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Octanol/water partitioning system

Based on Hquid—Hquid equiHbrium principles, a general model of octanol—water partitioning is possible if accurate activity coefficients can be determined. First, phase equiHbrium relationships based on activity coefficients permit Hquid—Hquid equiHbrium calculations for the biaary octanol—water system. Because the two components are almost immiscible ia each other, two phases form an octanol-rich phase containing dissolved water, and a water-rich phase containing dissolved octanol. [Pg.238]

With only few exceptions, most log P programs refer to the octanol-water system. Based on Rekker s fragmental constant approach, a log P calculation for aliphatic hydrocarbon-water partitioning has been reported [96]. Another more recent approach to alkane-water log P and log D is based on the program VolSurf [97]. It is believed that these values may offer a better predictor for uptake in the brain. [Pg.37]

Bouchard, G., Galland, A., Garrupt, P. A., Gulaboski, R., Mirceski, V., Scholz, F., Girault, H. H. Standard partition coefficients of anionic drugs in the n-octanol/water system determined by voltammetry at three-phase electrodes. Phys. Chem. Chem. Phys. 2003, 5, 3748-3751. [Pg.435]

Seiler [250] proposed a way of estimating the extent of hydrogen bonding in solute partitioning between water and a lipid phase by measuring the so-called A log P parameter. The latter parameter is usually defined as the difference between the partition coefficient of a solute measured in the octanol-water system and that measured in an inert alkane-water suspension AlogP = log Kp oet — log Kp aik. [Pg.224]

Chmelfk, J. Hudecek, J. Putyera, K. Makovicka, J. Kalous, V. Chmelikova, J., Characterization of the hydrophobic properties of amino acids on the basis of their partition and distribution coefficients in the 1-octanol-water system, Collect. Czech. Chem. Commum. 56, 2030-2040 (1991). [Pg.266]

Escher, B. I. Schwarzenbach, R. P., Partitioning of substituted phenols in liposome-water, biomembrane-water, and octanol-water systems, Environ. Sci. Tech. 30,260-270(1996). [Pg.272]

Chiou, C. T., Schmedding, D. W., Manes, M. (1982) Partitioning of organic compounds in octanol-water system. Environ. Sci. Technol. 16, 4-10. [Pg.50]

Hammers, W.E., Meurs, G.J., De Ligny, C.L. (1982) Correlations between liquid chromatographic capacity ratio data on Lichrosorb RP-18 and partition coefficients in the octanol-water system. J. Chromatogr. 247, 1-13. [Pg.609]

Watarai, H., Tanaka, M., Suzaki, N. (1982) Determination of partition coefficient of halobenzenes in heptane/water and 1-octanol/water systems and comparison with the scaled particle calculation. Anal. Chem. 54, 702-705. [Pg.616]

The octanol-water partition coefficient, Kow, is the most widely used descriptor of hydrophobicity in quantitative structure activity relationships (QSAR), which are used to describe sorption to organic matter, soil, and sediments [15], bioaccumulation [104], and toxicity [105 107J. Octanol is an amphiphilic bulk solvent with a molar volume of 0.12 dm3 mol when saturated with water. In the octanol-water system, octanol contains 2.3 mol dm 3 of water (one molecule of water per four molecules of octanol) and water is saturated with 4.5 x 10-3 mol dm 3 octanol. Octanol is more suitable than any other solvent system (for) mimicking biological membranes and organic matter properties, because it contains an aliphatic alkyl chain for pure van der Waals interactions plus the alcohol group, which can act as a hydrogen donor and acceptor. [Pg.217]

The LFER that results when correlating partitioning in the octanol-water system and the humic substances-water system Implies that the thermodynamics of these two systems are related. Hence, much can be learned about humic substances-water partitioning by first considering partitioning In the simpler octanol-water system. The thermodynamic derivation that follows is based largely on the approach developed by Chlou and coworkers (18-20), Miller et al. (21), and of Karickhoff (J, 22). In the subsequent discussion, we will adopt the pure liquid as the standard state and, therefore, use the Lewls-Randall convention for activity coefficients, l.e., y = 1 if the mole fraction x 1. [Pg.194]

