Nickel acylation

Two groups of workers (40, 41) have demonstrated that the reaction proceeds through the formation of a 77--allylnickel intermediate which absorbs CO to form a nickel acyl complex. This then liberates a molecule of acyl halide which is hydrolyzed by the solvent. The presence of the intermediate nickel acyl complex in solution has been demonstrated... 

A recent synthesis of methylenomycin-B (74), based on these observations, features an allylation/car-bonylation (69) - (70) followed by a C-1—C-2 bond/nickel acyl insertion (70) -> (71) and a final meth-oxycarbonylation (71) -> (72). Thus 2-butyn-l-ol (1,2-dialkylacetylenes are inert) afforded in one synthetic operation a 1 4 mixture (78%) of regioisomeric cyclopentenones (72) and (73) which was converted to the antibiotic (74) (Scheme 16). ... 

A recent synthesis of methylenomycin-B (74), based on these observations, features an allylation/car-bonylation (69) (70) followed by a C-1—C-2 bond/nickel acyl insertion (70) - (71) and a final meth-... 

Metal complexes are known to insert CO into carbon-sulfur bonds [118], even catalytically [119], Stoichiometric precedents exist for the formation offhioesters from nickel-alkyls, CO, and thiols [120], For example, NiMe2(bipy) reacts with thiols to afford mefhylnickel(ll) fhiolates, which carbonylate to afford acetyl-nickel(ll) fhiolates. These acetylnickel(II) thiolates reductively eliminate fhioester in the presence of CO [121], More biologically relevant is the reactivity of nickel acyls toward fhiolates, which gives fhe thioester concomitant with reduction to Ni(0) (Eq. 12.10) [122]. Thiolates are known to reduce Ni(II) to Ni(0) under an atmosphere of CO [123]. 

The CO insertion into a nickel-acyl bond and formation of a nickel metallacyclic intermediate have been proposed to be responsible for the formation of a-keto compounds. ... 

Exhaustive carbonylation of Ti-allyltricarbonyliron lactone complexes at elevated temperatures (190 °C) affords S-lactones. The usefulness of this process was demonstrated by a synthesis of the natural product ( )-massoilactone (Scheme 39). Conjugate addition of nickel acylate complexes to enones followed... 

The nickel acylate complex [Ni( 0)3 = (Bu)OLi ] reacts with mono- and disubstituted alkyne derivatives to afford 1,4-diketones, cyclopentenones or y-lactones, depending on the substitution pattern and the reaction time. " Nickelocene, [Ni(q - 5H5)2], reacts with 1,3-dimesitylimidazolium chloride to afford the carbene complex 63, the chloride ligand of which may be subsituted for a methyl group through further reaction with MeLi. Reduction of nickelocene with metallic sodium in the presence of either 1-pentene or 1-hexene results in alkene activation and formation of trinickel products containing p3-carbyne... 

Derivatives like (491 R = Me) can be de-5-methylated by Raney nickel in ethanol or concentrated hydrochloric acid. Acid hydrolysis of (491 R = acyl) also affords 5-mercap-topyrazoles, whereas alkaline hydrolysis of the pyrazolium salt (495) furnishes methanethiol and antipyrine. 

C-C bonds can be formed by reaction with alkyl iodides or more usefully by reaction with metal carbonyls to give aldehydes and ketones e.g. Ni(CO)4 reacts with LiR to form an unstable acyl nickel carbonyl complex which can be attacked by electrophiles such as H+ or R Br to give aldehydes or ketones by solvent-induced reductive elimination ... 

A somewhat more circuitous route is required to prepare sulfonamide-containing pyrimidines unsubstituted at 2. Thus, acylation of the 2-thiomethyl pyrimidine, 147, with the sulfonyl chloride, 88, affords 148. Removal of sulfur by means of Raney nickel (149) followed by deacetylation gives sulformethoxine (113). ... 

The majority of analgesics can be classified as either central or peripheral on the basis of their mode of action. Structural characteristics usually follow the same divisions the former show some relation to the opioids while the latter can be recognized as NSAlD s. The triamino pyridine 17 is an analgesic which does not seem to belong stmcturally to either class. Reaction of substituted pyridine 13 (obtainable from 12 by nitration ) with benzylamine 14 leads to the product from replacement of the methoxyl group (15). The reaction probably proceeds by the addition elimination sequence characteristic of heterocyclic nucleophilic displacements. Reduction of the nitro group with Raney nickel gives triamine 16. Acylation of the product with ethyl chlorofor-mate produces flupirtine (17) [4]. 

