Lipophilicity effective

From these equations it is possible to predict the effective lipophilicity (log D) of an acidic or basic compound at any pH value. The data required in order to use the relationship in this way are the intrinsic lipophilicity (log P), the dissociation constant (pKa) and the pH of the aqueous phase. The overaU effect of these relahonships is the effechve hpophilicity of a compound, at physiological pH, is approximately the log P value minus one unit of hpophilicity, for every unit of pH the pKa value is below (for acids) and above (for bases) pH 7.4. Obviously for compounds with mul-hfunchonal ionizable groups the relahonship between log P and log D, as weU as log D as a function of pH become more complex [65, 68, 70]. For diprotic molecules there are already 12 different possible shapes of log D-pH plots. 

The reduction of surfactant mixture concentration produces opposite formulation drifts for ionic and nonionic surfactants. In effect, lipophilic nonionic species tend to partition into oil, and very little is left in water because of... 

Lipophilic substances with low reactivity may dissolve in the cell membranes and change their physical characteristics. Alcohols, petrol, aromatics, chlorinated hydrocarbons, and many other substances show this kind of toxicity. Other, quite unrelated organic solvents like toluene give very similar toxic effects. Lipophilic substances may have additional mechanisms for their toxicity. Examples are hexane, which is metabolized to 2,5-hexandion, a nerve poison, and methanol, which is very toxic to primates. 

Newer 2-diethylaminoethyl ethers, such as 0-( 2-diethylaminoethyl )-agarose gels," are useful as media for electrophoresis and immunoelec-trophoresis, and the 2-diethylaminoethyl derivative of O-(2-hydroxy-propyl ) cross-linked dextran (Sephadex LH20) is an effective, lipophilic anion-exchanger. The relative stiffness of the molecular chain of 0-(2-diethylaminoethyl) dextran has been estimated from measurements of viscosity at various ionic strengths, and compared with that of other polysaccharide polycations and polyanions. 0-(2-Diethylaminoethyl) dextran itself is claimed to be toxic." ... 

Emulsifiers are classified by the hydrophilic—lipophilic balance (HLB) system. This system indicates whether an emulsifier is more soluble in water or oil, and for which type of emulsion (water-in-oil or oil-in-water) it is best suited. Emulsifiers having alow HLB value are more oil soluble, and are better suited for water-in-oil appHcations such as margarine. Conversely, emulsifiers having a high HLB value are more water soluble, and function more effectively in oil-in-water emulsions such as ice cream (34). The use of this system is somewhat limited because the properties of emulsifiers are modified by the presence of other ingredients and different combinations of emulsifiers are needed to achieve a desired effect. The HLB values of some common emulsifiers are given (35). 

Sediment Toxicity. Because of their low solubiUty ia water and lipophilic nature, phthalates tend to be found ia sediments. Unfortunately httle work has previously been carried out on the toxicity of phthalates to sediment dwelling organisms. Eor this reason ECPI has commissioned some sediment toxicity studies designed to measure the effect of DEHP and DIDP ia a natural river sediment on the emergence of the larvae of the midge, Chironomus riparius. 

The -NH(CH2)3N(CH2)2 amide of teicoplanin factor A2-2, coded MPT. 62,873 [122173-74-4] was also prepared. The combined effect of a moderate basicity and a slightly increased lipophilicity at neutral pH probably led to a better penetration through the cell wall. MDL 62,873 was consistentiy more active than teicoplanin against CNS clinical isolates (119,120). No semisynthetic dalbaheptide is under clinical evaluation at this writing. 

Skin. The skin may become contaminated accidentally or, in some cases, materials may be deHberately appHed. Skin is a principal route of exposure in the industrial environment. Local effects that are produced include acute or chronic inflammation, allergic reactions, and neoplasia. The skin may also act as a significant route for the absorption of systemicaHy toxic materials. Eactors influencing the amount of material absorbed include the site of contamination, integrity of the skin, temperature, formulation of the material, and physicochemical characteristics, including charge, molecular weight, and hydrophilic and lipophilic characteristics. Determinants of percutaneous absorption and toxicity have been reviewed (32—35,42,43,46—49). 

Toxic effects of propranolol are related to its blocking P-adrenoceptor blocking actions. They include cardiac failure, hypotension, hypoglycemia, and bronchospasm. Propranolol is lipophilic and crosses the blood—brain barrier. Complaints of fatigue, lethargy, mental depression, nightmares, hallucinations, and insomnia have been reported. GI side effects include nausea, vomiting, diarrhea, and constipation (1,2). 

For practical appHcation in mixtures of water—organic solvent, only ammonium and phosphonium salts containing 15 or more C atoms are sufficiently lipophilic. In empirical catalyst comparisons crown ethers (hexaoxacyclooctodecanes) (1)—(3) were often as effective as the best onium salts. 

A chemical must have certain physicochemical properties to elicit an endocrine disrupting effect. For example, the ability to enter the body and to cross the cell membrane into the cellular medium requires a degree of lipophilicity. Fipophilic potentials may be compared by reference to the chemical s octanol-water coefficient (usually expressed as log K ). This property, together with molecular size and chemical structure, has an important influence on the bioacciimiilation... 

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