Solubility in lipid

The solubility of antioxidants determines their phase distribution in foods. It has been observed that compared to lipid-soluble antioxidants water-soluble antioxidants like ascorbate yield better protection to strongly lipophilic food systems like pure oils. In contrast, antioxidants soluble in lipids like the tocopherols yield better protection to oil-in-water emulsions when compared to water-soluble antioxidants (Porter, 1993). The explanation offered for this... 

Another limitation of 2D gels is that membrane proteins are underrepresented. Because membrane proteins account for approximately 30% of total proteins (Wallin and Von Heijne, 1998), this is a serious problem for characterization of the proteome. The relative lack of membrane proteins resolvable on 2D gels can be attributed to thee main factors (i) they are not abundant, and therefore are difficult to detect by standard staining techniques, (ii) they often possess alkaline pi values, which make them difficult to resolve on the pH gradients most often used for isolelectric focusing, and (iii) the most important reason for under representation may be that membrane proteins are poorly soluble in the aqueous media used for isoelectric focusing (Santoni et al., 2000). Membrane proteins are designed to be soluble in lipid bilayers and are therefore difficult to solubilize in water-based solutions. 

Chessells, M., Hawker, D.W., Connell, D.W. (1992) Influence of solubility in lipid on bioconcentration of hydrophobic compounds. Ecotoxicol. Environ. Saf. 23, 260-273. 

The half-life of chlordane in water is comparatively short. m-Chlordane, for example, usually persists less than 18 h in solution. In soils, however, some chlordane isomers persist for 3 to 14 years because of low solubility in water, high solubility in lipids, and relatively low vapor pressure. There seems to be little accumulation of chlordane in crops grown in contaminated soils. 

Historically, organic environmental pollutants were hydrophobic, often persistent, neutral compounds. As a consequence, these substances were readily sorbed by particles and soluble in lipids. In modern times, efforts have been made to make xenobiotics more hydrophilic - often by including ionisable substituents. Presumably, these functional groups would render the compound less bioaccumulative. In particular, many pesticides and pharmaceuticals contain acidic or basic functions. However, studies on the fate and effect of organic environmental pollutants focus mainly on the neutral species [1], In the past, uptake into cells and sorption to biological membranes were often assumed to be only dependent on the neutral species. More recent studies that are reviewed in this chapter show that the ionic organic species play a role both for toxic effects and sorption of compounds to membranes. 

If the virus is treated with proteolytic enzymes the fuzzy layer formed by the viral spikes is removed (Osterrieth, 1965 Compans, 1971 Gahm-berg et al, 1972 Sefton and Gaffney, 1974 Utermann and Simons, 1974). Remnants of both El and E2 are left in the bilayer. These have a hydrophobic amino acid composition, and are soluble in lipid solvents such as chloroform-methanol. The amphiphilic nature of the spike protein is also evident from its capacity to bind Triton X-100 (0.6 g/g protein) which binds to the hydrophobic part to form a water-soluble protein-detergent complex (Simons et al., 1973a). The ability of amphiphilic proteins to bind Triton can be used to separate them from hydrophilic proteins using an extraction procedure recendy described... 

Chemical signals in urine, fresh-, and saltwater are water soluble. In water, many more compounds are pheromones candidates than in air, because molecules of a wide range of sizes are water soluble. Terrestrial scent marks have to survive humidity and precipitation and so here the active components are soluble in lipids. 

In order for a substance to be absorbed, it must cross biological membranes. Most substances cross by passive diffusion. This process requires a substance to be soluble both in lipid and water. The most useful parameters providing information on the potential for a substance to diffuse across biological membranes are the octanol/water partition coefficient (Log P) value and the water solubility. The Log value provides information on the relative solubility of the substance in water and the hydrophobic solvent octanol (used as a surrogate for lipid) and is a measure of lipophilicity. Log P values above zero indicate that the substance is more soluble in octanol than water, i.e., is lipophilic, and values below zero (negative values) indicate that the substance is more soluble in water than octanol, i.e., is hydrophilic. In general, moderate Log P values (between 0 and 4) are favorable for absorption. However, a substance with a Log P value around 0 and low water solubility (around 1 mg/1) will also be poorly soluble in lipids and hence not readily absorbed. It is therefore important to consider both the water solubility of a substance and its Log P value when assessing the potential of that substance to be absorbed. 

Four highly fluorinated ethers with low boiling points are currently used in anesthesia enflurane, isoflurane, sevoflumne, and desflurane (Figure 8.89). Des-flurane and sevoflurane are now the most used (sevoflurane is especially used in pediatrics). They exhibit the lowest blood-gas partition coefficients, the lowest ratio of toxic metabolites, and the lowest solubilities in lipids. These features limit the retention and, consequently, the metabolism is delayed (Table 8.2). 

Highly soluble in lipids and thus still penetrates bacterial cells that lack the pumping mechanism necessary for uptake of most tetracychne-resistant strains (same for minocychne too). 

