Stereochemistry alkene acylation

In 1995, and regrettably missed in last year s review, Klotgen and Wiirthwein described the formation of the 4,5-dihydroazepine derivatives 2 by lithium induced cyclisation of the triene 1, followed by acylation <95TL7065>. This work has now been extended to the preparation of a number of l-acyl-2,3-dihydroazepines 4 from 3 <96T14801>. The formation of the intermediate anion and its subsequent cyclisation was followed by NMR spectroscopy and the stereochemistry of the final product elucidated by x-ray spectroscopy. The synthesis of optically active 2//-azepines 6 from amino acids has been described <96T10883>. The key step is the cyclisation of the amino acid derived alkene 5 with TFA. These azepines isomerise to the thermodynamically more stable 3//-azepines 7 in solution. 

Entry 5 is an example of the use of fra-(trimethylsilyl)silane as the chain carrier. Entries 6 to 11 show additions of radicals from organomercury reagents to substituted alkenes. In general, the stereochemistry of these reactions is determined by reactant conformation and steric approach control. In Entry 9, for example, addition is from the exo face of the norbornyl ring. Entry 12 is an example of addition of an acyl radical from a selenide. These reactions are subject to competition from decarbonylation, but the relatively slow decarbonylation of aroyl radicals (see Part A, Table 11.3) favors addition in this case. 

Insertion of carbon monoxide into Csp2—Zr bonds occurs readily at ambient temperatures or below to produce a,(5-unsaturated, reactive acyl zirconocene derivatives [27—29]. Early work by Schwartz demonstrated the potential of such intermediates in synthesis [5d], as they are highly susceptible to further conversions to a variety of carbonyl compounds depending upon manipulation. More recently, Huang has shown that HC1 converts 16 to an enal, that addition of a diaryl diselenide leads to selenoesters, and that exposure to a sulfenyl chloride gives thioesters (Scheme 4.11) [27,28]. All are obtained with (F)-stereochemistry, indicative of CO insertion with the expected retention of alkene geometry. 

Phthalimidoaziridines can be cleaved by hydrazinolysis to give 1-aminoaziridines, which decompose slowly at room temperature, and rapidly above 48 C, regenerating the starting alkene with stereochemistry intact. There would appear to be some unexploited potential for phthalimidoaziridines to be used for alkene protection. Phth imidoaziridines are stable to reflux in chlorobenzene (132 C) for 24 h. A/-Aminoaziridines can be acylated to yield )V-acylaminoaziridines of varying thermal stability (34 ti/2 = IS min at 37 C) is a ready thermal source of benzamidonitrene from which new aziridines can... 

Little is known about the stereochemistry of trisubstituted alkene formation in the Julia alkenation. In a synthesis of milbemycin 33 Barrett and coworkersgenerated intermediate (91 equation 22) as a mixture of isomers (E Z = 5 3) by reductive elimination of a 3-acetoxy sulfone however, a similar reductive elimination on the 3-hydroxy sulfone shown in equation (23) gave a single isomer. The marked difference in the yield of these two transformations reflects the advantage of suppressing the retroaldoliza-tion reaction by acylation. 

Originally the phenylsulfone 147 Ar=Ph was used and the adduct was acylated then treated with dissolving metal (e.g. sodium amalgam) to bring about a reductive elimination by electron transfer. Addition of two electrons to 151 gives the dianion 152 that breaks down to the carbanion 153 or something like it - at any rate without stereochemistry - and so to the alkene. 

Protection of the primary and acylation of the secondary alcohol prepares the way for an Ireland-Claisen rearrangement. The E-enolate is produced and the [3,3] sigmatropic rearrangement transmits the chirality across the alkene to set up two new centres. The mechanism of the Ireland-Claisen rearrangement is described above 94 and occurs suprafacially across the backbone of the molecule through a chair-like transition state. We hope you agree both with the relative stereochemistry of the new centres and the E stereochemistry of the new alkene. 

The stereochemical outcome was in agreement with a mechanism for the palladium-catalyzed cyclization/carboalkoxylation of a substituted alkene (Scheme 47) that involves outer-sphere attack of the indole on the palladium-olefin complex I which, coupled with loss of HCI, would form the alkylpalladium intermediate II. 1,1-Migratory insertion of CO into the Pd-C bond of II with retention of stereochemistry would form the acyl-palladium complex III, which could undergo methanolysis to release c/.v-product and form a palladium(0) complex. Oxidation with Cu(II) would then regenerate the active Pd(II) catalyst. 

