Oil/water partition coefficient

General anaesthetics have been in use for the last 100 years, yet their mechanism of action are still not yet clearly defined. For many years it was thought that general anaesthetics exerted their effects by dissolving in cell membranes and perturbing the lipid environment in a non-specific manner. This theory derived from the observation that for a number of drugs which induced anaesthesia, their potency correlated with their oil-water partition coefficients. This Meyer-Oveiton correlation was accepted for a number of years, however in the last 15-20 years evidence has shown that a more likely theory is that of specific interactions of anaesthetics with proteins, particularly those within the CNS that mediate neurotransmission [1]. 

In 1868 two Scottish scientists, Crum Brown and Fraser [4] recognized that a relation exists between the physiological action of a substance and its chemical composition and constitution. That recognition was in effect the birth of the science that has come to be known as quantitative structure-activity relationship (QSAR) studies a QSAR is a mathematical equation that relates a biological or other property to structural and/or physicochemical properties of a series of (usually) related compounds. Shortly afterwards, Richardson [5] showed that the narcotic effect of primary aliphatic alcohols varied with their molecular weight, and in 1893 Richet [6] observed that the toxicities of a variety of simple polar chemicals such as alcohols, ethers, and ketones were inversely correlated with their aqueous solubilities. Probably the best known of the very early work in the field was that of Overton [7] and Meyer [8], who found that the narcotic effect of simple chemicals increased with their oil-water partition coefficient and postulated that this reflected the partitioning of a chemical between the aqueous exobiophase and a lipophilic receptor. This, as it turned out, was most prescient, for about 70% of published QSARs contain a term relating to partition coefficient [9]. 

Despite the work of Overton and Meyer, it was to be many years before structure-activity relationships were explored further. In 1939 Ferguson [10] postulated that the toxic dose of a chemical is a constant fraction of its aqueous solubility hence toxicity should increase as aqueous solubility decreases. Because aqueous solubility and oil-water partition coefficient are inversely related, it follows that toxicity should increase with partition coefficient. Although this has been found to be true up to a point, it does not continue ad infinitum. Toxicity (and indeed, any biological response) generally increases initially with partition coefficient, but then tends to fall again. This can be explained simply as a reluctance of very hydrophobic chemicals to leave a lipid phase and enter the next aqueous biophase [11]. An example of this is shown by a QSAR that models toxicity of barbiturates to the mouse [12] ... 

Table 2 Influence of Oil/Water Partition Coefficient (Ko/w) on Absorption from the Rat Intestine...

Since many essential nutrients (e.g., monosaccharides, amino acids, and vitamins) are water-soluble, they have low oil/water partition coefficients, which would suggest poor absorption from the GIT. However, to ensure adequate uptake of these materials from food, the intestine has developed specialized absorption mechanisms that depend on membrane participation and require the compound to have a specific chemical structure. Since these processes are discussed in Chapter 4, we will not dwell on them here. This carrier transport mechanism is illustrated in Fig. 9C. Absorption by a specialized carrier mechanism (from the rat intestine) has been shown to exist for several agents used in cancer chemotherapy (5-fluorouracil and 5-bromouracil) [37,38], which may be considered false nutrients in that their chemical structures are very similar to essential nutrients for which the intestine has a specialized transport mechanism. It would be instructive to examine some studies concerned with riboflavin and ascorbic acid absorption in humans, as these illustrate how one may treat urine data to explore the mechanism of absorption. If a compound is... 

Figure 7.5 Intrinsic permeabilities of ionizable acids versus oil-water partition coefficients.

This book is written for the practicing pharmaceutical scientist involved in absorption-distribution-metabolism-excretion (ADME) measurements who needs to communicate with medicinal chemists persuasively, so that newly synthesized molecules will be more drug-like. ADME is all about a day in the life of a drug molecule (absorption, distribution, metabolism, and excretion). Specifically, this book attempts to describe the state of the art in measurement of ionization constants (p Ka), oil-water partition coefficients (log PI log D), solubility, and permeability (artificial phospholipid membrane barriers). Permeability is covered in considerable detail, based on a newly developed methodology known as parallel artificial membrane permeability assay (PAMPA). 

The importance of lipids in membrane structure was established early in the 20th century when pioneering biophysicists established positive correlations between cell membrane permeabilities to small non-electrolytes and the oil/water partition coefficients of these molecules. Contemporary measurements of the electrical impedance of cell suspensions suggested that cells are surrounded by a hydrocarbon barrier, which was first estimated to be about 3.3 nm thick. This was originally thought to be a lipid monolayer. Among the pioneering biophysical experiments were those that established that the ratio of the area of a monolayer formed from erythrocyte... 

Assuming that for a solute the properties of the biological membrane resemble those of olive oil on an atomistic level, the membrane/donor partition coefficient K may be estimated from the olive oil-water partition coefficient tfoo/w according to the general relationship [16-18] ... 

Using the mineral oil-water partition coefficient to estimate the partition coefficient between the stratum corneum lipid and protein phases, and using a fixed value of Dprot = 2 x 10-7 cm2/s, Eq. 35 showed a remarkable agreement with experimental data for a value of Aip/ prot of 2 x 10-3. Unfortunately, data... 

Platford, R.F. Oil-water partition coefficients from solvent activities. J. Sdution Chem., 5(9) 645-651, 1976. 

D) Although some exceptions occur, a correlation between anesthetic potency and their oil-water partition coefficient suggested a unitary hypothesis for the production of anesthesia. 

Thiopentone sodium (Figure 4.3) is available as a yellow powder, stored in nitrogen to prevent atmospheric degradation, and mixed with 5% anhydrous sodium carbonate. The sodium carbonate prevents precipitation of the insoluble free acid and results in a solution with a pH of 10.5-11.0. The oil/water partition coefficient is 4.7 and the pKa 7.6. Although thiobarbiturate solutions are stable, if refrigerated, for up to two weeks, they should not be stored for longer than 24 hours as the solutions do not contain any antibacterial preservative. 

