Nucleophilic carbon compounds

The most important general alcohol sytithcses addition of nucleophilic carbon compounds to carbonyl groups. 

An intriguing class of nucleophilic carbon compounds that resemble acyclic carbenes, referred to as carbones, has attracted increasing attention in recent... 

A major application of ion exchange in non-aqueous solvents is for the synthesis of organometallic compounds. The common methods fall into two distinct classes. In one, the reagents are electrophilic carbon compounds, such as alkyl halides, and nucleophilic metal complexes, such as carbonylmetallates. In the other, the relative polarities of the reagents are reversed and nucleophilic carbon compounds, e.g. alkyllithium reagents, and electrophilic metal complexes, such as metal halides, are employed. Both classes of reaction are ion exchange processes and typically involve the formation of a salt as the low-solubility by-product. 

The formation of the above anions ("enolate type) depend on equilibria between the carbon compounds, the base, and the solvent. To ensure a substantial concentration of the anionic synthons in solution the pA" of both the conjugated acid of the base and of the solvent must be higher than the pAT -value of the carbon compound. Alkali hydroxides in water (p/T, 16), alkoxides in the corresponding alcohols (pAT, 20), sodium amide in liquid ammonia (pATj 35), dimsyl sodium in dimethyl sulfoxide (pAT, = 35), sodium hydride, lithium amides, or lithium alkyls in ether or hydrocarbon solvents (pAT, > 40) are common combinations used in synthesis. Sometimes the bases (e.g. methoxides, amides, lithium alkyls) react as nucleophiles, in other words they do not abstract a proton, but their anion undergoes addition and substitution reactions with the carbon compound. If such is the case, sterically hindered bases are employed. A few examples are given below (H.O. House, 1972 I. Kuwajima, 1976). 

The selective intermolecular addition of two different ketones or aldehydes can sometimes be achieved without protection of the enol, because different carbonyl compounds behave differently. For example, attempts to condense acetaldehyde with benzophenone fail. Only self-condensation of acetaldehyde is observed, because the carbonyl group of benzophenone is not sufficiently electrophilic. With acetone instead of benzophenone only fi-hydroxyketones are formed in good yield, if the aldehyde is slowly added to the basic ketone solution. Aldols are not produced. This result can be generalized in the following way aldehydes have more reactive carbonyl groups than ketones, but enolates from ketones have a more nucleophilic carbon atom than enolates from aldehydes (G. Wittig, 1968). 

The nucleophilic carbon of ketomethylene compounds can react with anhydrobases of different species in a basic medium. This reaction presents a narrow similitude with -CHj attack. The resulting dye, neut-rodimethine cyanine either mesomethyl-substituted or not. varies with the nature of the anhydro base (Scheme 30) (53. 54). 

The properties of organometallic compounds are much different from those of the other classes we have studied to this point Most important many organometallic com pounds are powerful sources of nucleophilic carbon something that makes them espe cially valuable to the synthetic organic chemist For example the preparation of alkynes by the reaction of sodium acetylide with alkyl halides (Section 9 6) depends on the presence of a negatively charged nucleophilic carbon m acetylide ion... 

Unlike elimination and nucleophilic substitution reactions foimation of oigano lithium compounds does not require that the halogen be bonded to sp hybndized carbon Compounds such as vinyl halides and aiyl halides m which the halogen is bonded to sp hybndized carbon react m the same way as alkyl halides but at somewhat slowei rates... 

Secondary amines cannot form imines, and dehydration proceeds to give carbon-carbon double bonds bearing amino substituents (enamines). Enamines were mentioned in Chapter 7 as examples of nucleophilic carbon species, and their synthetic utility is discussed in Chapter 1 of Part B. The equilibrium for the reaction between secondary amines and carbonyl compounds ordinarily lies far to the left in aqueous solution, but the reaction can be driven forward by dehydration methods. 

Another important feature of the Nef reaction is the possible use of a CH-NO2 function as an umpoled carbonyl function. A proton at a carbon a to a nitro group is acidic, and can be abstracted by base. The resulting anionic species has a nucleophilic carbon, and can react at that position with electrophiles. In contrast the carbon center of a carbonyl group is electrophilic, and thus reactive towards nucleophiles. 1,4-Diketones 4 can for example be prepared from a-acidic nitro compounds by a Michael additionfNef reaction sequence " ... 

