Lead reaction with ketene

The reaction doe.s not involve dehydrogenation and may also be applied (with low yield) to aliphatic acid chlorides. The reaction with aryl isocj anates proceeds analogously to the reaction with ketenes leading through a-ketoiminoketenes to atylimino-4-pyrones, identical to those obtained by Bardone-Gaudemar and described at the end of Section II,B,2,a (see Scheme 6). 

The three-component reaction with ketene as the heterocumulene component and 6-aminouracil (Scheme 136) leads to both zwitterionic het-eropolycyclic uracils and their monohydro products. For example, 377 is obtained by treatment of diphenylketene and pyridine in a 42% yield. However, diphenylketene and quinoline are transformed into the zwitterionic 378 in a satisfactory yield of 54% (94UP2). 

Ketones and aldehydes insert into B-X bonds, and the products vary with the substituents on the substrateU Thus, with BX3 either mono-, bis-, or tn s-inserted products may be obtained in which B-0 bonds are formed. Electron-withdrawing substituents favor insertion. Reactions with ketenes lead to insertion into both the C=C and C=0 bonds . 1,3-Addition of PhBCU occurs with a-diazoethylacetates to form PhClBOC(OEt)=CRCl under mild conditions. Cyclic perfluoroketones react with... 

A similar mechanism, leading to CH2CI and CO, has been proposed for the Cl-atom reaction with ketene (Wallington et al., 1996a). 

The reaction of ketene itself with tettaalkyl titanates followed by a ketone R R C=0 gives P-hydroxy-esters, R R C0HCH2C02R. Polyinsertion of ketene and aldehyde into the Ti—O bond leads to di-, tri-, and tetraesters, eg, H0CR R CH2C02CR R CH2C02R (200). 

Four-membered heterocycles are easily formed via [2-I-2] cycloaddition reac tions [65] These cycloaddmon reactions normally represent multistep processes with dipolar or biradical intermediates The fact that heterocumulenes, like isocyanates, react with electron-deficient C=X systems is well-known [116] Via this route, (1 lactones are formed on addition of ketene derivatives to hexafluoroacetone [117, 118] The presence of a trifluoromethyl group adjacent to the C=N bond in quinoxalines, 1,4-benzoxazin-2-ones, l,2,4-triazm-5-ones, and l,2,4-tnazin-3,5-diones accelerates [2-I-2] photocycloaddition processes with ketenes and allenes [106] to yield the corresponding azetidine derivatives Starting from olefins, fluonnaied oxetanes are formed thermally and photochemically [119, 120] The reaction of 5//-l,2-azaphospholes with fluonnated ketones leads to [2-i-2j cycloadducts [121] (equation 27)... 

The ketocarbene 4 that is generated by loss of Na from the a-diazo ketone, and that has an electron-sextet, rearranges to the more stable ketene 2 by a nucleophilic 1,2-shift of substituent R. The ketene thus formed corresponds to the isocyanate product of the related Curtius reaction. The ketene can further react with nucleophilic agents, that add to the C=0-double bond. For example by reaction with water a carboxylic acid 3 is formed, while from reaction with an alcohol R -OH an ester 5 is obtained directly. The reaction with ammonia or an amine R -NHa leads to formation of a carboxylic amide 6 or 7 ... 

Considerable efforts have been devoted to the stereoselective introduction of a /(-methyl function in intermediates for the synthesis of 1 jS-methylcarbapenems. While the trimethylsilyl trifluoromethanesulfonate catalyzed reaction of a 4-acetoxyazetidinone derivative with ketene acetals shows no selectivity, ketene thioacetals lead to stereoselective formation of the a-methyl isomer108. The zirconium enolate, however, shows high /(-methyl selectivity. 

Cyelobutanone has been prepared by (1) reaction of diazomethane with ketene,4 (2) treatment of methylenecyclobutane with performic acid, followed by cleavage of the resulting glycol with lead tetraacetate,s (3) ozonolysis of methylenecyclobutane, (4) epoxidation of methylene-cyclopropane followed by acid-catalyzed ring expansion,7 and (5) oxidative cleavage of cyclobutane trimethylene thioketal, which in turn is prepared from 2-(co-chloropropyl)-l,3-dithiane.8... 

