Imine anions directed

Imines derived from benzylamine and a,3-unsaturated ketones which represent 1-azadiene systems can be isomerized to the corresponding 2-azadienes with potassium t-butoxide. Addition of r-butyl-lithium occurs smoothly to afford simple imine anions that undergo alkylation in the usual fashion. 3S The two examples provided in Scheme 17 illustrate the power of this method to provide either a,a- or a,a -substitution. On the other hand, reaction of similar 1-azadiene systems with Grignard reagents results in addition to form the imine anion directly (equation 44). This example represents one of the early contributions to asymmetric induction in this area and will be elaborated in Section 4.1.3.5. 

Ornithine decarboxylase is a pyridoxal dependent enzyme. In its catalytic cycle, it normally converts ornithine (7) to putrisine by decarboxylation. If it starts the process with eflornithine instead, the key imine anion (11) produced by decarboxylation can either alkylate the enzyme directly by displacement of either fluorine atom or it can eject a fluorine atom to produce viny-logue 12 which can alkylate the enzyme by conjugate addidon. In either case, 13 results in which the active site of the enzyme is alkylated and unable to continue processing substrate. The net result is a downturn in the synthesis of cellular polyamine production and a decrease in growth rate. Eflornithine is described as being useful in the treatment of benign prostatic hyperplasia, as an antiprotozoal or an antineoplastic substance [3,4]. 

Further information concerning the stereochemical properties of the rearrangement were evaluated by submitting rigid cyclohexane derivatives 254/255 to the reaction conditions. In 1975, House described the allylation of a cyclohexyl cyanide 248 [53]. The initial deprotonation with LDA led to a ketene imine anion 249, which was then treated with allyl bromide. Two potential paths rationalized the outcome an AT-allylation generated the intermediate ketene imines 250/251, which underwent aza-Claisen rearrangement to deliver the nitriles 252/253 alternatively, the direct C-allylation of249 produced the nitriles. 

Classically, the acylzirconocene chlorides can be converted into aldehydes, carboxyhc acids, esters, and acyl halides. Recently, the usefulness of acylzirconocenes has been extended. In fact, these unmasked acyl anions directly add to aldehydes and imines affording a-hydroxy or a-amino ketones, respectively. The reaction of acylzirconocene chlorides with imines also proceeds under Bronsted acid-catalyzed conditions, even with aqneons acids. ... 

The application of hydrazone and oxime anions for carbon-carbon bond formation generally offers no advantages to the use of imine anions and, significantly, the hydrolysis of the hydrazone or oxime products to form the product carbonyl group is substantially more difficult than is the cleavage of an imine. The notable exception is in the area of asymmetric induction where powerful direction has been obtained with chiral hydrazone anions. This area has been explored fully by Enders following initial observations of Enders and Corey.2 Enders has recently reviewed these contributions. ... 

It is worth noting that this process could in principle lead to dynamic combinatorial libraries of products since the type of bond that brings together the different components in the reaction is a reversible one (namely imine formation). In fact, the initial mixture of products observed by the authors has been postulated to be a mixture of different-sized macrocycles and linear species (from which one of them is amplified upon addition of terephthalate). More detailed studies would be needed to determine whether this system indeed leads to the formation of a DCL of receptors (see Sect. 4 for examples of anion-directed DCLs). 

Aldehydes and ketones are useM building blocks in organic synthesis. The direct a-C-H substitutions of carbonyl compounds are well known. However, selective P-C(sp )-H functionalization remains rare. The MacMillan group introduced Site activation model by dual aminocatalysis and photocatalysis, opening up a practical synthetic route to P-substituted aldehydes and ketones (Scheme 3.25). With this novel strategy, radical-radical coupling of enaminyl radical with electron-poor cyanobenzene radical anion can elegantly produce P-aiylated aldehydes and ketones [74]. A recombination of enaminyl radical with imine anion radical was also developed [75]. In the presence of Michael acceptors, radical addition of enaminyl radical to electron-deficient alkenes affords P-alkylated aldehydes [76]. 

The reductive couphng of imines can follow different pathways, depending on the nature of the one-electron reducing agent (cathode, metal, low-valent metal salt), the presence of a protic or electrophihc reagent, and the experimental conditions (Scheme 2). Starting from the imine 7, the one-electron reduction is facihtated by the preliminary formation of the iminiiim ion 8 by protonation or reaction with an electrophile, e.g., trimethylsilyl (TMS) chloride. Alternatively, the radical anion 9 is first formed by direct reduction of the imine 7, followed by protonation or reaction with the electrophile, so giving the same intermediate a-amino radical 10. The 1,2-diamine 11 can be formed from the radical 10 by dimerization (and subsequent removal of the electrophile) or addition to the iminium ion 8, followed by one-electron reduction of the so formed aminyl radical. In certain cases/conditions the radical 9 can be further reduced to the carbanion 12, which then attacks the... 

Reduction of nitrostyrene with aqueous TiCl3 gives a 3,4-diarypyrrole directly in moderate yield (Eq. 10.46).52 The reaction proceeds via dimerization of anion radicals of nitrostyrene and reduction of the nitro function in the dimer to imines. Reduction of dinitrile with diisobutylalu-minum hydride (DIBAL) gives a-free pyrroles (Eq. 10.47) 53 both reactions may proceed in a similar mechanism. These pyrroles are useful intermediates for functionalized porphyrins. 

Although the reactivity of acylzirconocene chlorides towards imine derivatives under Yb(OTf)3/TMSOTf (20 mol%, l l)-catalyzed conditions is not necessarily very high, the direct access to a-amino ketone derivatives indicates the usefulness of acylzirconocene chlorides as unmasked acyl anion donors. 

Alternatively, the rhodium dimer 30 may be cleaved by an amine nucleophile to give 34. Since amine-rhodium complexes are known to be stable, this interaction may sequester the catalyst from the productive catalytic cycle. Amine-rhodium complexes are also known to undergo a-oxidation to give hydridorhodium imine complexes 35, which may also be a source of catalyst poisoning. However, in the presence of protic and halide additives, the amine-rhodium complex 34 could react to give the dihalorhodate complex 36. This could occur by associative nucleophilic displacement of the amine by a halide anion. Dihalorhodate 36 could then reform the dimeric complex 30 by reaction with another rhodium monomer, or go on to react directly with another substrate molecule with loss of one of the halide ligands. It is important to note that the dihalorhodate 36 may become a new resting state for the catalyst under these conditions, in addition to or in place of the dimeric complex. 

Sargeson and his coworkers have developed an area of cobalt(III) coordination chemistry which has enabled the synthesis of complicated multidentate ligands directly around the metal. The basis for all of this chemistry is the high stability of cobalt(III) ammine complexes towards dissociation. Consequently, a coordinated ammonia molecule can be deprotonated with base to produce a coordinated amine anion (or amide anion) which functions as a powerful nucleophile. Such a species can attack carbonyl groups, either in intramolecular or intermolecular processes. Similar reactions can be performed by coordinated primary or secondary amines after deprotonation. The resulting imines coordinated to cobalt(III) show unusually high stability towards hydrolysis, but are reactive towards carbon nucleophiles. While the cobalt(III) ion produces some iminium character, it occupies the normal site of protonation and is attached to the nitrogen atom by a kinetically inert bond, and thus resists hydrolysis. 

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