Acylation 392 Benzylic halides

Rearrangement is especially prevalent with primary alkyl halides of the type RCH2CH2X and R2CHCH2X Aluminum chloride induces ionization with rearrangement to give a more stable carbocation Benzylic halides and acyl halides do not rearrange... 

The cross-coupling reactions of benzylic halides and acyl halides produced the expected ketones in good to high yields(39,47). The present method can supplement the corresponding Grignard reaction, which does not work well since benzylmagnesium halides undergo dimerization readily. 

Nickel-bpy and nickel-pyridine catalytic systems have been applied to numerous electroreductive reactions,202 such as synthesis of ketones by heterocoupling of acyl and benzyl halides,210,213 addition of aryl bromides to activated alkenes,212,214 synthesis of conjugated dienes, unsaturated esters, ketones, and nitriles by homo- and cross-coupling involving alkenyl halides,215 reductive polymerization of aromatic and heteroaromatic dibromides,216-221 or cleavage of the C-0 bond in allyl ethers.222... 

Alkylation of P-dicarbonyl compounds and p-keto esters occurs preferentially on the carbon atom, whereas acylation produces the 0-acyl derivatives (see Chapter 3). There are indications that C- and 0-alkylated products are produced with simple haloalkanes and benzyl halides, but only C-alkylated derivatives are formed with propargyl and allyl halides [e.g. 90]. Di-C-alkylation frequently occurs and it has been reported that the use of tetra-alkylammonium 2-oxopyrrolidinyl salts are more effective catalysts (in place of aqueous sodium hydroxide and quaternary ammonium salt) for selective (-90%) mono-C-alkylation of p-dicarbonyl compounds [91]. 

Mechanistic aspects of the reduction of benzyl halides at mercury have been extensively investigated [35, 38]. From the reduction of benzyl iodide at platinum, Koch and coworkers [39] obtained toluene, bibenzyl, and hydrocinnamonitrile. Electrolysis of benzyl chloride in the presence of acyl chlorides can be used to synthesize alkyl benzyl ketones [40], whereas alcohols are formed by electrolysis of... 

Before addition of the benzyl halide, the only carbonyl adsorption peak is found at 1900 cm, indicative of the cobalt tetracarbonyl anion. After addition, this band immediately disappears and peaks at 2000 cm l are observed. These most likely represent the corresponding acyl complex. Reaction with methoxide yields the product and regenerates the cobalt anion. In the absence of sufficient methoxide, the reaction requires attack by the much... 

Reduction of RCOCI to RCHO. Sodium borohydride and this cadmium salt reduce acyl chlorides to aldehydes, but only in solvents such as DMF, DMA, and HMPT. DMF is essential, but the amount of DMF in the salt is sufficient. For the most part, yields are 50-90%. Aryl, alkyl, and benzylic halides do not react. Other functional groups (nitrile, nitro, ester, C=C) are also inert. 

Three different strategies are generally used for the attachment of carboxylic acids to resins as benzyl esters (a) acylation of resin-bound benzyl alcohols [38-40], (b) O-alkylation of carboxylates by resin-bound benzylic halides [4143], or (c) O-alkylation of carboxylic acids under Mitsunobu conditions [44,45] (Figure 3.3). These reactions are treated in detail in Section 13.4. 

Alkyl halide Benzylic halide Acyl halide These will not react with benzene under Friedel-Crafts conditions ... 

In other variations ketones are produced. The acyliron monoanion may be alkylated again with another alkyl halide to form a transient acyl-alkyl iron intermediate, which rapidly decomposes into ketone and the polynuclear iron carbonyl complex. This reaction is limited, however, because only very reactive alkylating agents such as methyl, allyl, and benzyl halides will react with the weakly nucleophilic acyliron monoanions ... 

Iodonium ylides 715 undergo rhodium-catalyzed reactions with acyl, phenyl, or benzyl halides to form 3-halo-coumarins in good yield (Equation 284) <2002J(P1)1309>. 

