Reduction, acid chlorides alkyne

Rearrangement reaction, 138 Reducing sugar, 992 Reduction, 229. 348 acid chlorides, 804 aldehydes, 609-610. 709 aldoses, 992 alkene, 229-232 alkyne, 268-270 amides, 815-816 arenediazonium salt, 943 aromatic compounds and, 579-580... 

Aldehydes are prepared by the hydroboration-oxidation of alkynes (see Section 5.3.1) or selective oxidation of primary alcohols (see Section 5.7.9), and partial reduction of acid chlorides (see Section 5.7.21) and esters (see Section 5.7.22) or nitriles (see Section 5.7.23) with lithium tri-terr-butox-yaluminium hydride [LiAlH(0- Bu)3] and diisobutylaluminium hydride (DIBAH), respectively. 

Symmetrical alkynes and symmetrical and unsymmetrical olefins may be prepared by reductive elimination of suitable groups by amalgams the preparation of diaryalkynes from aromatic acid chlorides with Li(Hg) was described earlier [113,114]. 

A v ety of reactions are catalyzed by electrochemically generated Ni(0) (62). Electrochemical reduction of Ni(bipy)3Br2 affords a reagent that couples acid chlorides and alkyl or aryl halides to form unsymmetrical ketones (63). Symmetrical ketones are formed from alkyl halides and carbon dioxide (64). Reductive electrochemical carboxylation of terminal alkynes, enynes and diynes can be accomplished with 10% Ni(bipy)3(Bp4)2 in DMF (65-68). Terminal allies lead selectively to a-substituted acrylic acids. Electrocatalytic hydrogenation on hydrogen-active electrodes has been reviewed (69). Radical cyclizations of vinyl, alkyl and aryl radicals can be carried out by indirect electrochemical reduction with a Ni(II) complex as a mediator (70). 

The functional groups, such as ester, lactone, N,N-dialkylamide, nitrile, al-kylhalide, benzylic halide, epoxide, alkene, alkyne, and nitroalkane are inert. Alcohols, water, and carboxylic acid produce only hydrogen. No further reaction occurs in B-acyloxy-9-BBN-Py with excess of the reagent 9-BBN-Py. Acid chlorides and anhydrides are, however, reduced rapidly. Thus, with exception of these groups, the selective reduction of aldehyde, in the presence of nearly all other functional groups, can be achieved (Eq. 25.12). 

A synthesis of the biaryl moiety and the seven-membered ring core 3.16 of allocolchicine employed a C-H activation reaction as part of the intramolecular biaryl formation (Scheme 3.19). The starting material was prepared by the acid chloride variant of the Sonogashira reaction (Section 2.8), coupling alkyne 3.17 with acid chloride 3.18. Asymmetric reduction of the ketone 3.19, protection of the alcohol and reduction of the alkyne gave the substrate 3.20 for CH activation. Diimide, generated in situ, was employed for the alkyne reduction to avoid potential problems of over reduction. C-H activation and biaryl formation was then... 

Now, let s draw out the forward scheme. This multi-step synthesis uses three equivalents of ethylene (labeled A, B, C in the scheme below) and one equivalent of acetic acid (labeled D). Ethylene (A) is converted to 1,2-dibromoethane upon treatment with bromine. Subsequent reaction with excess sodium amide produces an acetylide anion which is then treated with bromoethane [made tfom ethylene (B) and HBr] to produce 1-butyne. Deprotonation with sodium amide, followed by reaction with an epoxide [prepared by epoxidation of ethylene (C)] and water workup, produces a compound with an alkyne group and an alcohol group. Reduction of the alkyne to the cis alkene is accomplished with H2 and Lindlar s catalyst, after which the alcohol is converted to a tosylate with tosyl chloride. Reaction with the conjugate base of acetic acid [produced by treating acetic acid (D) with NaOH] allows for an Sn2 reaction, thus yielding the desired product, Z-hexenyl acetate. 

Titanocene dichloride catalyzes the reduction of alkyl, aryl, and vinyl bromides, aryl chlorides, alkoxy- and halosilanes ketones, esters, and carboxylic acids with alkyl Grignard reagents. This Cp2TiCl2/RMgX system can also be used for the hydromagnesation of alkynes, dienes, and alkenes (Section 3.2.5). Kambe et al. have reported a new type of titanocene-catalyzed transformation with vinyl Grignard reagents and chlorosilanes to furnish l,4-disilyl-2-butenes, as shown in Scheme 3.43 [31]. 

The best reagent for selective reduction of alkynes to the cis alkene is the Lindlar catalyst.3 1 Palladium chloride (PdCl2) was precipitated on calcium carbonate (CaCOs) in acidic media and deactivated with lead tetraacetate [Pb(OAc)4] to give the named Pd-CaC03-Pb0 catalyst. Reduction of alkynes will stop at the cis alkene with little or no cis-trans isomerization. A variation uses quinoline as a poison, and this catalyst was used by Overman and co-workers to convert alkyne 378 to cis-alkene 379 as part of a synthesis of... 

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