Lipophilicity halogenation

A lipophilic halogen, alkyl, or aryl substiment in the 3 position. An isopropyl group has the optimal effect. 

This ranking of halogen atoms can be exemplified by the recently described SAR of halogenated phthalic acid diamides (F < Cl < Br < I) in the development product fiubendiamide (54 ISO-proposed, Hal = I Nihon Nohyaku Co., Ltd./ Bayer Crop Science) [24], which activates selective ryanodine-sensitive intracellular Ca + release channels in insects as novel mode of action [25]. Introduction of a bulky and moderate lipophilic halogen such as iodine into 3-position of the phthalic acid aryl moiety increased the insecticidal activity considerably (Fig. 35.4) (for more details see Chapter 34). 

S. Broder and H. Mitsuya, Lipophilic halogenated congeners of 2 -3 -dideoxypurine nucleosides active against human immunodeficiency virus in vitro, Proc. Natl. Acad. Sci. U.SA.iT. 9426 1990). 

Biooxidation products originating from simple homoaromatic precursors are usually formed in high regio- and stereoselectivity. Lipophilic substituents are most readily converted and the incorporation of a halogen (R = Cl, Br, I) into biooxidation products of TDO is also exploited to give a more pronounced difference in reactivity... 

The ability of quaternary ammonium halides to form weakly H-bonded complex ion-pairs with acids is well established, as illustrated by the stability of quaternary ammonium hydrogen difluoride and dihydrogen trifluorides [e.g. 60] and the extractability of halogen acids [61]. It has also been shown that weaker acids, such as hypochlorous acid, carboxylic acids, phenols, alcohols and hydrogen peroxide [61-64] also form complex ion-pairs. Such ion-pairs can often be beneficial in phase-transfer reactions, but the lipophilic nature of H-bonded complex ion-pairs with oxy acids, e.g. [Q+X HOAr] or [Q+X HO.CO.R], inhibits O-alkylation reactions necessitating the maintenance of the aqueous phase at pH > 7.0 with sodium or potassium carbonate to ensure effective formation of ethers or esterification [49,64]. 

It is noteworthy that benzyltriethylammonium chloride is a slightly better catalyst than the more lipophilic Aliquat or tetra-n-butylammonium salts (Table 5.2). These observations obviously point to a mechanism in which deprotonation of the amine is not a key catalysed step. As an extension of the known ability of quaternary ammonium halides to form complex ion-pairs with halogen acids in dichloromethane [8], it has been proposed that a hydrogen-bonded ion-pair is formed between the catalyst and the amine of the type [Q+X—H-NRAr] [5]. Subsequent alkylation of this ion-pair, followed by release of the cationic alkylated species, ArRR NH4, from the ion-pair and its deprotonation at the phase boundary is compatible with all of the observed facts. 

Chlorinated micropoUutants are harmful for man and environment due to their toxicity, persistence, and bioaccumulation. Persistent compounds are very stable and difficult to get metabolized and mineralized by biological and chemical processes in the environment, and as a result, they have become ubiquitous in water, sediments, and the atmosphere bioaccumulation is the result of the lipophilicity of these compounds. Polychlorinated dibenzodioxins and -furans (PCDD/F) are not produced purposely like many of other chlorinated technical products, such as chlorinated biocides DDT, lindane, and toxaphene. The production and use of persistent organic pollutants (POPs), the dirty dozen has now been banned worldwide by the Stockholm protocol. It should be mentioned that about 3000 halogenated products have now been isolated as natural products in plants, microorganisms, and animals," but the total amount of these products is much smaller compared to xenobiotics. 

The mechanism of action of inhalational anesthetics is unknown. The diversity of chemical structures (inert gas xenon hydrocarbons halogenated hydrocarbons) possessing anesthetic activity appears to rule out involvement of specific receptors. According to one hypothesis, uptake into the hydrophobic interior of the plasmalemma of neurons results in inhibition of electrical excitability and impulse propagation in the brain. This concept would explain the correlation between anesthetic potency and lipophilicity of anesthetic drugs (A). However, an interaction with lipophilic domains of membrane proteins is also conceivable. Anesthetic potency can be expressed in terms of the minimal alveolar concentration (MAC) at which 50% of patients remain immobile following a defined painful stimulus (skin incision). Whereas the poorly lipophilic N2O must be inhaled in high concentrations (>70% of inspired air has to be replaced), much smaller concentrations (<5%) are required in the case of the more lipophilic halothane. 

Halogenated Hydrocarbons. Halogenated hydrocarbons are not easily metabolized and show significant stability in vivo. The addition of halogens tends to increase the lipophilicity and to prolong the half-life of the drug. 

Other types of insecticides have been developed and used over the past several decades. To discuss them all requires an entire course. There is an ASIDE which illustrates the halogenated hydrocarbons most of which are not in current use because of their effects on the environment (DDT) and toxicity to humans (Dieldrin/Aldrin). Estrogenic acivity of DDT led to fatal fragility in the eggs of certain predatory birds. All of these compounds are lipophilic and interfere with nerve signal transmission. 

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