Aldehydes vinyl sulfones

The synthetic applications of o-halobenzyl sulfones as precursors of 1,3- and 1,5-zwitter ionic synthons, have been investigated and their sulfonyl carbanions, generated by means of the phosphazene base Et-P2 reacted with different electrophiles, such as alkyl halides and aldehydes. When the alkylation was performed with ethyl bromoacetate, orf/io-substituted cinnamates were obtained after a subsequent p-elimination of sulfmic acid. When the aldol reaction was performed with paraform aldehyde, vinyl sulfones were obtained. The... 

Methyl vinyl sulfone forms 1,2-cycloaddition adducts with aldehydic enamines, both with and without 3 hydrogens (37). Simple alkylation was reported to take place when phenyl vinyl sulfone was allowed to react with cyclohexanone enamines (58,60), but it has recently been shown that phenyl vinyl sulfone also forms cyclobutane adducts (60a). 

Symmetrical 1,4-diketones (249) can be prepared by the reaction of phenyl vinyl sulfones (53) or divinyl sulfone with aldehydes in the presence of 3-benzyl-5-(2-hydroxymethyl)-4-methylthiazolium chloride as a catalyst (equations 148 and 149)142. 

Vinyl sulfones such as 262 are smoothly converted to a,) -unsaturated nitriles such as 263 on treatment with KCN in the presence of dicyclohexyl-18-crown-6 in refluxing t-butyl alcohol (equation 155)148. The reaction conditions are compatible with base-labile functionalities such as a methoxycarbonyl group (equation 156)148. This method can be used in the preparation of the sesquiterpene aldehyde nuciferal from allyl phenyl sulfones. 

The aziridine aldehyde 56 undergoes a facile Baylis-Hillman reaction with methyl or ethyl acrylate, acrylonitrile, methyl vinyl ketone, and vinyl sulfone [60]. The adducts 57 were obtained as mixtures of syn- and anfz-diastereomers. The synthetic utility of the Baylis-Hillman adducts was also investigated. With acetic anhydride in pyridine an SN2 -type substitution of the initially formed allylic acetate by an acetoxy group takes place to give product 58. Nucleophilic reactions of this product with, e. g., morpholine, thiol/Et3N, or sodium azide in DMSO resulted in an apparent displacement of the acetoxy group. Tentatively, this result may be explained by invoking the initial formation of an ionic intermediate 59, which is then followed by the reaction with the nucleophile as shown in Scheme 43. 

The synthesis of 4,5-disubstituted triazoles shown in Scheme 208, carried out on a polymer support with microwave assistance, is based on a similar principle. In the first step, sulfinate 1248 is converted to sulfone 1249. Condensation with aldehydes provides vinyl sulfones 1250. Cyclocondensation of sulfones 1250 with sodium azide generates corresponding triazoline intermediates that eliminate sulfinate 1248 to provide triazoles 1251 in moderate to good yield <2006OL3283>. 

Also known as Morita-Baylis-Hillman reaction, and occasionally known as Rauhut-Currier reaction. It is a carbon—carbon bond-forming transformation of an electron-poor alkene with a carbon electrophile. Electron-poor alkenes include acrylic esters, acrylonitriles, vinyl ketones, vinyl sulfones, and acroleins. On the other hand, carbon electrophiles may be aldehydes, a-alkoxycarbonyl ketones, aldimines, and Michael acceptors. 

With aldehyde donors, the reactions are generally syn selective. A range of acceptors can be used, including a,p-unsaturated nitro compounds [72, 270, 274-281], a,p-unsaturated ketones [71, 282-285], vinyl phosphonates [286] and vinyl sulfones [287] etc. (Scheme 27). So far, no general anti selective... 

Treatment of lithiated (41) with aldehydes (42a-c) at -78 °C and then at room temperature gives the corresponding alcohols (43a-c) in yields up to 80%. When (43a-c) were refluxed in benzene containing a catalytic amount of p-toluenesulfonic acid the 2-substituted furans (44a-c) were formed in good yields. Various 2,3-disubstituted furans were readily prepared by combination of the synthetic methods for 2- and 3-substituted furans (Scheme 9). The synthetic utility of this route is illustrated by the preparation of 2-(3,7-dimethyl-2,6-heptadienyl-3-methylfuran (47), which is a typical 2,3-disubstituted furan occurring in nature, starting from the aldehyde (46) and the acetal (45) (Scheme 10). Table 1 summarizes the 2,3-disubstituted furans synthesized by this route. However, attempts to extend the method to the preparation of 3-acylfurans (48) was unsuccessful because of the formation of the vinyl sulfone (49) via deacylation. 

Peptide thioesters (Section 15.1.10) are generally prepared by coupling protected amino acids or peptides with thiols and are used for enzymatic hydrolysis. Peptide dithioesters, used to study the structures of endothiopeptides (Section 15.1.11), may be prepared by the reaction of peptide nitriles with thiols followed by thiolysis (Pinner reaction). Peptide vinyl sulfones (Section 15.1.12), inhibitors of various cysteine proteases, are prepared from N-protected C-terminal aldehydes with sulfonylphosphonates. Peptide nitriles (Section 15.1.13) prepared by dehydration of peptide amides, acylation of a-amino nitriles, or the reaction of Mannich adducts with alkali cyanides, are relatively weak inhibitors of serine proteases. 