One such compound, bropirimine (112), is described as an agent which has both antineo-plastic and antiviral activity. The first step in the preparation involves formation of the dianion 108 from the half ester of malonic acid by treatment with butyllithium. Acylation of the anion with benzoyl chloride proceeds at the more nucleophilic carbon anion to give 109. This tricarbonyl compound decarboxylates on acidification to give the beta ketoester 110. Condensation with guanidine leads to the pyrimidone 111. Bromination with N-bromosuccinimide gives bropirimine (112) [24]. 

As with the reduction of carbonyl compounds discussed in the previous section, we ll defer a detailed treatment of the mechanism of Grignard reactions until Chapter 19. For the moment, it s sufficient to note that Grignard reagents act as nucleophilic carbon anions, or carbanions ( R ), and that the addition of a Grignard reagent to a carbonyl compound is analogous to the addition of hydride ion. The intermediate is an alkoxide ion, which is protonated by addition of F O"1 in a second step. 

The reaction of A-acyliminium ions with nucleophilic carbon atoms (also called cationic x-amidoalkylation) is a highly useful method for the synthesis of both nitrogen heterocycles and open-chain nitrogen compounds. A variety of carbon nucleophiles can be used, such as aromatic compounds, alkcncs, alkyncs, carbcnoids, and carbanions derived from active methylene compounds and organometallics. 

Both electrophilic and nucleophilic reagents are able to cleave the ring in cyclic germanium-carbon compounds due to the ring strain and the polarizability of the germanium-carbon bond, as illustrated in Figure 748,49. 

Although carbon and silicon both belong to the same group of periodic table and many of the silicon compounds resemble carbon compounds, but the chemical reactivity of silicon in organosilicon compounds is more comparable to that of hydrogen because many nucleophilic displacements at... 

The compound dimethylallyl diphosphate provides an excellent example of a natural product with a diphosphate leaving group that can be displaced in a nucleophilic substitution reaction. Suitable nucleophiles are hydroxyl groups, e.g. a phenol, though frequently an electron-rich nucleophilic carbon is employed. Dimethylallyl diphosphate is a precursor of many natural products that contain in their structures branched-chain C5 subunits termed isoprene units. 

The disulfide dimers of 2-aminothiophenols have also been used in the syntheses of benzothiazines. In this case, nitrogen acts as a nucleophile and sulfur as an electrophile. Reagents that have nucleophilic carbons adjacent to an electrophilic carbon can be reacted with these disulfides. Examples include a,(3-unsaturated esters that undergo conjugate addition followed by enolate addition to sulfur (Equation 86) <1983J(P1)567>, and 1,3-dicarbonyl compounds such as ethyl acetoacetate <2005AXEo2716> and dimethyl malonate <2006ARK(xv)68> (Scheme 63). 

Three-component reactions between organic electrophile (halide, ester, etc.), carbon monooxide, and organic nucleophile (organometallic compound) (Equation (1)) catalyzed by transition metal complexes afford a powerful method for the synthesis of various ketones. The pioneering works in this area appeared in the early 1980s. 

Compounds with a low HOMO and LUMO (Figure 5.5b) tend to be stable to selfreaction but are chemically reactive as Lewis acids and electrophiles. The lower the LUMO, the more reactive. Carbocations, with LUMO near a, are the most powerful acids and electrophiles, followed by boranes and some metal cations. Where the LUMO is the a of an H—X bond, the compound will be a Lowry-Bronsted acid (proton donor). A Lowry-Bronsted acid is a special case of a Lewis acid. Where the LUMO is the cr of a C—X bond, the compound will tend to be subject to nucleophilic substitution. Alkyl halides and other carbon compounds with good leaving groups are examples of this group. Where the LUMO is the n of a C=X bond, the compound will tend to be subject to nucleophilic addition. Carbonyls, imines, and nitriles exemplify this group. 

An important pyrrole synthesis, known as the Knorr synthesis, is of the cyclizative condensation type. An a -amino ketone furnishes a nucleophilic nitrogen and an electrophilic carbonyl, while the second component, a /3-keto ester or similar /3-dicarbonyl compound, furnishes an electrophilic carbonyl and a nucleophilic carbon. The initial combination involves enamine formation between the primary amine and the dicarbonyl compound. Subsequent cyclization occurs as a result of the nucleophilic jg-carbon of the enamine adding to the electrophilic carbonyl group of the a-amino ketone (equation 76). Since a-amino... 

In Chapter 12 and in the preceding sections of this chapter we examined displacement and addition reactions involving nucleophilic centers on O, N, or S. Bonds from carbon to these atoms can usually be broken easily by acidic or basic catalysis. The breaking and making of C-C bonds does not occur as readily and the "carbon skeletons" of organic molecules often stick together tenaciously. Yet living cells must both form and destroy the many complex, branched carbon compounds found within them. 

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