By definition, the fraction that enters the circulatory system is eliminated by extrarenal mechanisms (usually metabolism by the liver and other tissues) and is derived by the difference from renal excretion that is, 1 — Fg. The excretory organs are able to eliminate polar compounds such as tetracycline and tylosin more efficiently than compounds that are highly soluble in lipids (i.e., lipophilic) such as metronidazole, erythromycin, clindamycin, and trimethoporin. Thus, the highly lipophilic compounds will not be eliminated until they are metabolized to more polar intermediates. 

The presence of large neutral (green) regions in the electrostatic potential map for vitamin E suggests that the molecule will be soluble in lipids (as it must be in order to function as a trap for radicals). 

The oximes contain a quaternary ammonium group that contributes to their acidity and their strong binding to the inhibited enzyme. This appears to be a key structural element in known reactivators, but it tends to make them poorly soluble in lipids. Practically, this means that the drugs are slowly absorbed from the gastrointestinal tract, have difficulty entering the brain, do not easily enter hepatic cells to be biotransformed, and are not reabsorbed from the renal tubular urine. 

Percutaneous absorption of podophyllum resin occurs, particularly in intertriginous areas and from applications to large moist condylomas. It is soluble in lipids and therefore is distributed widely throughout the body, including the central nervous system. 

In general, the specific constituents of milk are synthesized from small molecules absorbed from the blood. These precursors are absorbed across the basal membrane but very little is known about the mechanism by which they are transported across the membrane. Since the membrane is rich in lipids, and precursors are mostly polar with poor solubility in lipid, it is unlikely that the precursors enter the cell by simple diffusion. It is likely, in common with other tissues, that there are specialized carrier systems to transport small molecules across the membrane such carriers are probably proteins. 

Benzyl acetate is quite soluble in lipids and therefore readily absorbed from the gastrointestinal tract and lung, as well as through the skin, in the species investigated. The absorption after oral administration in the rat was delayed if it was administered in com oil or propylene glycol as compared to neat [wet/zy/ene- Cjbenzyl acetate (Chidgey Caldwell, 1986) the peak plasma concentration of benzyl acetate-derived radioactivity occurred later after 1 h versus 4-6 h) and was lower at a 500 mg/kg benzyl acetate dose at 5 mg/kg benzyl acetate, there was no difference. The urinary excretion of the metabolites was also delayed by com oil, but the extent of absorption seemed not to be affected more than 80% was absorbed and excreted within 24 h, mainly in urine and, ultimately, less than 5% in faeces. In plasma and urine, no intact benzyl acetate was detected at any time only its metabolites were present (Chidgey Caldwell, 1986). Benzyl acetate is rapidly hydrolysed by esterases to benzyl alcohol and acetate (Yuan et al., 1995). These esterases are present in plasma and probably also in the tissues it is... 

Chessells, M., D. W. Hawker, and D. W. Connell, Influence of Solubility in Lipid on Bioconcentration of Hydrophobic Compounds. Ecotoxicol. Environ. Safety, 1992 23, 260-273. 

As we have noted, some vitamins are soluble in water, and others are soluble in lipids. In the following sections we survey the range of biochemical reactions in which water-soluble coenzymes participate. 

The ortho- and para carboxylic acid substituted tetraphenyl porphyrins were used by Nishino and coworkers [36] to prepare the well defined 4-a-helix structures 42 and 43, which are soluble in lipid bilayer membranes. The rigid template of 42 provides some stability to the bundle structure (as measured by... 

Most drug substances and substances of interest to health and environmental risk assessors enter cells by passive permeation (diffusion). In this process, a substance dissolves in the membrane lipid bilayer, permeates through the membrane, and enters into the cytoplasm of the cell. The substance thus must be soluble in lipids. The process is passive because the rate and extent to which a substance will enter a cell by this means depends on its concentration outside and inside the cell. The net movement is from the region of higher concentration to that of lower concentration. Unlike the cell membrane, which is chiefly lipid, the extracellular and intracellular spaces separated by the membrane are aqueous. The higher the concentration of substance outside of the cell, and the more soluble the substance in the membrane lipid bilayer, the greater will be the tendency for the substance to diffuse across the membrane and enter the cytoplasm. The rate and extent of diffusion will decrease as the concentration of the substance inside the cell increases until, eventually, equilibrium is reached. 

The potent oxidizing properties of this activated oxygen permit oxidation of a large number of substrates. Substrate specificity is very low for this enzyme complex. High solubility in lipids is the only common structural feature of the wide variety of structurally unrelated drugs and chemicals that serve as substrates in this system (Table 4-1). 

Soluble in water (4 mg/mL) and 50% ethanol (150 mg/mL) soluble in ethanol (1 to 2) very soluble in lipids. Both powders and liquids are stable in aqueous solutions, most stable at pH 4 (half-life, 511 minutes) in acid solutions and in solutions above pH 7, decomposes rapidly2 at neutral pH, half-life is 98 minutes.3... 

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