Only one method has been used to prepare peptide vinyl sulfones. N-Terminal protected peptides are reacted with the salts of amino acid vinyl sulfones derived from the Horner-Emmons reaction of N-terminal protected aldehydes with sulfonylphosphonates in the presence of a base. 4 5 ... 

Horner-Emmons reaction of N-terminal blocked aldehyde 1 with sulfonylphosphonates in the presence of sodium hydride gives the amino acid vinyl sulfone 2, which is deprotected with acid and converted into its chloride or tosylate salt 3 and coupled by the mixed anhydride method with an N-terminal protected peptide or amino acid to give the desired peptide vinyl sulfones 4 (Scheme 2). 4 5 N-Terminal protected aldehydes 1 are obtained from reduction of Boc amino acid V-methoxy-A-methylamides (Weinreb amides, see Section 15.1.1) by lithium aluminum hydride. 9 The V-methoxy-V-methylamide derivatives are prepared by reaction of Boc amino acids with N,O-dimethylhydroxylamine hydrochloride in... 

In the Horner-Emmons reaction (Scheme 3), the sulfonylphosphonate carbanion 5 is formed in the presence of NaH and then reacts with an aldehyde to produce the intermediate 6 that undergoes in situ elimination to yield the vinyl sulfones and phosphonate anion. The sulfonyl group can stabilize the anion in the sulfonylphosphonate 5. The vinyl sulfones that are produced by this method using aldehydes as starting materials are exclusively the E (trans) isomers. The E-isomers of the vinyl sulfones are shown in the NMR spectra based on the coupling constants of the vinylic protons. Although strongly basic conditions are used in the Horner-Emmons reaction and a-amino aldehydes are easily racemized, the amino acid vinyl sulfones prepared by this method still show substantial optical activity. However, the enantiomeric purity of these compounds has not been determined. 5 ... 

The benzene derivatives containing the fluorinated sulfone have been prepared either by nucleophilic substitution of the 4-fluorophenyl derivative (e.g. 1) or by starting with the appropriately substituted sodium thiophenoxide and reacting with perfluoroalkyl iodide follow by oxidation with either MCPBA or chromium oxide (12. li.) The biphenyl derivatives have been prepared by palladium catalyzed cross coupling chemistry of the 4-bromophenyl derivative (e.g. 2) with substituted phenyl boronic acid (yields 37-84%) (JLH, .). Compound 16 has been prepared by palladium catalyzed cross coupling of (4-bromophenyl)perfluorohexyl sulfone with vinyl anisole in 37 % yield (JJL). The vinyl sulfones, 7 and 9, have been prepared by condensation of CH3S02Rf (JJL) with the appropriate aldehyde (yields 70,and 73%) following a literature procedure (1 ). Yields were not optimized. 

The first asymmetric direct Michael addition of enolizable aldehydes RCH2CH=0 to vinyl sulfones CH2=C(S02Ph)2 catalysed by /V-Pr -2,2 -bipyrrolidine (146) has been reported. The 1,4-adducts were obtained in good yields and enantioselectivities... 

Small chiral organic molecules may catalyze the asymmetric addition of ketones, and aldehydes to electron-deficient olefins, such as vinylidene acetones, nitroole-fins, enones, and vinyl sulfones. In this chapter we will describe the inter- and intramolecular reactions in which activation of the carbonyl compound takes place via enamine formation. 

Peptide aldehydes constitute a rather general example of protease inhibitors. The electrophilic carbonyl group is attacked reversibly by the cleaving nucleophile, forming a covalent acetal or thioacetal intermediate. With cysteine proteases the preferred inhibitors are strong electrophiles, for example ketones, chloromethyl ketones, epoxides, or vinyl sulfones. Many cysteine protease inhibitors form an enzyme-inhibitor complex irreversibly these are therefore denoted suicide-inhibitors . 

In the course of these investigations Hoffmann and his group have also developed novel entries to f-butyl 2-methylene-3-oxoalkanoates 2-109a and 2-methylene-3-oxo-sulfones 2-109b by oxidation of 2-108a and 2-108b, respectively obtained by reaction of the aldehydes 2-106 and acrylate 2-107 a or phenyl vinyl sulfone 2-107 b. The cycloadditions of these oxabutadienes to enol ethers and alkenes proceeded in the expected way (Fig. 2-29) [133]. 

Vinyl sulfones. The anion of 1 (n-BuLi) undergoes a Peterson reaction with aldehydes or ketones to afford vinyl sulfones directly in 50-85% yield. Use of dimethoxy-ethane as solvent is essential for satisfactory results. The reaction is not stereoselective. 

Certain substituted sulfones may be obtained by special methods for instance, vinyl sulfones (82) may be formed by addition of a sulfonyl carbanion (83) to a carbonyl compound followed by elimination (Scheme 34). An example when X = H is the synthesis of methyl styryl sulfones (84) by the Knoevenagel condensation of an aromatic aldehyde with a methanesulfonylacetate (85) followed by dealkylation-decarboxylation of the intermediate product by treatment with lithium iodide in DMF (Scheme 35). 

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