Ketones primary amine addition

Addition of amines to aldehydes/ketones primary amine -1- mesityl oxide = acetone -1- imine separation of primary amine from secondary amines as the later has no reactivity for mesityl oxide imine can be hydrolysed back to primary [83]... 

Whereas secondary amines are suitable catalysts for activation of a,(3-unsaturated aldehydes, more difficulties are usually encountered with sterically demanding substrates, such as a,(5-unsaturated ketones. Primary amines can be useful catalysts in such cases. Yoshida et al. [52] reported an amino acid-catalyzed sulfa-Michael addition of arylmethyl mercaptans to cyclic enones. The proposed mechanism invokes the formation of an imine intermediate. However, even with the best screened catalyst, 5-trityl L-cysteine, the reaction proceeded with modest levels of enantioselectivity (8-58% ee). 

A number of compounds of the general type H2NZ react with aldehydes and ketones m a manner analogous to that of primary amines The carbonyl group (C=0) IS converted to C=NZ and a molecule of water is formed Table 17 4 presents exam pies of some of these reactions The mechanism by which each proceeds is similar to the nucleophilic addition-elimination mechanism described for the reaction of primary amines with aldehydes and ketones... 

Primary amines undergo nucleo philic addition to the carbonyl group of aldehydes and ketones to form carbinol amines These carbinolamines dehydrate under the conditions of their formation to give N substituted imines Secondary amines yield enamines... 

Imines are formed by nucleophilic addition of a primary amine to the carbonyl group of an al dehyde or a ketone The key step is formation of a carbinolamine intermedi ate which then dehy drates to the imine... 

The reaction of disubstituted diacetylenes with hydrazine hydrate was reported by Darbinyan et al. (70AKZ640). In the first stage the addition of hydrazine to the terminal carbon atom of the diacetylene system is analogous to that of primary amines to diacetylene (69ZC108 69ZC110). With monosubstituted diacetylenes (R = H), hydrazine adds to the terminal triple bond. This leads to the formation of vinylacetylenic hydrazine 22 which cyclizes to dihydropyrazole 23 subjected to further isomerization to the pyrazole 25. It is possible that hydrazine 22 undergoes hydration to the ketone 24 which can easily be cyclized to the pyrazole 25... 

Formation of C—Nu The second mode of nucleophilic addition, which often occurs with amine nucleophiles, involves elimination of oxygen and formation of a C=Nu bond. For example, aldehydes and ketones react with primary amines, RNH2, to form imines, R2C=NR. These reactions proceed through exactly the same kind of tetrahedral intermediate as that formed during hydride reduction and Grignard reaction, but the initially formed alkoxide ion is not isolated. Instead, it is protonated and then loses water to form an imine, as shown in Figure 3. 

Nitriles are similar in some respects to carboxylic acids and are prepared either by SN2 reaction of an alkyl halide with cyanide ion or by dehydration of an amide. Nitriles undergo nucleophilic addition to the polar C=N bond in the same way that carbonyl compounds do. The most important reactions of nitriles are their hydrolysis to carboxylic acids, reduction to primary amines, and reaction with organometallic reagents to yield ketones. 

The DKR processes for secondary alcohols and primary amines can be slightly modified for applications in the asymmetric transformations of ketones, enol esters, and ketoximes. The key point here is that racemization catalysts used in the DKR can also catalyze the hydrogenation of ketones, enol esters, and ketoximes. Thus, the DKR procedures need a reducing agent as additional additive to enable asymmetric transformations. 

In addition, interest in combinatorial chemical applications led a team at AMGEN to the recognition of a related but different pathway which afforded tetrahydro tetrazolo[l,5-zz]pyrazine-6-ones 121 (Scheme 22) <2000TL8729>. In this procedure, three starting components, that is, the ketone, the primary amine, and trimethylsilyl azide, as in the previous method, were used, and the fourth component was methyl isocyanoacetate. This reaction also took place under relatively smooth conditions (methanolic solution at room temperature for 6h followed by reflux for 24 h) to yield the products 121 in good to high yields. The reaction obviously proceeds by the formation of intermediate 120. 

Addition of RMgBr to nitriles. Grignard reagents react with nitriles slowly if at all, but even r-butylmagnesium chloride will add to nitriles in refluxing THF when catalyzed by a copper(I) salt. The adduct can be converted to a ketimine by anhydrous protonation, to a primary amine by reduction (Li/NH,), or to a ketone by hydrolysis. The actual reagent may be a cuprate such as R3Cu(MgX)2. 

Several trivial but highly useful reactions are known to convert one acceptor-substituted allene into another. For example, the transformation of allenic carboxylic acids is possible both via the corresponding 2,3-allenoyl chlorides or directly to 2,3-allen-amides [182,185], Allenylimines were prepared by condensation of allenyl aldehydes with primary amines [199]. However, the analogous reaction of allenyl ketones fails because in this case the nucleophilic addition to the central carbon atom of the allenic unit predominates (cf. Section 7.3.1). Allenyl sulfoxides can be oxidized by m-CPBA to give nearly quantitatively the corresponding allenyl sulfones [200]. The reaction of the ketone 144 with bromine yields first a 2 1 mixture of the addition product 145 and the allene 146, respectively (Scheme 7.24). By use of triethylamine, the unitary product 146 is obtained [59]. The allenylphosphane oxides and allene-... 

Complexation of [Cp IrCl2]2 with iV-heterocyclic carbenes has led to complexes such as 25, developed by Peris and coworkers [107, 108], and 133, developed by Crabtree and coworkers [12]. Complex 24 is activated by the addition of silver triflate and is effective for the iV-alkylation of amines with alcohols and for the iV-alkylation of anilines with primary amines. Complex 25 has also been shown to couple benzyl alcohol 15 with a range of alcohols, including ethanol 134, to give ether products such as ether 135 (Scheme 31). Complex 133 was an active hydrogen transfer catalyst for the reduction of ketones and imines, using 2-propanol as the hydrogen source. It was also an effective catalyst for the iV-alkylation of amines... 

The addition of primary amines to the carbonyl group of aldehydes and ketones is generally followed by elimination of water (dehydration), and the product is called an imine or Schiff base. 

The Tsogoeva group, in 2006, reported the introduction of newly designed bifunctional secondary amine-functionalized proline-based thioureas (95 and 96) and the primary amine-functionalized thioureas (97-99) for catalysis of the asymmetric addition of ketones to trans-P-nitrostyrenes (Figure 6.30) [260, 261]. Using... 

Scheme 6.102 Bifunctional catalysis with primary amine thiourea 99 Proposed transition states to explain the onfi-diastereoselectivity (A) and the syn- diastereoselectivity (B) of the Michael addition of both acylic and cyclic ketones to frans-P-nitrostyrene.

Chiral sulfinimines 236 are very useful intermediates for the preparation of enantiomer-ically pure primary amines 237 (equation 158) . This reaction has been applied to the synthesis of a-amino acids . For sulfinimines obtained from simple ketones, lithium reagents are preferable for the addition , while for cyclic ketones organomagnesium compounds gave the best results. Addition of alkyl and aryl Grignard compounds to sulfinimines, derived from 3- and 4-substituted cyclohexanones, proceeds with excellent diastereoselectivity, depending on the stereochemistry of the ring substituents rather than the sulfinyl group . 

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