resolution was strongly dependent on the Vydac column lot. ... 

Utilizing the difference in selectivity between a monolithic silica-C18 column (2nd-D) and another particle-packed column of C18 phase (lst-D), 2D HPLC separation was shown mainly for basic compounds and other species (Venkatramani and Zelechonok, 2003). The authors also reported other examples of reversed-phase 2D HPLC, using amino- and cyano-derivatized particle-packed columns for 2nd-D separation. The combination of normal-phase separation for the 1 st-D and reversed-phase separation on monolithic Ci g column for the 2nd-D was reported (Dugo et al., 2004). The use of a microbore column and weak mobile phase for the lst-D and a monolithic column for the 2nd-D was essential for successful operation. Improvement in the 2D separation of complex mixtures of Chinese medicines was also reported (Hu et al., 2005). Following are practical examples of comprehensive 2D HPLC using monolithic silica columns that have been reported. 

To separate homogeneous compounds from co-eluting metabolites, repeated HPLC experiments with changes in column and solvent systems were necessary. For example, kalihinol-A (107) sharing similar retention times with kalihinol-C (114), and kalihinol-F (112) with kalihinol-E (108), were resolved successfully on an ODS reverse phase column. Crystallization experiments were repeatedly undertaken. The sample of kalihinol-F (112) prepared for X-ray analysis had two C22H33N3O2 molecules in its asymmetric unit. 

Reverse-phase HPLC (RP-HPLC) separates proteins on the basis of differences in their surface hydophobicity. The stationary phase in the HPLC column normally consists of silica or a polymeric support to which hydrophobic arms (usually alkyl chains, such as butyl, octyl or octadecyl groups) have been attached. Reverse-phase systems have proven themselves to be a particularly powerful analytical technique, capable of separating very similar molecules displaying only minor differences in hydrophobicity. In some instances a single amino acid substitution or the removal of a single amino acid from the end of a polypeptide chain can be detected by RP-HPLC. In most instances, modifications such as deamidation will also cause peak shifts. Such systems, therefore, may be used to detect impurities, be they related or unrelated to the protein product. RP-HPLC finds extensive application in, for example, the analysis of insulin preparations. Modified forms, or insulin polymers, are easily distinguishable from native insulin on reverse-phase columns. 

Examples of the separation of styrene oligomers by HPLC on reversed-phase oc-tadecylsilica columns in a gradient of the mobile phase follow the expected tendency for reversed-phase chromatography of small molecules [120]. Their re-... 

The first results of optimization in chromatography were published in 1975 Since then a growing number of optimization experiments in HPLC using the Simplex procedure has been reported (table 9). The examples are mainly reversed-phase separations, in which the composition of the ternary or binary mobile phase composition is optimized. The factors optimized are usually a selection from flow rate, column temperature and length, the eluents constitution (e.g. organic modifier content, buffer concentration and pH), the gradient shape. Seven years after the first applications of Simplex optimization had appeared, the first fully automated optimization of HPLC separations was published by Berridge in 1982. This development coincid-... 

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