Carbonyl compounds a-halo

Synthesis Since a-halo-carbonyl compounds are very reactive electrophiles, we can use a short cut ... 

The condensation of 3-amino-1,2,4-benzotriazine 1-oxides 29 with a-halo-carbonyl compounds results in imidazo[2,l-c]-l,2,4-benzotiiazine 1-oxides 30 (82JHC61, 86MI). 

Reaction of imines with a-halo carbonyl compounds... 

Organoboranes can also be used to construct carbon-carbon bonds by several other types of reactions that involve migration of a boron substituent to carbon. One such reaction involves a-halo carbonyl compounds.20 For example, ethyl bromoac-etate reacts with trialkylboranes in the presence of base to give alkylated acetic acid derivatives in excellent yield. The reaction is most efficiently carried out with a 9-BBN derivative. These reactions can also be effected with (3-alkenyl derivatives of 9-BBN to give (3,y-unsaturated esters.21... 

The reaction of an a-halo carbonyl compound with zinc, tin, or indium together with an aldehyde in water gave a direct cross-aldol reaction product (Eq. 8.90).226,227 A direct Reformatsky-type reaction occurred when an aromatic aldehyde reacted with an a-bromo ester in water mediated by zinc in low yields. Recently, it was found that such a reaction mediated by indium was successful and was promoted by son-ication (Eq. 8.91).228 The combination of BiCl3-Al,229 CdCl2-Sm,230 and Zn-Et3B-Eb0231 is also an effective mediator. Bismuth metal, upon activation by zinc fluoride, effected the crossed aldol reaction between a-bromo carbonyl compounds and aldehydes in aqueous media. The reaction was found to be regiospecific and syn-diastereoselective (Eq. 8.92).232... 

A lot of methods are available for the synthesis of this heterocycle, and most of them rely on the formation of the five-membered ring. In this section, only the methodologies of reasonable scope will be reported. The most classical method involves the cyclocondensation of 2-aminopyridine with an a-halo carbonyl compound. Due to the broad availability of the required substrates and the efficiency of this cyclocondensation, it continues to be the method of choice to prepare this heterocycle. New examples highlighting the generality of this reaction are collected in Table 14. 

Dehalogenation.1 DMBI effects dehalogenation of a-halo carbonyl compounds in a variety of ethereal solvents with formation of DMBI+X in generally high yield. The order of relative reactivity is Br > Cl > F (halides) and primary > secondary > tertiary (for the a-substituted position). In combination with HO Ac (1 equiv.) the reagent also reduces acyl chlorides to aldehydes (70-90% yield). 

Oshima [30] reported a radical alkenylation of a-halo carbonyl compounds under mild conditions by utilizing alkenylindium reagents. Using 0.5 equivalent of triethylborane as a radical initiator at ambient temperature, we demonstrated that this process affords the alkenylation products in high yield (Scheme 10, Eq. 10a). Styrylation reaction showed retention of the stereochemistry from starting alkenylindium (Eq. 10b). 

Alkylation of enolates with a-halo carbonyl compounds. (Formation of 1,4-dicarbonyl compounds)... 

Iron-acyl enolates, such as 2, prepared by x-deprotonation of the corresponding acyl complexes with lithium amides or alkyllithiums, are nearly always generated as fs-enolates which suffer stereoselective alkylation while existing as the crmt-conformer which places the carbon monoxide oxygen anti to the enolate oxygen (see Section 1.1.1.3.4.1.). These enolates react readily with strong electrophiles, such as primary iodoalkanes, primary alkyl sulfonates, 3-bromopropenes, (bromomethyl)benzenes and 3-bromopropynes, a-halo ethers and a-halo carbonyl compounds (Houben-Weyl, Volume 13/9 a, p 413) (see Table 6 for examples). 

This synthesis, originally devised by Tschitschibabin,8 is still the most widely used because it can easily be modified to yield substituted indolizines. The synthesis involves the quaternization of a 2-substituted pyridine, normally using an a-halo carbonyl compound, followed by intramolecular cyclization of the quaternary salt with a mild base, usually aqueous sodium bicarbonate (Scheme 1). 

The disconnection 47 gives a different synthon 48 at the carbonyl oxidation level and the best reagents are the a-halo carbonyl compounds 49. At first this looks like a one-group disconnection but there are two reasons why it isn t. The presence of the carbonyl group makes the Sn2 displacement of halide enormously faster and the a-halo carbonyl compounds 49 are made from the ketone 51 by acid-catalysed halogenation of the enol 50. 