The cycloaddition of aldehydes and ketones with ketene under the influence of quinine or quinidine produce chiral 2-oxetanones [46,47]. Solvolytic cleavage of the oxetanone, derived from chloral, and further solvolysis of the trichloromethyl group leads to (5)- and (R)-malic acids with a 98% ee [46] (the chirality of the product depends on the configuration of the catalyst at C-8 and, unlike other alkaloid-induced reactions, it is apparently independent of the presence of the hydroxyl group). No attempts have been made to catalyse the reaction with chiral ammonium salts. 

Since reaction of wood with acetic anhydride leads to the formation of acetic acid by-product, which must be removed from the wood, there has been some interest in the use of ketene gas for acetylation (Figure 4.4a). Ketene, for reaction with wood, is produced by pyrolysis of diketene. Provided that the wood contains no moisture, no acetic acid by-product is produced. However, ketene presents handling problems it is very toxic and explosive, and it also has a tendency to dimerize. A comprehensive series of studies of ketene-based acetylation has been performed in Latvia and this work has been reviewed by Morozovs etal. (2003). Hardwoods have been found to be more reactive to ketene than softwoods and the optimal temperature for reaction has been determined as 47 °C. Application of vacuum and treatment of wood with ammonia solution has been used to remove the excess ketene. The reaction of wood with liquid diketene was also studied, with a WPG of 35 % being obtained after reaction for 3 hours at 52 °C. 

For applications in total synthesis this method was also thought to be applicable to chiral aldehydes, leading to matched and mismatched situations. Therefore, vinylogous ketene acetal 40 was put to reaction with chiral aldehyde 44 and both enantiomers of Carreira s catalyst. Reaction of aldehyde 44 with the (S)-Tol-BINAL-CuF catalyst (matched case) produced only one diastereomeric... 

The reaction of Cjq with silylated nucleophiles [47] requires compounds such as silyl ketene acetals, silylketene thioacetals or silyl enol ethers. It proceeds smoothly and in good yields in the presence of fluoride ions (KF/18-crown-6) (Scheme 3.10). The advantage of the latter synthesis is the realization of the cyclopropanation under nearly neutral conditions, which complements the basic conditions that are mandatory for Bingel reactions. Reaction with similar silyl ketene acetals under photochemical conditions and without the use of F does not lead to methanofullerenes but to dihydrofullerene acetate [48]. 

Ketene dithioacetal 82 reacts with aromatic methyl ketones to generate thiopyranones. Further reaction with ethyl mercaptoacetate leads to the formation of thieno[3,2-f]pyranones in good yields (Scheme 18) <1997BML3101>. 

Unlike ketcnc cycloadditions, very few mechanistic studies have been carried out with ketene iminium salt cycloadditions. Differences in regiochemistry in the latter examples suggest that these reactions are not concerted and that a carbcne-type addition to the alkene leading to an intermediate such as 6 is responsible for these reactions.8... 

Gallop et al. [80] reported the preparation of p-lactams via a [2+2] cycloaddition reaction of ketenes with resin-bound imines derived from amino acids (Scheme 9). This is another solid-phase adaptation of the Staudinger reaction, which could lead to the synthesis of structurally diverse 3,4-bis-substituted 2-azetidinones [81]. In addition, a novel approach to the synthesis of A-unsubstituted-p-lactams, important building blocks for the preparation of p-lactam antibiotics, and useful precursors of chiral p-amino acids was described [82]. 

Abstract The main computational studies on the formation of (3-lactams through [2+2] cycloadditions published during 1992-2008 are reported with special emphasis on the mechanistic and selectivity aspects of these reactions. Disconnection of the N1-C2 and C3-C4 bonds of the azetidin-2-one ring leads to the reaction between ketenes and imines. Computational and experimental results point to a stepwise mechanism for this reaction. The first step consists of a nucleophilic attack of the iminic nitrogen on the sp-hybridized carbon atom of the ketene. The zwitterionic intermediate thus formed yields the corresponding (3-1 actant by means of a four-electron conrotatoty electrocyclization. The steroecontrol and the periselectivity of the reaction support this two-step mechanism. The [2+2] cycloaddition between isocyanates and alkenes takes place via a concerted (but asynchronous) mechanism that can be interpreted in terms of a [n2s + (n2s + n2s)] interaction between both reactants. Both the regio and the stereochemistry observed are compatible with this computational model. However, the combination of solvent and substituent effects can result in a stepwise mechanism. 