In the presence of a ruthenium catalyst, 3-diazochroman-2,4-dione 716 undergoes insertion into the O-H bond of alcohols to yield 3-alkyloxy-4-hydroxycoumarins 717 (Equation 285) <2002TL3637>. In the presence of a rhodium catalyst, 3-diazochroman-2,4-dione 716 can undergo insertion into the C-H bond of arenes to yield 3-aryl-4-hydroxy-coumarins (Equation 286) <2005SL927>. In the presence of [Rh(OAc)2]2, 3-diazochroman-2,4-dione 716 can react with acyl or benzyl halides to afford to 3-halo-4-substituted coumarins (Equation 287) <2003T9333> and also with terminal alkynes to give a mixture of 477-furo[3,2-f]chromen-4-ones and 4/7-furo[2,3-3]chromen-4-ones (Equation 288) <2001S735>. 

The insight that zinc ester enolates can be prepared prior to the addition of the electrophile has largely expanded the scope of the Reformatsky reaction.1-3 Substrates such as azomethines that quaternize in the presence of a-halo-esters do react without incident under these two-step conditions.23 The same holds true for acyl halides which readily decompose on exposure to zinc dust, but react properly with preformed zinc ester enolates in the presence of catalytic amounts of Pd(0) complexes.24 Alkylations of Reformatsky reagents are usually difficult to achieve and proceed only with the most reactive agents such as methyl iodide or benzyl halides.25 However, zinc ester enolates can be cross-coupled with aryl- and alkenyl halides or -triflates, respectively, in the presence of transition metal catalysts in a Negishi-type reaction.26 Table 14.2 compiles a few selected examples of Reformatsky reactions with electrophiles other than aldehydes or ketones.27... 

Methyl Allylic Benzylic Halides on a-carbons of Acyl... 

Benzyl ketones. Ni(0) is a useful catalyst for coupling of benzyl halides with acyl halides to form benzyl ketones, AK-HjCOR, in 40-85% yield.-... 

Incorporation of a benzylic halide into the structure of the alternate-substrate lactone (12-4) led to the bifunctional lactones (13-1, Table 2.13), and (13-2), which showed rapid and irreversible inactivation of a-chymotrypsin and PPE [178]. It was postulated that the intermediate acyl-enzyme formed from attack of Ser-195 on the lactone carbonyl dehydrohalogenated to form a reactive quinone methide that coupled with His-57. If this mechanism were followed, then lactone (13-2) would be an example of a mechanism-activated inhibitor. However, lactone (13-2) is sufficiently reactive as an alkylating agent to directly couple with imidazole while the lactone ring is intact. Because of this, it is not clear, from the published data, whether acylation of Ser-195 precedes alkylation, a prerequisite for this compound to be confirmed as a mechanism-activated inhibitor. Interestingly, the corresponding coumarin (13-3) was both less potent and only provided partial inactivation of a-chymotrypsin [179, 180]. It was shown that the lactone linkage in this coumarin was stable in the presence of a-chymotrypsin and that the modified enzyme retained its intact active-site. These facts led to the postulate that, like the action of phenacyl bromides or benzyl bromides on a-chymotrypsin, the partial inactivation by (13-3) involves alkylation of Met-192 [179]. 

Acidic conditions for hydroxy deprotection can be avoided if benzyl-type ethers ate used as the blocking functions. They can be prepared from the alcohols by alkylation with benzyl halide/sodium hydride in DMSO or benzyl halide/silver(I) oxide in DMF (the silver salt does not cause acyl migration as a side... 

One-step functionalization of aminomethylpolystyrene, type 4, prepared by the Delepine reaction, or by other routes, with various ligands carrying a benzylic halide group i.s shown in Scheme 3. Reaction of polymers of type 4 (4A, Z = H 4B, Z = Br 4C, 2% DVB, gel-type copolymer) with 2-acetyl-4-chloromethylphenol or 4-chloro-methyl-2-formylphenol (2-acyl-4-chlorometh-ylphenoLs are stable at acidic pH [31]) in CHClj, followed by oximation, yields the hydroxyoxime polymers of type.s 5 (66% conversion) and 6 (48% conversion), respectively. 

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