Compounds like the ester 56 were briefly mentioned in chapter 4 and we can now show how they can be made by a two-group disconnection. The electrophile will be the a-halo carbonyl compound 57 and the nucleophile the anion of a carboxylic acid. 

The bromide 57 is made by direct bromination of the ketone 59 and only the very weak base NaHCC>3 is needed to make the anion of the carboxylic acid. This reaction shows just how electrophilic such a-halo carbonyl compounds must be as carboxylate anions are very weak nucleophiles. Compounds 56 are therefore derivatives of carboxylic acids. They are highly crystalline and can be used to characterise and purify such acids.4... 

The oxidative insertion of zinc into a-halo carbonyl compounds and the subsequent reaction of the zinc enolates formed with various electrophiles can either be carried out in a one-pot Barbier-type fashion or in two consecutive steps.1-3 Zinc enolates exhibit a reasonably high stability over a wide temperature range (from -78°C to above 80°C for short periods of time) compared to other metal enolates. Although it has been reported that solutions of BrZnCH2COOtBu can be stored for several days without loss in activity,5 it is generally advisable to use freshly prepared reagents in order to avoid... 

Indium-mediated Barbier-type coupling between carbonyl compounds and allyl halides has been revealed to proceed effectively in diverse reaction media. Even under solvent-free conditions, allylation works well, although no reaction is observed with benzyl bromide and a-halo carbonyl compounds.59 Various aldehydes react with allyl bromide mediated by indium in liquid carbon dioxide to give homoallylic alcohols (Scheme 1). In contrast to the corresponding neat allylation, the liquid C02-mediated reaction can allylate solid aldehydes successfully.60 Indium-mediated allylations of carbonyl compounds with allyl bromide proceed in room temperature ionic liquids. In [bmim][BF4] and [bmim][PF6] (bmin l-butyl-3-methylimidazolium), the desired homoallylic alcohols are formed with good levels of conversion.61 Homoallyllic alcohols are also prepared by the reaction of resin-bound aldehydes (Equation (l)).62... 

Allylgallium and propargylgallium compounds can be prepared by the direct reaction of the corresponding bromides or iodides with gallium metal.402,403Gallium enolates are also prepared from a-halo carbonyl compounds with gallium.404... 

Treatment of silyl enolates with methyllithium followed by an addition of gallium trichloride affords the corresponding gallium enolates. The reaction of the resulting gallium enolates with a-halo carbonyl compounds in the presence of triethylborane provides 1,4-dicarbonyl compounds in good yields (Scheme 142).433... 

The Sml2-mediated Reformatsky reaction provides a useful alternative to traditional versions of the reaction as it proceeds under mild, homogeneous conditions, with high chemo- and diastereoselectivity. Although a-halo esters are the most common substrates for the reaction, in principle any a-halo carbonyl compound can be employed in the reaction. The reactions are most often carried out by the addition of Sml2 to a 1 1 mixture of the a-halocarbonyl compound and the coupling partner. These are often referred to as Barbier conditions (see Section 5.4). 

When the Wittig reaction was introduced (Chapter 14) we saw it simply as an alkene synthesis. Now if we look at one group of Wittig reagents, those derived from a-halo-carbonyl compounds, we can see that they behave as specific enol equivalents in making unsaturated carbonyl compounds. 

In Chapter 26 we saw that reliable C-alkylation occurs with reactive allyl halides and a halo-carbonyl compounds, but that unwanted N-alkylation often competes with simple alkyl halides. 

Carbon-carbon bonds can also be made with alkyl boranes. The requirement for a carbon nucleophile that bears a suitable leaving group is met by a-halo carbonyl compounds. The halogen makes enolization of the carbonyl compound easier and then departs in the rearrangement step. The product is a boron enolate with the boron bound to carbon. Under the basic conditions of the reaction, hydrolysis to the corresponding carbonyl compound is rapid. 

In a one-pot reaction, a,a-disubstituted a-halo carbonyl compounds 1 (R, potassium thiocyanate, acetic acid, and monosubstituted hydrazines 3 are transformed into dihydro-lfT-imidazo[l,5- 7][l,2,4]triazole-2,5 (3H,6H)dithiones 8 (Scheme 1) (93TH, 01TH). With R =H, the reaction takes a different course (cf. Section 2.3). 

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