Thus, ketenes (2) can react as dienophiles with (E)-l,3-diazabuta-l,3-dienes (E)-(25) to yield either [4 + 2] cycloaducts (26) or (27) depending on the participation of the C = C or C = O moieties of the ketenes (Scheme 7). Claisen rearrangement of 3,6-dihydro-2-methylene-2//-l,3,5-oxadiazines (27) yields the p-lactams (28). Alternatively, reaction between ketenes (2) and (Z)-l,3-diaza-buta-1,3-dienes (Z)-(25) leads to the usual zwitterionic intermediates (29), whose conrotatory electrocyclation leads to p-lactams (28). No computational data including solvent effects have been reported for these reactions. 

More recently, we have found that the role of the isomerization pathways in the reaction between ketenes and imines can be extended to the (E)/(Z) isomerization of imines themselves [68]. Thus, the stereocontrol observed in the reaction between methoxyketene 41 and (E)-imines (62a,b) was attributed to the competition between the energy barriers associated with the formation of intermediates (63a,b) and (65a,b) and the energies of activation corresponding to the isomerisation of (E)-imines (62a,b). Inclusion of isomerisation processes involving both imines (62a,b) and zwitterionic intermediates (63a,b) and (65a,b) led to a more complex kinetic analysis. As the final steps leading to (3-lactams (64) can be considered irreversible, the formation of both cis- and trans-(64) can be described by (3) and (4) ... 

In all examples discussed up to now the radical cation of Qo is involved in the reaction mechanism. However, due to the electronic features reduction of the fullerenes leading to radical anions should be much easier performed. For example, a useful method to synthesize 1-substituted l,2-dihydro-[60]fullerenes is the irradiation of Q0 with ketene silyl acetals (KAs) first reported by Nakamura et al. [216], Interestingly, when unstrained KAs are used, this reaction did not yield the expected [2 + 2]-cycloaddition product either by the thermal, as observed by the use of highly strained ketene silyl acetals [217], or by the photochemical pathway. In a typical reaction Q0 was irradiated for 10 h at 5°C with a high pressure mercury lamp (Pyrex filter) in a degassed toluene solution with an excess amount of the KA in the presence of water (Scheme 11). Some examples of the addition of KAs are summarized in Table 11. 

Hetero-Diels-Alder reaction of 44 with enol ether 13 as the dienophile gives cycloadduct 45, which is not isolable but reacts with the water formed in the condensation step with loss of acetone and C02 to lactone 15. A suggested mechanism for the formation of lactone 15 is a retro Diels-Alder reaction which leads to the ketene intermediate 46. Ketene 46 adds to the water formed in the previous condensation step, yielding /3-keto-carboxylic acid 47, which then undergoes decarboxylation to 48. 

Based on their fluorination protocol, Cahard and co-workers have elaborated a convenient synthesis of a-fluoro-a-phenylglycin derivatives [18]. For example, upon reaction with reagent 24 racemic nitrile 23 was converted into the fluorinated derivative 25 with 94% enantiomeric excess. The corresponding ester derivatives of 23 gave rise to somewhat lower ees. This difference was contributed to the fact that a-lithiated nitriles can be in equilibrium with axial-chiral lithio ketene imines of low racemization barriers thus leading to a potential dynamic kinetic resolution. 

The reaction of ketene with a,(1-unsaturated carbonyl compounds in the presence of a cationic palladium(ll) complex leads to the formation of 4-vinyloxetan-2-one intermediates 863, which rearrange under the reaction conditions to give 3,6-dihydropyran-2-ones 864. ot,(3-Unsaturated aldehydes provide higher yields of the desired 3,6-dihydropyran-2-ones than their corresponding ketones (Scheme 239, Table 37) <2000CC73, 2002T5215>. 

---