Reverse phase method development

A Reverse Phase Method Development Protocol for CYCLOBOND 1 2000... 

Development of fast, accurate, and reproducible high-performance liquid chromatography (HPLC) methods has offset the use of traditional open-column and TLC methods in modern chlorophyll separation and analysis. A number of normal and reversed-phase methods have been developed for analysis of chlorophyll derivatives in food samples (unit F4.4), with octadecyl-bonded stationary phase (C]8) techniques predominating in the literature (Schwartz and Lorenzo, 1990). Inclusion of buffer salts such as ammonium acetate in the mobile phase is often useful, as this provides a proton equilibrium suitable for ionizable chlorophyllides and pheophorbides (Almela et al., 2000). 

Because of the bitterness observed in cheeses in which ripening had been accelerated by the addition of enzymes, a reversed-phase method was developed to study the peptide profile in... 

HPLC is commonly used to separate and quantify carotenoids using C18 and, more efficiently, on C30 stationary phases, which led to superior separations and improved peak shape.32 4046 An isocratic reversed-phase HPLC method for routine analysis of carotenoids was developed using the mobile phase composed of either methanol acetonitrile methylene chloride water (50 30 15 5 v/v/v/v)82 or methanol acetonitrile tetrahydrofuran (75 20 5 v/v/v).45 This method was achieved within 30 minutes, whereas gradient methods for the separation of carotenoids can be more than 60 minutes. Normal-phase HPLC has also been used for carotenoid analyses using P-cyclobond46 and silica stationary phases.94 The reversed-phase methods employing C18 and C30 stationary phases achieved better separation of individual isomers. The di-isomers of lycopene, lutein, and P-carotene are often identified by comparing their spectral characteristic Q ratios and/or the relative retention times of the individual isomers obtained from iodine/heat-isomerized lycopene solutions.16 34 46 70 74 101 However, these methods alone cannot be used for the identification of numerous carotenoids isomers that co-elute (e.g., 13-ds lycopene and 15-cis lycopene). In the case of compounds whose standards are not available, additional techniques such as MS and NMR are required for complete structural elucidation and validation. 

Minimal sample preparation (dilution in HPLC mobile phase) is necessary. A standard reversed-phase HPLC method is used for all the samples associated with a drug candidate to reduce time-consuming method development/method refinement procedures. Standard reversed-phase methods typically involve a 20-30 min cycle time and provide information on a wide range of compounds. The incorporation of a standard method strategy allows the use of autosampling procedures and standard system software for data analysis. 

Valko et al. have developed chromatographic methods which are based on established reversed phase methods with acetonitrile water gradients. The lipophilicity is characterized as a so-called chromatographic hydrophobicity index (CHI), which approximates the percentage of acetonitrile necessary for equal distribution between mobile and stationary... 

C. Machado, S. Thomas, D. Hegarty, R. Thompson, D. Ellison, and J. Wyvrat, Development of an indirect reversed phase method for the quahty assessment of an acyl halide, J. Liq. Chromatogr. Relat. Technol. 21 (1998), 575-589. 

The majority of reversed-phase methods have been developed on covalently modified silica gel and the most popular stationary phase is octade-cylsilyl silica (ODS, Cig). Polymeric supports, such as functionalized polystyrene-divinylbenzene copolymers (MacBlane et al., 1987), are particularly useful when mobile phases of higher pH are required because of their resistance to degradation in alkaline solutions. The main drawback of polymeric supports is their reduced column efficiencies and their lower mechanical resistance to high pressures compared with silica gel. 

Exploiting the differences in the characteristics of various commercially available stationary phases would appear to be an attractive option for the development of a reversed-phase method. However, most optimization... 

Are there any other analytical protocols available from the analytical chemist The more information about a compound, the easier it will be to develop a purification procedure. For example, in addition to the reversed-phase method, are there thin-layer chromatography (TLC) methods available for this compound This could help in deciding whether a silica column may be the appropriate tool for this separation. 

