Cyanation aldehydes /ketones

Aldehydes or Ketones with Other Functional Groups Aldehydes, Ketones with Other Functional Groups Kepone Chlordecone Aliphatic Flydrocarbons Aliphatic Nitriles and Cyanates Acetonitrile Acrylonitrile Aliphatic Nitriles Aliphatic Nitrosamines Aliphatic Nitrosamines A-Nitrosodimethylamine (NDMA)... 

Keywords Cyanation, a-Cyanohydrin, a-Aminonitrile, Cyanide, HCN, TMSCN, Lewis acid, Metal-free, Organocatalyst, C=0 bond, C=N bond, Strecker, Reissert, Aldehydes, Ketones, Imines, Aldimines, Ketoimines... 

Cyanation of carbonyl compounds has one of the richest histories of any transformation in the field of asymmetric catalysis, and intensive research efforts have continued unabated since the editorial deadline for the first edition of Comprehensive Asymmetric Catalysis in 1998. This chapter will summarize all efforts in this area from 1998 to date, highlighting the most important catalytic systems from a synthetic and/or mechanistic standpoint. Significant advances in both the cyanation of aldehydes (formation of secondary cyanohydrins Section 28.2.1) and the cyanation of ketones (formation of tertiary cyanohydrins Section 28.2.2) will be addressed [1,2]. 

Relatively few of the enzymatic methods applicable to the preparation of secondary cyanohydrins have been adapted successfully to the synthesis of optically pure tertiary cyanohydrins [1,3,4]. Similarly, progress in asymmetric hydro-cyanation of ketones with synthetic catalysts lagged far behind advances in aldehyde cyanation. This situation has changed fairly dramatically over the past... 

The aldehyde/ketone 1 (4.00 mmol), or the ketone 7 (2.00 mmol), or the isothio-cyanate 5 (2.00 mmol) was ball-milled with the solid hydrazine-hydroquinone complex 2 (2.00 mmol) at 25-30 °C for lh (3 h in the case of Id). The yield was quantitative in all cases, as spectroscopically pure mixtures of 3, 6, 8 with 4 were obtained. Hydroquinone 4 was removed by 5 min trituration with 20 mL of water, filtration and three washings with 2 mL of water, each. The residue was dried in a vacuum to obtain the pure products. 4 was recycled from the aqueous washings by evaporation, addition of 1.0 g of 80% hydrazine hydrate in water per 4 mmol of initially reacted 2 and recrystallization to give 520 mg (91%) of pure 2 after filtration, washing with water and drying. 

The hydrocyanation of alkenes [1] has great potential in catalytic carbon-carbon bond-formation because the nitriles obtained can be converted into a variety of products [2]. Although the cyanation of aryl halides [3] and carbon-hetero double bonds (aldehydes, ketones, and imines) [4] is well studied, the hydrocyanation of alkenes has mainly focused on the DuPont adiponitrile process [5]. Adiponitrile is produced from butadiene in a three-step process via hydrocyanation, isomerization, and a second hydrocyanation step, as displayed in Figure 1. This process was developed in the 1970s with a monodentate phosphite-based zerovalent nickel catalyst [6],... 

Aldehydes, ketones, and acetals react with allyltrimethylsilane in the presence of a catalytic amount of BiX3 (X = C1, Br, OTf) to give homoallyl alcohols or homoallyl alkyl ethers (Equation (52)).91-93 The BiX3-catalyzed allylation of aldehydes and sequential intramolecular etherification of the resulting homoallylic silyl ethers are involved in the stereoselective synthesis of polysubstituted tetrahydropyrans (Equation (53)).94,95 Similarly, these Lewis acids catalyze the cyanation of aldehydes and ketones with cyanotrimethylsilane. When a chiral bismuth(m) catalyst is used in the cyanation, cyanohydrines are obtained in up to 72% ee (Equation (54)). a-Aminonitriles are prepared directly from aldehydes, amines, and cyanotrimethysilane by the BiCl3-catalyzed Strecker-type reaction. 

Because of their predictable behavior and reactivity, thioacyl isocyanates comprise the bulk of this work, and extensive studies of their [4 -I- 2] reactions with olefins, enamines, enol ethers, thioacyl isocyanates, imines, carbodiimides, isocyanates, azirines, /3-enaminoke-tones, dianils, azines, hydrazones, imidazoline-4,5-diones, aryl cyanates, disubstituted cyanamides, aldehydes, ketones, ketenes, alkyl or aryl iminodithiocarbonates, and the carbon-carbon double bond of ketenimines have been detailed. In an extensive comparative study of the [4 + 2] cycloaddition reactions of thioacyl isocyanates, the heterocu-mulenes bearing strong electron-withdrawing substituents were found to be more stable and less prone to participate in cycloaddition reactions. Representative examples are summarized in Scheme 9-IV. 

