Gem-dibromo compounds

Hydrazones. Reaction of hydrazine with aldehydes and ketones is not generally useful due to competing azine formation or competing Wolff-Kishner reduction. Exceptions have been documented. Recommended conditions for hydrazone preparation are to reflux equimolar amounts of the carbonyl component and hydrazine in n-butanol. - A more useful method for simple hydrazone synthesis involves reaction of the carbonyl compound with dimethylhydrazine followed by an exchange reaction with hydrazine. For substrates where an azine is formed, the hydrazone can be prepared by refluxing the azine with anhydrous hydrazine. gem-Dibromo compounds have been converted to hydrazones by reaction with hydrazine (eq 6). ... 

Harada T, Katsuhira T, Hattori K, Oku A (1994) Stereochemistry in carbenoid formation by bromine/lithium and bromine/zinc exchange reactions of gem-dibromo compounds. Tetrahedron 50 7987-8002. doi 10.1016/S0040-4020(01)85284-4... 

The preparative versatility of the dibromovinylcyclopropanes is further demonstrated by their oxidation to gem-dibromo-cyclopropylaldehydes, compounds which are difficult to obtain by other routes [127]. 

An excellent method for the preparation of gem-difluoro compounds from aldehydes and ketones consists of conversion of the carbonyl compound to the corresponding 1,3-dithiolane followed by treatment with two equivalents of l,3-dibromo-5,5-dimethylhydantoin (DBH) and pyridinium poly(hydrogen fluoride) (HF-pyridine) in methylene chloride. Attempted extension of this procedure to 7-methoxy-2,2-dimethyl-4-chromanone, however, gave only the dihydro- 1,4-dithiin derivative 1 in 78% yield. This transformation, which proceeded in excellent yield with a variety of 4-chromanones, was found to require only the DBH (i.e. fluoride ion played no role). 

The preparation of e/n-difluoro compounds by the oxidative fluorodesul-furization ot 1,3-dithiolanes readily proceeds by treatment with a pyridinium polyhydrogen fluoride-Af-halo compound reagent the latter serves as a bromonium ion source [2], l,3-Dibromo-5,5-dimethylhydantoin is the most effective of several At-halo oxidants. It is believed that /V-halo compounds combine with hydrogen fluoride to generate in situ halogen fluorides, the oxidants. Formation of gem-difluorides from dithiolanes derived from ketones is efficient and rapid, even at -78 °C, whereas the reaction of dithiolanes derived from aldehydes requires higher temperature (0 °C) (equation 4). 

Hydrolysis of the pyrethroids may occur prior to hydroxylation. For dichloro groups (i.e., cyfluthrin, cypermethrin and permethrin) on the isobutenyl group, hydrolysis of the trans-isomers is the major route, and is followed by hydroxylation of one of the gem-dimethyls, the aromatic rings, and hydrolysis of the hydroxylated esters. The cis-isomers are not as readily hydrolyzed as the tran -isomers and are metabolized mainly by hydroxylation. Metabolism of the dibromo derivative of cypermethrin, deltamethrin, is similar to other pyrethroids (i.e., cyfluthrin, cypermethrin, and permethrin) that possess the dichloro group. Type 11 pyrethroid compounds containing cyano groups (i.e., cyfluthrin, cypermethrin, deltamethrin, fenvalerate, fenpropathrin, and fluvalinate) yield cyanohydrins (benzeneacetonitrile, a-hydroxy-3-phenoxy-) upon hydrolysis, which decompose to an aldehyde, SCN ion, and 2-iminothia-zolidine-4-carboxylic acid (TTCA). Chrysanthemic acid or derivatives were not used in the synthesis of fenvalerate and fluvalinate. The acids (i.e., benzeneacetic acid, 4-chloro-a-(l-methylethyl) and DL-valine, Af-[2-chloro-4-(trifluoromethyl) phenyl]-) were liberated from their esters and further oxidized/conjugated prior to elimination. Fenpropathrin is the oifly pyrethroid that contains 2,2,3,3-tetramethyl cyclopropane-carboxylic acid. The gem-dimethyl is hydroxylated prior to or after hydrolysis of the ester and is oxidized further to a carboxylic acid prior to elimination. 

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