Carbanions carbanion’’-type reactivity

The carbanion -type reactivity of dienamine activation can be promoted by a silyl-protected diarylprolinol catalyst in the presence of reactive electrophilic species, such as nitroolefins or diarylmethanols (Scheme 2.10) [20]. Although both direct addition (a-addition) and vinylogous addition (y-addition) are viable reaction pathways, the a-reactivity is the more typical one and usually provides better selectivities due to more effective shielding of the a-position by the aminocatalyst. Interestingly, the a-/y-selectivity of dienamine-mediated carbanion -type addition reactions seems to be strongly influenced by the substitution pattern of the enal reactant For example, it was demonstrated that y,y-disubstituted enals favor the a-addition product while y-functionaUzation is the predominant reaction pathway for y-monosubstituted enals. 

Scheme 2.10 Representative examples of carbanion -type reactivity via dienamine activation.

Over the years there have been a number of mechanistic proposals for substrate oxidation by TMADH. An early proposal considered a carbanion mechanism in which an active site base deprotonates a substrate methyl group to form a substrate carbanion [69] reduction of the flavin was then achieved by the formation of a carbanion-flavin N5 adduct, with subsequent formation of the product imine and dihydroflavin. A number of active site residues were identified as potential bases in such a reaction mechanism. Directed mutagenesis and stopped-flow kinetic studies, however, have been used to systematically eliminate the participation of these residues in a carbanion-type mechanism [76-79], thus indicating that a proton abstraction mechanism initiated by an active site residue does not occur in TMADH. Early proposals also invoked the trimethylammonium cation as the reactive species in the enzyme-substrate complex, owing to the high (9.81) of free... 

It therefore becomes possible to take advantage of this peculiar mechanism to prepare palm-tree like architectures where the C ) core bears six PS chains of the same length and an additional seventh chain of a different length or/and a different chemical nature (e.g., polyisoprene). Furthermore, as the out-growing chain bears a terminal carbanion more reactive than the five remaining on the core, it becomes possible to specifically couple two palm-trees with, for example, dibromo-p-xylene to form dumbbell type architectures where two six-arm PS stars with a fullerene core are linked together by a PS or a polyisoprene chain [97, 98]. Scheme 5.17 gives a schematic representation of these palm-tree and dumbbell architectures. 

Chapters 1 and 2. Most C—H bonds are very weakly acidic and have no tendency to ionize spontaneously to form carbanions. Reactions that involve carbanion intermediates are therefore usually carried out in the presence of a base which can generate the reactive carbanion intermediate. Base-catalyzed condensation reactions of carbonyl compounds provide many examples of this type of reaction. The reaction between acetophenone and benzaldehyde, which was considered in Section 4.2, for example, requires a basic catalyst to proceed, and the kinetics of the reaction show that the rate is proportional to the catalyst concentration. This is because the neutral acetophenone molecule is not nucleophihc and does not react with benzaldehyde. The much more nucleophilic enolate (carbanion) formed by deprotonation is the reactive nucleophile. 

Normally, reactive derivatives of sulfonic acids serve to transfer electrophilic sulfonyl groups259. The most frequently applied compounds of this type are sulfonyl halides, though they show an ambiguous reaction behavior (cf. Section III.B). This ambiguity is additionally enhanced by the structure of sulfonyl halides and by the reaction conditions in the course of electrophilic sulfonyl transfers. On the one hand, sulfonyl halides can displace halides by an addition-elimination mechanism on the other hand, as a consequence of the possibility of the formation of a carbanion a to the sulfonyl halide function, sulfenes can arise after halide elimination and show electrophilic as well as dipolarophilic properties. 

The cyclization of aryl 3-chloropropyl sulfones by potassium t-butoxide in t-butyl alcohol at 30 °C (equation 20) has a p value of 2.32 for substituents in Ar202. This is considered by Bird and Stirling to indicate the formation of an intermediate carbanion which is essentially in equilibrium with the reactants. A recent review by Stirling203 deals with structure-reactivity aspects of many sulfonyl promoted reactions of this type. 

Sulfur compounds are useful as nucleophilic acyl equivalents. The most common reagents of this type are 1,3-dithianes, which on lithiation provide a nucleophilic acyl equivalent. In dithianes an umpolung is achieved on the basis of the carbanion-stabilizing ability of the sulfur substituents. The lithio derivative is a reactive nucleophile toward alkyl halides and carbonyl compounds. 11... 

A triparametric model of the electrical effect has been introduced17 that can account for the complete range of electrical effects on chemical reactivities of closed shell species (carbenium and carbanions), that is, reactions which do not involve radical intermediates. The basis of this model was the observation that the electronic demand. On the assumption that they are generally separated by an order of magnitude in this variable it is possible to assign to each oq type a corresponding value of the electronic... 

A new stereocenter is formed when a synthon 143 with umpoled carbonyl reactivity (d reactivity) is introduced into aldehydes or imines. The enantioselective variant of this type of reaction was a longstanding problem in asymmetric synthesis. The very large majority of a-hetero-snbstitnted carbanions which serve as eqnivalents for synthons like 142 and 143 lead to racemic products with aldehydes or imines. However, enantiomerically pnre acylions and a-hydroxy carboxylic acids or aldehydes (144 and ent-144, respectively) as well as a-amino acids and aldehydes (145 and ent-145) are accessible either by nsing chiral d reagents or by reacting the components in the presence of chiral additives (Scheme 18). 

---