Metalation and Reactivity with Electrophiles. The reaction of 2-(trimethylsilyl)thiazole (1) with carbon electrophiles such as aldehydes, ketones, ketenes, carboxylic acid chlorides, and azaaryl cations has attracted considerable attention. In this series, Nagasaki and coworkers reported the use of trimethylsilyl heteroarenes as the heteroarenyl carbanion donors in the electrophilic cyanation and described, for example, the electrophilic cyanation of 2-TST (1) with p-toluenesulfonyl cyanide in the absence of solvent (eq 25). ... 

Peroxomonosulfuric acid oxidi2es cyanide to cyanate, chloride to chlorine, and sulfide to sulfate (60). It readily oxidi2es carboxyflc acids, alcohols, alkenes, ketones, aromatic aldehydes, phenols, and hydroquiaone (61). Peroxomonosulfuric acid hydroly2es rapidly at pH <2 to hydrogen peroxide and sulfuric acid. It is usually made and used ia the form of Caro s acid. 

Ozone can be used to completely oxidize low concentrations of organics in aqueous streams or partially degrade compounds that are refractory or difficult to treat by other methods. Compounds that can be treated with ozone include alkanes, alcohols, ketones, aldehydes, phenols, benzene and its derivatives, and cyanide. Ozone readHy oxidizes cyanide to cyanate, however, further oxidation of the cyanate by ozone proceeds rather slowly and may require other oxidation treatment like alkaline chlorination to complete the degradation process. 

The synthetic utility of the carbonylation of zirconacycles was further enhanced by the development of a pair of selective procedures producing either ketones or alcohols [30] and has been extensively applied to the synthesis of cyclic ketones and alcohols, most extensively by Negishi [22—27,29—33,65,87,131—134], as detailed below in Section I.4.3.3.4. The preparation of unsaturated aldehydes by carbonylation with CO is not very satisfactory. The use of isonitriles in place of CO, however, has provided a useful alternative [135], and this has been applied to the synthesis of curacin A [125]. Another interesting variation is the cyanation of alkenes [136]. Further developments and a critical comparison with carbonylation using CO will be necessary before the isonitrile reaction can become widely useful. The relevant results are shown in Scheme 1.35. 

Another reaction type for which EGA catalysis has been thoroughly explored is the reaction between organo-silicon nucleophiles and acetals or unprotected aldehydes and ketones [31-33]. The reaction types are aldol condensation, allyla-tion, cyanation, and hydride reductions depending on which of the nucleophiles (16) to (20) is used. 

The cyanation reactions with (19) (extremely toxic and requires essentially nonacidic reaction conditions) can also he carried out with unprotected aldehydes in good yields but with higher charge consumption (88-97%, 0.15-0.45 F). For ketones, the products are isolated as trimethylsilyl ethers, whereas for aldehydes the sdyl ethers are hydrolyzed to alcohols [33]. 

Cyanation of aldehydes and ketones is an important chemical process for C C bond formation." " Trimethylsilyl cyanide and/or HCN are commonly used as cyanide sources. The intrinsic toxicity and instability of these reagents are problematic in their applications. Acetyl cyanide and cyanoformates were used as cyanide sources in the enantioselective cyanation of aldehydes catalyzed by a chiral Ti complex and Lewis base (Scheme 5.31)." The Lewis base was necessary for the good yields and selectivities of these reactions. The desired products were obtained in the presence of 10mol% triethyl amine and 5mol% chiral titanium catalyst (Figure 5.14). Various aliphatic and aromatic aldehydes could be used in these reactions. 

The double process of cyanation/transcyanation of co-bromoaldehydes and racemic cyanohydrins as a source of HCN is a really interesting process (Scheme 10.25). Thus, using this reaction it is possible to obtain optically active (S)-ketone- and (R)-aldehyde-cyanohydrins in one pot [55], The reaction is carried out in diisopropyl ether using a crude extract of almond containing (R)-oxynitrilase as biocatalyst. The optically active (a-bromocyanohydrins prepared by this method is used as starting materials for the synthesis of valuable compounds such as... 

