Antoni Nasal scite author profile

The importance of lipophilicity for pharmacological and toxicological potency of xenobiotics has been recognized for a century. The reference lipophilicity scale is defined by the logarithm of partition coefficient, log P, determined in the l-octanol-water partition system. The tediousness of determinations and limited interlaboratory reproducibility of log P, on one hand, and the observations of linear relationship between log P and chromatographic retention parameters, on the other hand, gave rise to the substitution of the former by the readily available chromatographic data. Since its introduction, the reversed-phase high - performance liquid chromatography (HPLC), which has been viewed in terms of partition of a solute between a polar, aqueous mobile phase and a nonpolar stationary phase appeared especially suitable for lipophilicity (hydrophobicity) determination. The method got wide acceptance and has officially been recommended by the OECD. Fundamental relationships between chromatographic parameters are reviewed from the point of view of convenient and reliable lipophilicity measurements. The advantages and disadvantages of the stationary phase materials, which are presently employed for the determination of lipophilicity as well as those of specific HPLC systems and procedures, are critically reported. The literature on the application of chromatographic and electrochromatographic methods for assessment of lipophilicity of xenobiotics is reviewed. A separate paragraph is devoted to interpretation of retention parameters from HPLC systems comprising biomacromolecules. Role of lipophilicity in drug-biomacromolecule interactions is discussed in terms of quantitative structure-retention relationships (QSRR). Finally, reports are analyzed on systemic information which can be extracted by multivariate methods of data processing, like principal component analysis (PCA), from sets of lipophilicity parameters determined in diverse HPLC systems.

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Determination of solute lipophilicity, as log P(octanol) and log P(alkane) using poly(styrene–divinylbenzene) and immobilised artificial membrane stationary phases in reversed-phase high-performance liquid chromatography

Abraham

Chadha

Leitao³

et al. 1997

Journal of Chromatography A

154

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Simultaneous Determination of pK_a and Lipophilicity by Gradient RP HPLC

et al. 2005

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High-performance methods of testing of drug candidates for properties of pharmacokinetics and pharmacodynamics importance, in particular lipophilicity and acidity, are necessary to overcome innovation stagnation in the pharmaceutical industry. Reversed-phase high-performance liquid chromatography (RP HPLC) might be a unique tool for the determination of both pKa and the apparent (pH-dependent) partition coefficient, applicable in high-throughput analysis of multicomponent mixtures, e.g., samples originating from automated synthesis. In this work, the pH/organic modifier gradient RP HPLC is presented as a means of simultaneous determination of an analyte's acidity and lipophilicity. The approach consists of retention measurements in a series of methanol gradient runs differing in pH range and duration of the gradient. Two different models of the influence of pH on retention in organic modifier gradient RP HPLC are compared regarding the quality of the simultaneously determined lipophilicity and dissociation constants. Advantages of the proposed approach over currently employed procedures are that it can be applied to compound mixtures, it requires only minute amounts of substances, and pKa values can be determined in the range 3-10 units and lipophilicity in the range 0-7 units. Verification of the reliability of the parameters determined by the new method was demonstrated on a series of 93 acidic and basic drug analytes.

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Hydrophobicity parameter from high-performance liquid chromatography on an immobilized artificial membrane column and its relationship to bioactivity

Nasal

Sznitowska

Buciński

et al. 1995

Journal of Chromatography A

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Test Analytes for Studies of the Molecular Mechanism of Chromatographic Separations by Quantitative Structure−Retention Relationships

1999

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Three model series of nonionized in water analytes are proposed for objective interlaboratory comparisons of effects on chromatographic separations of the stationary and the mobile phases by means of the analysis of quantitative structure-retention relationships (QSRR). Each series was designed specifically for a given general QSRR model by selecting the analytes whose properties were well reflected by the respective structural descriptors. Rules of a meaningful chemometric analysis were observed, and the structural information content was compromised with the length of analyte series. Three QSRR models were verified and are recommended for studies of molecular mechanism of chromatographic retention: the reduced linear solvation energy relationship-based model of Abraham, a model employing structural descriptors from molecular modeling, and a model correlating retention to the 1-octanol-water partition coefficient, log P. All the models were demonstrated to provide reliable QSRR equations for five sets of diverse retention data. These equations discriminate quantitatively individual chromatographic systems and are interpretable in straightforward chemical categories. In view of QSRR analysis, the retention processes clearly emerge as the net effects of fundamental intermolecular interactions involving the analyte and the components of chromatographic systems.

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Antoni Nasal

Chromatographic Retention Parameters in Medicinal Chemistry and Molecular Pharmacology

Determination of solute lipophilicity, as log P(octanol) and log P(alkane) using poly(styrene–divinylbenzene) and immobilised artificial membrane stationary phases in reversed-phase high-performance liquid chromatography

Simultaneous Determination of pK_a and Lipophilicity by Gradient RP HPLC

Hydrophobicity parameter from high-performance liquid chromatography on an immobilized artificial membrane column and its relationship to bioactivity

Test Analytes for Studies of the Molecular Mechanism of Chromatographic Separations by Quantitative Structure−Retention Relationships

Contact Info

Product

Resources

About

Antoni Nasal

Chromatographic Retention Parameters in Medicinal Chemistry and Molecular Pharmacology

Determination of solute lipophilicity, as log P(octanol) and log P(alkane) using poly(styrene–divinylbenzene) and immobilised artificial membrane stationary phases in reversed-phase high-performance liquid chromatography

Simultaneous Determination of pKa and Lipophilicity by Gradient RP HPLC

Hydrophobicity parameter from high-performance liquid chromatography on an immobilized artificial membrane column and its relationship to bioactivity

Test Analytes for Studies of the Molecular Mechanism of Chromatographic Separations by Quantitative Structure−Retention Relationships

Contact Info

Product

Resources

About

Simultaneous Determination of pK_a and Lipophilicity by Gradient RP HPLC