Partitioning In Octanol-Water Systems. At equilibrium, the chemical potential of a solute (defined as pj = p + RT In y x ) Is equal In the octanol and the water phase. Hence, we may write... [Pg.194]

The retention times of test solutes are correlated with reference compounds whose partition coefficients in octanol/water (Kow) are known The reliability of this technique depends on the extent to which the stationary and mobile phases simulate the octanol/water system... [Pg.253]

Lipophilicity in particular, as reflected in partition coefficients between aqueous and non-aqueous media most commonly water (or aqueous buffer) and Z-octanol,has received much attention [105,141,152,153,176,199,232,233]. Logic )W for the octanol-water system has been shown to be approximately additive and constitutive, and hence, schemes for its a priori calculation from molecular structure have been devised using either substituent tt values or substructural fragment constants [289, 299]. The approximate nature of any partition coefficient has been frequently emphasized and, indeed, some of the structural features that cause unreliability have been identified and accommodated. Other complications such as steric effects, conformational effects, and substitution at the active positions of hetero-aromatic rings have been observed but cannot as yet be accounted for completely and systematically. Theoretical statistical and topological methods to approach some of these problems have been reported [116-119,175,289,300]. The observations of linear relationships among partition coefficients between water and various organic solvents have been extended and qualified to include other dose-response relationships [120-122,160,161,299-302]. [Pg.266]

Kralj, F. and Sincic, D. Mutual solubilities of phenol, salicyaldehyde, phenol-salicyaldehyde mixture, and water with and without the presence of sodium chloride and sodium chloride plus sodium sulfate, J. Chem. Eng. Data, 25 (4) 335-338,1980. Kramer, C.R. and Henze, U. Partitioning properties of benzene derivatives. 1. Temperature dependence of the partitioning of monosubstituted benzenes and nitrobenzenes in the n-octanol/water system, Z. Phys. Chem., 271(3) 503-513,1990. Krasnoshchekova, R.Ya. and Gubergrits, M. Solubility of paraffin hydrocarbons in fresh and salt water, Neftekhlmlya, 13(6) 885-888, 1973. [Pg.1682]

Yonezawa, Y. and Umshigawa, Y. Chemical-biological interactions in biological pnrification systems. V. Relation between biodegradation rate constants of aliphatic alcohols by activated slndge and their partition coefficients in a 1 -octanol-water system, Chemosphere, 8(3) 139-142, 1979. [Pg.1745]

The plots of log k vs. log P w and the plots of log k (v) vs. log k (z) were studied for seven cephalosporins. A linear relationship was obtained in micellar solution and in microemulsion solution (Tables 3 and 4). The results obtained indicate that the capacity factor determined by EKC could be used both as parameter to characterize the partition behavior of drugs in ME and MC and as hydrophobic parameter instead of log Pow. k appears to be an evident parameter, and it shows a better diversification than P w. In the 1-octanol/water system, we did not found high values of the partition coefficients. In contrast, the ME systems used provide a better characterization of the drugs according to their hydrophilic/lipophilic properties. [Pg.148]

Partitioning in 1-octanol/water system has been characterized from a data set of 600 experimental log Poet values by the following LEER equation (Equation 5.8) [60, 61] ... [Pg.96]


See other pages where Octanol/water partitioning system is mentioned: [Pg.248]    [Pg.166]    [Pg.248]    [Pg.166]    [Pg.685]    [Pg.334]    [Pg.408]    [Pg.410]    [Pg.818]    [Pg.53]    [Pg.76]    [Pg.126]    [Pg.197]    [Pg.209]    [Pg.393]    [Pg.9]    [Pg.30]    [Pg.48]    [Pg.345]    [Pg.220]    [Pg.191]    [Pg.136]    [Pg.101]   
See also in sourсe #XX -- [ Pg.194 ]




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