Aldehydes electrophilic fluorination

There are several new methodologies based on the Julia olefination reaction. For example, 2-(benzo[t/Jthiazol-2-ylsulfonyl)-j -methoxy-i -methylacetamide 178, prepared in two steps from 2-chloro-iV-methoxy-jV-methylacetamide, reacts with a variety of aldehydes in the presence of sodium hydride to furnish the ajl-unsaturated Weinreb amides 179 <06EJOC2851>. An efficient synthesis of fluorinated olefins 182 features the Julia olefination of aldehydes or ketones with a-fluoro l,3-benzothiazol-2-yl sulfones 181, readily available from l,3-benzothiazol-2-yl sulfones 180 via electrophilic fluorination <06OL1553>. A similar strategy has been applied to the synthesis of a-fluoro acrylates 185 <06OL4457>. 

Olefination of aldehydes with a-silyl- and a-stannyl-stabilized phosphonate carbanions derived from cyclo-[L-AP4-D-Val] allow a (Z)-selective access to a,p-substituted vinyl phosphonates (343) that have been transformed into enantiomerically pure 4-alkylidene 4PA derivatives (344) (Figure 54). " Electrophilic fluorination of lithiated bis-lactim ethers derived from cyclo-[L-AP4-D Val] (345) with commercial NFSi allow direct access to a-monofluor-inated phosphonate mimetics of naturally occurring phosphoserine (346) and phosphothreonine (347), in enantiomerically pure form and suitably protected for solid-phase peptide synthesis (Figure 55). ... 

Substituted 2-oxazolidones 165 are useful chiral auxiliaries for diastereoselective functionalization at the a-carbon of their amide carbonyl group. The a-fluoroaldehydes 166 were prepared by a series of reactions electrophilic fluorination of the corresponding oxazolidinone sodium enolates with AMluorobenzenesulfonimine reductive removal of the auxiliary with LiBH4 and Dess-Martin oxidation. The aldehydes are so unstable for isolation that they are converted with (R)-/ -toluenesulfinamide to /7-toluenesul(inimines 167, which are isol-able and satisfactorily enantio-enriched. Chiral sulfinimine-mediated diastereoselective Strecker cyanation with aluminum cyanide provided cyanides 168 in excellent diastereose-lectivity, which were finally derived to 3-fluoroamino acids 169 (see Scheme 9.37) [63]. 

A variety of compounds cannot be prepared by direct nucleophilic F-fluorination. When high specific activity is required and electrophilic fluorination thus is impossible, labeling is often carried out by a multistep route using small reactive intermediates, often named secondary labeling precursors or prosthetic groups. A whole battery of these F-labeled intermediates was investigated and prepared, such as amines, alcohols, aldehydes, ketones, carboxylic acids, esters, and halides. Since a quantitative overview about these synthons is outside the scope of this chapter, only some examples are discussed. 

Noteworthy are the quite complex mechanisms proposed by the authors for the alternative formation of propaigylic and allylic fluorides as depicted in Scheme 2.64. The initial condensation of the catalyst (S)-97 and aldehyde 9 leads to the formation of a reactive enamine species B. The intermediate product D obtained from iminium C, which is formed via electrophilic fluorination of B with 190, can be trapped following two alternative pathways. In the first case, methyl (triphenylphosphoranylidene) acetate (193) forms the oxaphosphetane... 

MacMillan and Beeson [10a] reported studies on the direct asymmetric a-fluorination of aldehydes using N-fluorobenzenesulfonimide (NFSI) as the source of electrophilic fluorine. Scheme 4.2 depicts the results of these investigations. In addition, the successful appUcation of this method for the fluorination of pregnanedione and cholestanone was described by the authors [11]. 

An organocascade aminofluorination reaction of a, 3-unsaturated aldehydes with 174 and NFSI (A-fluorobenzenesulfonimide) as an electrophilic fluorination agent was developed to produce chiral a-fluoro-P-amino aldehydes using catalyst 34 (Scheme 1.74) [ 116]. Up to 85% yield, 98 2 dr, and 99% ee of the reduced alcohols 175 were achieved. 