Warren has used a variation of his phosphine oxide-based olefination method to synthesise single isomers (E or Z) of unsaturated carboxylic acids.23 a-Diphenylphosphinoyl ketones (32) are reduced by sodium borohydride to give diastereomeric mixtures of the corresponding alcohols (33) and (34). These alcohols can be converted to the lactones (35) and (36) which can be separated and individually converted stereospecifically into (Z)-(37) and (E)-(38) alkenes by base treatment (Scheme 6). In many cases it is possible to reduce p-ketophosphine oxides (39) and enones (41) stereoselectively to the ery/Aro-alcohols (40) and (42), respectively, using sodium borohydride in the presence of cerium chloride (Scheme 7).24 An earlier report that reduction in the presence of cerium salts did not cause reversal of stereochemistry compared to reduction with borohydride alone appears to be true only of the compounds studied in that report. The carbanions of 3-hydroxypropylphosphine oxides (43) have been reported to undergo O- to C-acyl transfer to give the p-ketoalkylphosphine oxides... 

As noted in the introduction to this section, under UV light irradiation, carbonyl groups [42] and alkenes [43] will add photochemically in a 2 + 2 sense across the 2- and 3-positions of indole, but only if an acyl or aroyl group is present on the indole nitrogen atom. The photocycloaddition reaction of carbonyl compounds with acylindoles was first reported by Julian and Tringham in 1973 [42], They found that irradiation of N-acetylindole or N-para-chlorobenzoylindole with benzophenone, benzoyl-formamide, or methyl benzoylformate gave oxetane products, as shown in Scheme 12. The stereochemistry of the products was not reported. No products were obtained when the indoles were irradiated with acetophenone, benzaldehyde, acetone, or propionaldehyde. This observation... 

This reaction was first reported by Nenitzescu in 1931. It is the formation of an a,p-unsaturated ketone directly by aluminum chloride-promoted acylation of alkenes with acyl halides. Therefore, it is known as the Darzens-Nenitzescu reaction (or Nenitzescu reductive acylation), or Nenitzescu acylation. Under such reaction conditions, Nenitzescu prepared 2-butenyl methyl ketone from acetyl chloride and 1-butene and dimethylacetylcyclohex-ene from acetyl chloride and cyclooctene. However, in the presence of benzene or hexane, the saturated ketones are often resolved, as supported by the preparation of 4-phenyl cyclohexyl methyl ketone from the reaction of cyclohexene and acetyl chloride in benzene, and the synthesis of 3- or 4-methylcyclohexyl methyl ketone by refluxing the mixture of cycloheptene and acetyl chloride in cyclohexane or isopentane. This is probably caused by the intermolecular hydrogen transfer from the solvent. In addition, owing to its intrinsic strain, cyclopropyl group reacts in a manner similar to an oleflnic functionality so that it can be readily acylated. It should be pointed out that under various reaction conditions, the Darzens-Nenitzescu reaction is often complicated by the formation of -halo ketones, 3,)/-enones, or /3-acyloxy ketones. This complication can be overcome by an aluminum chloride-promoted acylation with vinyl mercuric chloride, resulting in a high purity of stereochemistry. ... 

The stereochemistry of radical addition of hydrogen bromide to alkenes has been studied with both acylic and cyclic alkenes. Anti addition is favored. This is contrary to what would be expected if the sp carbon of the radical were rapidly rotating with respect to the remainder of the molecule ... 

Reviews cover the topics alkynethiolates in synthesis " oxygen-exchange reactions of sulphoxides sulphonyldiazomethanes C—S bond cleavage acyl isothiocyanates radical reactions of sulphur compounds addition of sulphenyl halides to olefins " sulphenamidcs mercaptoethylation of amines sulphur as a chiral centre " stereochemistry of S and S " compounds " reductive cleavage of sulphides, synthetic uses of alkene- and alkyne-thiolates, and thio-Claisen rearrangements nucleophilic displacements at sulphur in disulphides aromatic... 

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