Emollients are often added to cream formulations to modify either the characteristics of the pharmaceutical vehicle or the condition of the skin itself to promote penetration of the active ingredient to act either locally or systemically. The stratum corneum, being keratinized tissue, behaves as a semipermeable artificial membrane, and drug molecules can penetrate by passive diffusion. The rate of drug movement depends on the drug concentration in the vehicle, its aqueous solubility, and the oil/ water partition coefficient between the stratum corneum and the product s vehicle. Commonly used emollients include glycerin, mineral oil, petrolatum, isopropyl pal-mitate, and isopropyl myristate. 

The study of receptors has not featured as prominently in toxicology as in pharmacology. However, with some toxic effects such as the production of liver necrosis caused by paracetamol, for instance, although a dose-response relation can be demonstrated (see chap. 7), it currently seems that there may be no simple toxicant-receptor interaction in the classical sense. It may be that a specific receptor-xenobiotic interaction is not always a prerequisite for a toxic effect. Thus, the pharmacological action of volatile general anesthetics does not seem to involve a receptor, but instead the activity is well correlated with the oil-water partition coefficient. However, future detailed studies of mechanisms of toxicity will, it is hoped, reveal the existence of receptors or other types of specific targets where these are involved in toxic effects. 

The induction of unconsciousness may be the result of exposure to excessive concentrations of toxic solvents such as carbon tetrachloride or vinyl chloride, as occasionally occurs in industrial situations (solvent narcosis). Also, volatile and nonvolatile anesthetic drugs such as halothane and thiopental, respectively, cause the same physiological effect. The mechanism(s) underlying anesthesia is not fully understood, although various theories have been proposed. Many of these have centered on the correlation between certain physicochemical properties and anesthetic potency. Thus, the oil/water partition coefficient, the ability to reduce surface tension, and the ability to induce the formation of clathrate compounds with water are all correlated with anesthetic potency. It seems that each of these characteristics are all connected to hydrophobicity, and so the site of action may be a hydrophobic region in a membrane or protein. Thus, again, physicochemical properties determine biological activity. 

Phenobarbital is utilized as a daytime sedative and anticonvulsant. It also induces several cytochrome P450 isozymes. Compared to other barbiturates, phenobarbital has a low oil/water partition coefficient, which results in slow distribution into the brain. It is available for oral, intravenous, or intramuscular administration. Doses for epileptic patients range from 60 to 200 mg per day. After a single oral dose of 30 mg, peak serum concentrations averaged 0.7 mg/L (n = 3). Repeated doses over a period of 7 days resulted in an average peak concentration of 8.1 mg/L.6 Chronic administration of 200 mg per day as anticonvulsant medication resulted in an average blood concentration of 29 mg/L (range = 16 to 48 mg/L).8... 

The permeability of unionizable compounds is a function of their lipid solubilities, determined by their oil water partition coefficients. Squier et al. [16] demonstrated this dependence of water permeability on the lipid contents of keratinized and nonkeratinized epithelia. The lipids present however contribute to this effect more in the keratinized epithelia (more total lipid content, nonpolar lipids, ceramides) than in the nonkeratinized epithelia where permeability seems to be related to the amount of glycosylceramides present. 

Forty years later Meyer [1], and at the same time Overton [2], observed a linear relationship between the activity of narcotics and their oil-water partition coefficient. An 40 years after that, a thermodynamic interpretation of this relationship was provided by Ferguson [3], which also explained cut-off of biological activity that is sometimes observed after a certain lipophilicity range has been passed. 

Table 2.2 Relationship of oil/water partition coefficient to drug absorption...

It was at the turn of the twentieth century that the importance of lipid solubility in drug action was also independently described by Meyer and Overton (the significance of the oil/water partition coefficient was discussed in Chapter 2). The importance of lipid solubility in drug action subsequently became manifested in the lipoid theory of cellular depression. In essence, this theory correlated a pharmacological effect (e.g., CNS depression) with a physical property (i.e., lipid solubility) rather than a structure-activity relationship. In the process, the theory was attempting to explain the diverse chemical structures that exist within the hypnotic and general anesthetic classes of drugs (see Chapter 11). Today, we realize the limitations of the lipoid theory and appreciate that the distinction between physical and chemical factors is illusory, since chemical structure is a determinant of physical properties. 

The properties and uses of surfactants are strongly dependent on the HLB (as described above), the oil-water partition coefficient (K ), and the solubility parameter. The relationship between HLB and of nonionic surfactants has been examined and is expressed by ... 

Based on the earlier work of Meyer and Overton, who showed that the narcotic effect of anesthetics was related to their oil/water partition coefficients, Hansch and his co-workers have demonstrated unequivocally the importance of hydrophobic parameters such as log P (where P is, usually, the octanol/water partition coefficient) in QSAR analysis.28 The so-called classical QSAR approach, pioneered by Hansch, involves stepwise multiple regression analysis (MRA) in the generation of activity correlations with structural descriptors, such as physicochemical parameters (log P, molar refractivity, etc.) or substituent constants such as ir, a, and Es (where these represent hydrophobic, electronic, and steric effects, respectively). The Hansch approach has been very successful in accurately predicting effects in many biological systems, some of which have been subsequently rationalized by inspection of the three-dimensional structures of receptor proteins.28 The use of log P (and its associated substituent parameter, tr) is very important in toxicity,29-32 as well as in other forms of bioactivity, because of the role of hydrophobicity in molecular transport across cell membranes and other biological barriers. 

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