Other examples of electrophilic toxic chemicals are aldehydes and ketones, especially unsaturated ones, acyl halides and cyanates. 

Reductive cyanation (5, 684 6, 600).1 The original conditions for conversion of ketones into nitriles give low yields when applied to aldehydes. Satisfactory results are obtained, however, if the initial reaction with TosMIC is conducted at 50° in DME before addition of methanol and reflux. Yields of 50-70% are then possible. 

The potential substrates for the Strecker reaction fall into two categories ald-imines (derived from aldehydes, for which cyanide addition results in formation of a tertiary stereocenter) and ketoimines (derived from ketones, for which addition results in a quaternary stereocenter). As in the case of carbonyl cyanation, significant differences are observed between the substrate subclasses. To date, while a few catalyst systems have been found to display broad substrate scope with respect to aldimine substrates, successful Strecker reactions of ketoimines have been reported in only two cases. As is the case for all asymmetric catalytic methodologies, the breadth of the substrate scope constitutes a crucial criterion for the application of the Strecker reaction to a previously unexplored substrate. 

Essentially all of the work on [4 + 2] cycloadditions of selenocarbonyl compounds has been reported within the past five years.Krafft and coworkers have developed a novel method for producing seleno-aldehydes and -ketones, and have investigated in some detail the Diels-Alder chemistry of these species.Alkyl- and aryl-substituted selenocarbonyl compounds could be formed from silyl seleno-cyanates (198) (equation 105). As is the case with thioaldehydes, selenoaldehydes react with cy-clopentadiene to afford predominantly endo cycloadducts. This stereochemical preference has also been observed by Segi et using a different method for generating selenoaldehydes. 

Reduction, Alkylation, Allylation, Cyanation, and Phenylation of Aldehydes and Ketones... 

The earliest method of this type was the old Marckwald synthesis (1] in which a suitable a-aminocarbonyl compound is cyclized with cyanate, thiocyanate or isothiocyanatc. More recent modifications have employed the acetals of the a-amino aldehyde or ketone or an a-amino acid ester. The two-carbon fragment can also be provided by cyanamide, a thioxamate, a carbodiimidc or an imidic ester. When cyanates, thiocyanates or isothiocyanates are used, the imidazolin-2-ones or -2-thiones (1) are formed initially, but they can be converted into 2-unsubstituted imidazoles quite readily by oxidative or dehydrogenative means (Scheme 4.1.1). The chief limitations of the method arc the difficulty of making some a-aminocarbonyls and the very limited range of 2 substituents which are possible in the eventual imidazole products. The method is nonetheless valuable and widely used, and typically condenses the hydrochloride of an a-amino aldehyde or ketone (or the acetals or ketals), or an a-amino-)6-ketoester with the salt of a cyanic or thiocyanic acid. Usually the aminocarbonyl hydrochloride is warmed in aqueous solution with one equivalent of sodium or potassium cyanate or thiocyanate. An alkyl or aryl isocyanate or isothiocyanate will give an A-substituted imidazole product (2), as will a substituted aminocarbonyl compound (Scheme 4.1.1) [2-4]. 

Optically pure cyanohydrins serve as highly versatile synthetic building blocks [24], Much effort has, therefore, been devoted to the development of efficient catalytic systems for the enantioselective cyanation of aldehydes and ketones using HCN or trimethylsilyl cyanide (TMSCN) as a cyanide source [24], More recently, cyanoformic esters (ROC(O)CN), acetyl cyanide (CH3C(0)CN), and diethyl cyanophosphonate have also been successfully employed as cyanide sources to afford the corresponding functionalized cyanohydrins. It should be noted here that, as mentioned in Chapter 1, the cinchona alkaloid catalyzed asymmetric hydrocyanation of aldehydes discovered... 

The allylation and cyanation of aldehydes and ketones are mediated by BiCl3 and BiBr3 [174, 175]. When a chiral bismuth(lll) catalyst is used for cyanation, cyanohydrins are obtained in up to 72% ee (Scheme 14.85) [175]. The Bi(OTf)3-promoted intramolecular Sakurai cyclization of homoallylic alcohols is involved as a key step in the stereoselective synthesis of polysubstituted tetrahydropyrans (Scheme 14.86) [176]. In the presence of the BiCl3-xMl binary catalyst, allyltrimethylsilane [177] and silyl enolates [178] are acylated to give aUyl ketones and /l-dikelories, respectively. 

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