Cyanation Strecker synthesis

Cyanations. Aluminum complexes with diarylphosphine oxide groups possev cyanation of aldehydes and imines- with in a manner analogous to the Reisser asymmetric Strecker synthesis is applic reactivity of Me SiCN than HCN in the p catalytic amount while supplying stoichica... 

Cyanadons. Aluminum complexes of BINOLs (1) that are armed at C-3 and C-3 with diarylphosphine oxide groups possess both Lewis acid and base centers. Asymmetric cyanation of aldehydes and mines with MeaSiCN, and of quinolines and isoquinolines in a manner analogous to the Reissert reaction is successful (ee 70-90%). The asymmetric Strecker synthesis is applicable to conjugated aldimines and the higher reactivity of Me SiCN than HCN in the presence of 10 mol% of PhOH enables its use in catalytic amount while supplying stoichiometric HCN as the cyanide source. 

The Strecker synthesis starting from a-amino nitriles and potassium cyanate yields useful hydantoins as intermediates. They are hydrolyzed at neutral pH to hydantoic acids and to amino acids (not shown) (Scheme 9.4.3)... 

Peptide-catalysed Cyanations Cyanhydrin Synthesis and Strecker Reactions... 

Asymmetric cyanation of imines, a modified Strecker synthesis, affords enantiomerically enriched a-aminonitriles, which can be converted into a-amino acids. Seayad and Ramahngam reported a homogeneous catalyst system that was derived... 

Basic principle for the synthesis of optically pure l- and o-amino acids via Strecker synthesis of racemic hydantoins and their (dynamic) kinetic resolution and stepwise hydrolysis toward the amino acids. KOCN, potassium cyanate HYD, hydantoin 28 CARB-AA,... 

The Strecker reaction [1] starting from an aldehyde, ammonia, and a cyanide source is an efficient method for the preparation of a-amino acids. A popular version for asymmetric purposes is based on the use of preformed imines 1 and a subsequent nucleophilic addition of HCN or TMSCN in the presence of a chiral catalyst [2], Besides asymmetric cyanations catalyzed by metal-complexes [3], several methods based on the use of organocatalysts have been developed [4-14]. The general organocatalytic asymmetric hydrocyanation reaction for the synthesis of a-amino nitriles 2 is shown in Scheme 5.1. 

An important application of oxidation of a C-H bond adjacent to a nitrogen atom is the selective oxidation of amides. This reaction proceeds in the presence of ferf-BuOOH as the oxidant and Ru(II) salts. Thus in the example of Eq. (36), the a-tert-butylperoxy amide of the isoquinoline was obtained, which is an important synthetic intermediate for natural products [138]. This product can be conveniently reacted with a nucleophile in the presence of a Lewis add. Direct trapping of the iminium ion complex by a nudeophile was achieved in the presence of trimethylsilyl cyanide, giving a-cyanated amines as shown in Eq. (37) [45]. This ruthenium/peracid oxidation reaction provides an alternative to the Strecker reaction for the synthesis of a-amino acid derivatives since they involve the same a-cyano amine intermediates. In this way N-methyl-N-(p-methoxyphenyl) glycine could be prepared from N,N-dimethyl-p-methoxyaniline in 82% yield. 

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. 

Strecker reactions are among the most efficient methods of synthesis of a-amino nitriles, useful intermediates in the synthesis of amino acids [73] and nitrogen-containing heterocycles such as thiadiazoles, imidazoles, etc. [74]. Although classical Strecker reactions have some limitations, use of trimethylsilyl cyanide (TMSCN) as a source of cyano anion provides promising and safer routes to these compounds [73b,75]. TMSCN is, however, readily hydrolyzed in the presence of water, and it is necessary to perform the reactions under strictly anhydrous conditions. BusSnCN [76], on the other hand, is stable in water and a potential source of cyano anion, and it has been found that Strecker-type reactions of aldehydes, amines, and BuaSnCN proceed smoothly in the presence of a catalytic amoimt of Sc(OTf)3 in water [77]. No surfactant was needed in this reaction. The reaction was assumed to proceed via imine formation and successive cyanation (it was confirmed that imine formation was much faster than cyanohydrin ether formation under these reaction conditions) again the dehydration process (imine formation) proceeded smoothly in water. 

The catalytic asymmetric cyanation of imines-the Strecker reaction-represents one of the most direct and viable methods for the asymmetric synthesis of a-amino... 

Discovered in the middle of the 19th century, the Strecker reaction is one of the earliest atom-economic multicomponent reactions. Amino nitriles were simply obtained from ammonia, hydrogen cyanide and an aldehyde. These products are important intermediates for the synthesis of natural and unnatural a-aminoacids. Due to the ever-increased demand for enantioenri-chied a-aminoacids, the asymmetric Strecker reaction has emerged as a viable synthetic method. Since the first report published in 1996, the catalytic enantioselective cyanation of preformed imines was intensively studied and several excellent reviews were devoted to this topic. ... 

Since the toxicity and volatility of HCN are high, these facts limit its extensive and practical application in organic synthesis. In this respect, a number of cyanating agents have been developed to avoid the use of toxic HCN, such as TMSCN [76], (Et0)2P(0)CN [77], Et AlCN [78], BUjSnCN [79], MeCOCN [80], K [Ee-(CN)g] [81], and acetone cyanohydrin [82]. Although TMSCN has been the most widely used in the Strecker reaction, this often requires a Brpnsted or Lewis acids or bases as catalysts [83]. 

However, in contrast to the relatively well-developed cyanation of aldimines, limited reports were related to the cyanation of ketoimines. In this context, Feng et al. have designed a novel Ai, A -dioxide catalyst derived from BINOL and prolinamide in order to be applied as organocatalyst for the asymmetric Strecker reaction of ketoimines with fairly wide substrate scope and excellent enantioselectivities of up to 99% ee (Scheme 3.34)." A low catalyst loading of 2 mol % combined with mild reaction conditions and an operational simplicity made this strategy facile to be used for the synthesis of pharmaceutically important chiral disubstituted a-amino nitriles. 

Asymmetric phase-transfer catalytic addition of cyanide to C=N, C=0, and C=C bonds has been recently explored, which has been demonstrated to be an efficient method toward the synthesis of a series of substituted chiral nitriles. In this context, Maraoka and coworkers disclosed an enantioselective Strecker reaction of aldimines by using aqueous KCN [140]. In this system, the chiral quaternary ammonium salts (R)-36e bearing a tetranaphthyl backbone were found to be remarkably efficient catalysts (Scheme 12.25). Subsequently, this phase-transfer-catalyzed asymmetric Strecker reaction was further elaborated by use of a-amidosulfones as precursor of N-arylsulfonyl imines. Interestingly, the reaction could be conducted with a slight excess of potassium cyanide [141] or acetone cyanohydrin [40] as cyanide source, and good to high enantioselectivities were observed. In contrast, the asymmetric phase-transfer-catalytic cyanation of aldehydes led to the cyanation products with only moderate enantioselectivity [142]. 

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