In contrast, fluorinated ketones have been used as both nucleophilic and electrophilic reaction constituents The (Z)-lithium enolate of 1 fluoro 3,3-di-methylbutanone can be selectively prepared and undergoes highly diastereoselec-tive aldol condensations with aldehydes [7] (equation 8) (Table 4)... 

Rovis and co-workers have also extended the intermolecular Stetter reaction to inclnde nitroaUcenes as the electrophilic component. Fluorinated triazolinm precatalyst 155 was effective in catalysing the reaction of a variety of heteroaromatic aldehydes 153 with nitroalkenes 154 to generate P-nitroketones in excellent yields and enantioselectivities. The authors propose that stereoelectronically induced conformational effects on the catalyst skeleton are key to the high selectivities observed with flnorinated catalyst 155 (Scheme 12.33) [69],... 

The best carbonyl components for these reactions are highly electrophilic compounds such as glyocylate, pyruvate, and oxomalonate esters, as well as chlorinated and fluorinated aldehydes. Most synthetic applications of the carbonyl-ene reaction utilize Lewis acids. Although such reactions may be stepwise in character, the stereochemical outcome is often consistent with a cyclic TS. It was found, for example, that steric effects of trimethylsilyl groups provide a strong stereochemical influence.28... 

Trifluoromethyl)trimethylsilane has been prepared by a modification5 of the procedure originally published by Ruppert.4 The optimized yield is 75%. Other less convenient methods are also available for its preparation. (Trifluoromethyl)trimethylsilane acts as an in situ trifluoromethide equivalent under nucleophilic initiation and reacts with a variety of electrophilic functional groups. Carbonyl compounds such as aldehydes, ketones and lactones react rather readily5 7 with (trifluoromethyl)trimethylsilane under fluoride initiation. The reagent also reacts with oxalic esters,8 sulfonyl fluorides,9 a-keto esters,10 fluorinated ketones,11 and... 

Although efficient organocatalytic methods for the electrophilic a-fluorination of aldehydes and ketones have recently been developed [7], high enantiomeric excesses can only be reached with aldehydes so far. The asymmetric inductions in the case of ketone fluorinations have remained low ee < 36%) [7a]. Thus, the a-silyl ketone-controlled stoichiometric asymmetric synthesis of a-fluoroketones 10 (Scheme 1.1.1) still constitutes a practical method. 

They could be trapped with a variety of electrophiles such as aldehydes, water, carbon dioxide, trimethylsilyl chloride, tributyltin chloride to give the corresponding difluorovinyl derivatives [132-138] (Scheme 52), which were demonstrated to be versatile and useful building blocks for the synthesis of organo-fluorine compounds. 

Cyanoformamidines, exhibiting nucleophilic and electrophilic properties in the 1,3-positions, react with hexafluoroacetone forming five-membered heterocycles (86CB2127). This ability to form five-membered heterocycles is the major characteristic of hexafluoroacetone, which is also inherent in some perfluorinated and partially fluorinated ketones, aldehydes, and imines in their reactions with a-functional derivatives of carboxylic acids, as well as w-amino, a-N-alkylamino,... 

The asymmetric electrophilic a-fluorination of aldehydes with 2,5-disub-stituted pyrrolidines was tested independently by Jorgensen and Barbas III, but in these reactions MacMillan s imidazolidinones (Chapter 18) or diatylprolinol silyl ethers (Chapter 8) afforded much better yields and higher enantioselectivities. 

Houk, Rovis, and their co-workers later extended the scope of the asymmetric intermolecular Stetter reaction of p-nitrostyrenes to unactivated aliphatic aldehydes, which have rarely been utilized in this reaction due to their relatively lower electrophilicity compared with aryl aldehydes. Comparing to known scaffolds, tert-leucine derived trans-fluorinated catalyst leads to improved reactivity and enantioselectivity in this transformation. Computational studies show that the optimized catalyst is the most stereoselective one because the Re-face attack is stabilized by favorable electrostatic interactions between the phenyl group and the fluorine on the catalyst backbone (Scheme 7.31). 

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