Several reversed-phase methods were also developed which do not use a C18 column. A reversed-phase method using a C8 Spherisorb column has been reported (54) to quantitate diltiazem and two of its metabolites (N-monodemethyl diltiazem and desacetyl diltiazem). A 10 pm particle size PRP-1 column (55), mobile phase of 60% acetonitrile and 0.01 M aqueous KH2PO4, 40% 0.005M aqueous tetrabutylammonium hydroxide and UV absorbance detection at 254 nm was used to determine diltiazem present in plasma. Several HPLC methods have been developed which use a cyano-bonded column. One such method was developed for the determination of diltiazem and its metabolite desacetyl diltiazem in human plasma (56). The analytes are extracted from plasma made basic with 0.5M aqueous dibasic sodium phosphate (pH 7.4) using 1% 2-propanol in hexane. The method uses a cyanopropylsilane column with a mobile phase of 45% acetonitrile and 55% 0.05M aqueous acetate buffer (pH 4.0). The minimum detectable limit was 2 ng/mL in plasma. A similar HPLC method was developed by Johnson and Pieper (57) for the determination of diltiazem and three of its metabolites. Also, an HPLC method was developed (58) for the analysis of diltiazem and desacetyl diltiazem in plasma using UV detection at 237 nm, a Zorbax CN 6 pm particle size column and a mobile phase of 45% methanol, 55% 0.05M aqueous ammonium dihydrogen phosphate and 0.25% triethylamine adjusted to pH 5. 

Results of the study indicate that it is possible to simultaneously detect the active drug substance and most related substances at 0.1% (w/w). Furthermore, the method provides different selectivity than reversed-phase HPLC. As a broader conclusion, this indicates orthogonality to reversed-phase HPLC and suggests the viability of SFC in support of early-phase method development. 

The selection and development of a reversed-phase method can be a straightforward process, and for this reason, many methods have been developed on reversed-phase SPE, especially the C-18 sorbent due to its reliable nature. The following examples describe the reversed-phase extraction of compounds of differing polarities from various matrices, as an indication of the broad extent to which reversed-phase SPE can be applied. 

This chapter provides an overview of modern HPLC method development and discusses approaches for initial method development (column, detector, and mobile phase selection), method optimization to improve resolution, and emerging method development trends. The focus is on reversed-phase methods for quantitative analysis of small organic molecules since RPLC accounts for 60-80% of these applications. Several case studies on pharmaceutical impurity testing are presented to illustrate the method development process. For a detailed treatment of this subject and examples of other sample types, the reader is referred to the classic book on general HPLC method development by L. Snyder et al.1 and book chapters2,3 on pharmaceutical method development by H. Rasmussen et al. Other resources include computer-based training4 and training courses.5... 

Despite their structural similarity, atropine ( hyoscyamine) and homatropine cannot be assayed in the same way as hyoscine (6,7-epoxyatropine) as the former compounds are very strongly retained on unmodified silica. Reversed-phase methods usually suffer from analyte peak tailing and, although some success with base deactivated columns has been achieved, it has not proved possible to develop... 

The selection of starting conditions is the first step in HPLC method development. Instead of starting with arbitrary conditions or conditions derived from the chromatographer s experience or intuition, the software can predict suitable initial conditions for reversed-phase methods from analyte structures and properties of the sorbent/solvent system [1-3]. If structures are known, the theoretical approach has the potential to save time and effort, since in this way the experimental method development process will start under the theoretically predicted optimum conditions. 

At the same time, nonaqueous reversed-phase methods have been developed. Wright and Shearer [220] used a linear gradient from 90% of acetonitrile to 100% of ethyl acetate to separate 44 pigments that included carotenes, xanthophylls, chlorophylls, and derivatives, in marine phytoplankton. Khachik et al. [240] combined an isocratic elution and gradient of methanol, acetonitrile, methylene chloride, and n-hexane to separate the major constituents (xanthophylls, chlorophylls, and caroteies) in different vegetables. 

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