When acid catalysts are employed, in the absence of nickel carbonyl, the mechanism involves initial attack by a proton, followed by attack of the resulting carbocation on carbon monoxide to give an acyl cation, which, with water, gives the product ... 

The square planar Ni11 complex (583) was prepared from the template reaction of 3,3 -(ethylene bis(iminomethylidene)bis(2,4-pentanedionato)nickel(II) with l,3-diamino-2-propanol (Equation (18)). The uncoordinated OH group reacted smoothly with acylating agents, resulting in... 

A few further general examples of zinc catalytic activity or reactivity include the following. Other zinc-containing systems include a zinc phenoxide/nickel(0) catalytic system that can be used to carry out the chemo- and regioselective cyclotrimerization of monoynes.934 Zinc homoenolates have been used as novel nucleophiles in acylation and addition reactions and shown to have general utility.935,936 Iron/zinc species have been used in the oxidation of hydrocarbons, and the selectivity and conditions examined.362 There are implications for the mechanism of metal-catalyzed iodosylbenzene reactions with olefins from the observation that zinc triflate and a dizinc complex catalyze these reactions.937... 

The reaction may be reasonably explained by the smooth oxidative addition of benzylic and acyl halides to nickel to afford benzylnickel halides and acylnickel halides. The metathesis of these complexes could give the acylbenzylnickel complex, which upon reductive elimination would yield the benzyl ketone. 

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... 

The instability of 5-aminoimidazoles (96) has led to in situ acylation being used to obtain stable compounds and using this approach several derivatives have been prepared. For example, a solution of the appropriate 5-nitroimidazole (97) in ethyl acetate was reduced with Raney nickel, and the resulting solution of 5-aminoimidazole (96) then treated with an acid chloride to give the amides (118 R1 = Me, R2 = S02Me, COPh, R3 = alkyl, aryl, hetaryl) (25-45%) [82IJC(B)1087],... 

Treated with trifluoroacetic anhydride, sulfoxides 218 undergo conversion to triazapentalenes 219 with high yields. The process must involve acylation of the sulfoxide oxygen atom and generation of a carbocation that attacks the N-2 atom of benzotriazole. Hydrogenation over Raney nickel cleaves the C-S and one of the N-N bonds to generate >rtfe -substituted anilines 220 (Scheme 27) <2002EJ0493>. 

Conjugation between the imino and acyl [121], or nitrile (in complex 1.47) [122] moieties permitted the remote activation of nickel. Another catalyst (1.48) exhibiting coordination via an alkenyl moiety is noteworthy because of its sterically small size, which should prohibit the production of high molecular weight polymers [123], This is believed to be possible because of the catalyst s unique electronic properties. As bulkier imino-aryl substituents are introduced, polymerization activity and polymer molecular weight increases, as expected [124],... 

An intermediate acylnickel halide is first formed by oxidative addition of acyl halides to zero-valent nickel. This intermediate can attack unsaturated ligands with subsequent proton attack from water. It can give rise to benzyl- or benzoin-type coupling products, partially decarbonylate to give ketones, or react with organic halides to give ketones as well. Protonation of certain complexes can give aldehydes. Nickel chloride also acts as catalyst for Friedel-Crafts-type reactions. 

Scheme 7 comprises the following patterns First, a metallacycle gives rise to ketones by CO insertion and reductive elimination. Next, a nickel hydride inserts an unsaturated substrate L, followed by CO. The acyl intermediate can give rise to reductive elimination with formation of acyl halides or acids and esters by hydrolysis, or it can insert a new ligand with subsequent reductive elimination as before. Alternatively, there may be a new insertion of carbon monoxide with final hydrolysis. Third, an intermediate R—Ni—X is formed by oxidative addition. It can react in several ways It can insert a new ligand L, followed by CO to give an... 

The regioselectivity is maintained with mono- and even disubstituted propargylic chlorides (Table 9.33) [56], The copper complex affords allenylcarbinols (A) and the nickel complex favors homopropargylic alcohols (B). In the latter case, the syn adducts are predominant, suggestive of an acylic transition state. 

---