Hydrophobic protective systems

Hydrophobic protective systems include vitamin E, i.e. a-tocopherol which, as all chromanol compounds, is a free radical scavenger which yields a long-lived radical upon hydrogen abstraction, thereby interrupting the chain reaction [160]. This property is optimized in a-tocopherol (a-TH) which is a remarkable scavenger of peroxyl radicals in phospholipid membrane bilayers [161,162]  

The rate constant for the bimolecular decay of the a-tocopheroxyl radical is only 3.5x 102M-1 s . Therefore, its half-life is several hours in chloroform at ambient temperature. This implies that vitamin E free radical can react with a second peroxyl radical. In biological membranes, a-tocopherylquinone is generally believed to be the major end-product, but the mechanism of its production remains controversial. It may arise either from the decomposition of a-tocopherone, or from dismutation of a-tocopheroxyl radicals. However, the steady-state concentration of a-tocopherylquinone is usually too low to be measurable ex vivo when tissue homogenization and extraction are performed in the presence of pyrogallol and butylated hydroxytoluene, respectively, 

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Thus, without SAIE, Parylene C film, which has excellent barrier and physical properties, cannot be utilized in corrosion protection of a metal. Conversely, SAIE is the key to yield an excellent corrosion protection systems. It is also important to recognize how a nanofilm of hydrophobic amorphous network of plasma coating can prevent the initiation of the salt intrusion process. 

In natural systems dimerization reactions are prevented by the location of the haeme group in a sterically protected protein pocket, which prevents another haeme group approaching and attacking the original haeme. Analogously, protonation reactions are limited by the fact that the haeme group lies in a hydrophobic pocket. 

Topical spermicides such as nonoxynol-9 (N9) and benzalkonium chloride act on sperm membranes through a detergent effect, namely, hydrophobe-hydrophobe interaction between the active and substrate (spermatozoa). The idea was to optimize the cationic/hydrophobic polymer in the drug delivery system so epithelial cells were protected without sacrificing the drug s spermicidal activity. One of the questions that needed to be answered in designing an optimum cationic/hydrophobe modified polymer was the effect of the hydrophobe on the drug activity (N9 initially, and other actives subsequently). 

Biphasic systems consisting of ionic liquids and supercritical CO2 showed dramatic enhancement in the operational stability of both free and immobilized Candida antarctica lipase B (CALB) in the catalyzed kinetic resolution of rac- -phenylethanol with vinyl propionate at 10 MPa and temperatures between 120 and 150°C (Scheme 30) 275). Hydrophobic ionic liquids, [EMIM]Tf2N or [BMIM]Tf2N, were shown to be essential for the stability of the enzyme in the biotransformation. Notwithstanding the extreme conditions, both the free and isolated enzymes were able specifically to catalyze the synthesis of (J )-l-phenylethyl propionate. The maximum enantiomeric excess needed for satisfactory product purity (ee >99.9%) was maintained. The (S)-l-phenylethanol reactant was not esterified. The authors suggested that the ionic liquids provide protection against enzyme denaturation by CO2 and heat. When the free enzyme was used, [EMIM]Tf2N appeared to be the best ionic liquid to protect the enzyme, which... 

Composite thermochromic pigments consist of three components a pH sensitive dye, a proton donor, which acts as the colour developer, and a hydrophobic, nonvolatile co-solvent. To achieve the desired effect the components are mixed in specific ratios and usually encapsulated to protect the system in subsequent applications. A review of the patent literature on these compositions has been published. ... 

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