Carbonyl substrate

The reaction of tnchlorotrifluoroethane with lead in the presence of carbonyl substrates gives the 1 -chloro-2,2-difluoroethenyl carbinols, presumably via a fluo-rinated organolead intermediate [25] (equaUon 18)... 

Dimethylsulfoxonium methylide (1) is the reagent of choice for the cyclopropanation of a,p-unsaturated carbonyl substrates. The reaction is generally carried out at more elevated temperatures in comparison to that of 2, although exceptions exist. The method works for 0 ,P-unsaturated ketones, esters and amides. Representative examples are found in transformations of 2(5//)-furanone 55 to cyclopropane 56 and 0 ,P-unsaturated Weinreb amide 57 to cyclopropane 58. ... 

The reactions of various substrates under various reaction conditions cannot be rationalized by one general mechanism. Alcohols are not considered to be intermediates, since these generally are not reduced under Clemmensen conditions, as has been demonstrated with independently prepared alcohols corresponding to the carbonyl substrates. ... 

Instead of a-halo esters, related reactants can be used e.g. the a-halo derivatives of ketones, nitriles, sulfones and A,A-disubstituted amides. The Darzens condensation is also of some importance as a synthetic method because a glycidic acid can be converted into the next higher homolog of the original aldehyde, or into a branched aldehyde (e.g. 5) if the original carbonyl substrate was a ketone ... 

Grignard reagents that contain a /3-hydrogen—e.g. 15—can reduce a carbonyl substrate by transfer of that hydrogen as a side-reaction. The so-called Grignard reduction is likely to proceed via a six-membered cyclic transition state 16 the alkyl group of alkylmagnesium compound 15 is thereby converted into an alkene 17. 

Grignard reagents can react as nucleophiles with a large variety of carbonyl substrates in the following scheme the products obtained after a hydrolytic workup are shown. The scheme gives an impression of the versatility of the Grignard reaction ... 

The corresponding anion 5, formed from 2 by deprotonation, subsequently adds to the carbonyl substrate to give the aldol-type intermediate 6. Loss of water from intermediate 6 leads to a primary o ,/3-unsaturated condensation product 3 ... 

The usual procedure is to simply heat a mixture of the starting materials. A common side-reaction is the polyalkylation it can be suppressed by employing an excess of amine. In addition carbonyl substrates with a-hydrogens may undergo competitive aldol reactions the corresponding reaction products may then undergo a subsequent Leuckart-Wallach reaction. 

The initial step of the coupling reaction is the binding of the carbonyl substrate to the titanium surface, and the transfer of an electron to the carbonyl group. The carbonyl group is reduced to a radical species 3, and the titanium is oxidized. Two such ketyl radicals can dimerize to form a pinacolate-like intermediate 4, that is coordinated to titanium. Cleavage of the C—O bonds leads to formation of an alkene 2 and a titanium oxide 5 ... 

The 1,4-addition of an enolate anion 1 to an o ,/3-unsaturated carbonyl compound 2, to yield a 1,5-dicarbonyl compound 3, is a powerful method for the formation of carbon-carbon bonds, and is called the Michael reaction or Michael addition The 1,4-addition to an o ,/3-unsaturated carbonyl substrate is also called a conjugate addition. Various other 1,4-additions are known, and sometimes referred to as Michael-like additions. 

The Peterson olefination is a quite modern method in organic synthesis its mechanism is still not completely understood. " The a-silyl organometallic reagent 2 reacts with the carbonyl substrate 1 by formation of a carbon-carbon single bond to give the diastereomeric alkoxides 4a and 4b upon hydrolysis the latter are converted into /3-hydroxysilanes 5a and 5b ... 

The reaction with a carbonyl substrate 3 is similar to a Grignard reaction. Hydrolytic workup then yields the /3-hydroxy ester 4. Sometimes product 4 easily eliminates water to yield directly an o ,/3-unsaturated ester. 

The carbonyl substrate 3 to be reacted with the organozinc compound 2 can be an aldehyde or ketone that may contain additional functional groups. With a vinylogous halo ester—i.e. a y-halocrotyl ester—the corresponding y-crotylzinc derivative is formed. 

The phosphoniutn salt 7 is usually isolated, and in most cases is a crystalline material, while the ylide 1 is usually prepared in solution and used directly for reaction with the carbonyl substrate. 

The carbanionic deprotonated phosphonate thus obtained—e.g. 14—can be reacted with a carbonyl substrate 2 just like a phosphorus ylide. However... 

With respect to the carbonyl substrate, a variety of additional functional groups is tolerated, e.g. ester, ether, halogen. With compounds that contain an ester as well as a keto or aldehyde function, the latter usually reacts preferentially. Due to its mild reaction conditions the Wittig reaction is an important method for the synthesis of sensitive alkenes, as for example highly unsaturated compounds like the carotinoid 17 shown above. 

With chiral auxiliaries1,41 a remote chiral moiety is temporarily introduced into the substrate in order to direct the nucleophilic addition diastereoselectively. The chiral auxiliary can be removed from the initial addition product with complete conservation of the chirality of the desired product and also of the chiral auxiliary. The recovered chiral auxiliary can then be reused in further reactions. Therefore, chiral auxiliaries are used to chiralize an a priori achiral carbonyl substrate by the introduction of a covalently bound, but nevertheless easily removable, chiral source. 

With unsymmetrical ions, three products are possible, since either oxygen can attack. With a carbonyl substrate the ion can analogously undergo C- or O-acylation. 

Figure 1 General dehydrogenase mechanism. In this example, the A hydride of NAD(P)H is transferred to the carbonyl substrate, which is activated by interaction with a Lewis acid (LA). A proton is donated to the developing oxyanion by a general acid (HX).

When enzymes like alcohol dehydrogenase, are chiral, reduce carbonyl groups using coenzyme NADH, they discriminate between the two faces of the trigonal planar carbonyl substrate, such that a predominance of one of the two possible stereoisomeric forms of the tetrahedral product results, i) If the original reactant was chiral, the formation of the new stereocenter may result in preferential formation of one diastereomer of the product => a diastereoselectiv reaction. 

When alcohols are added to the reaction mixture, unsymmetrical ether products may be obtained. Starting with a mixture of aldehydes can also give rise to the formation of unsymmetrical ethers. These ether products are formed under conditions different from those used in the formation of ethers directly from alcohols. Thus, it is postulated that the reaction sequence that leads from the carbonyl substrate to the ether involves the intermediate formation of hemiacetals, acetals, or their protonated forms and alkoxycarbenium ions, which are intercepted and reduced to the final ether products by the organosilicon hydrides present in the reaction mix. The probable mechanistic scheme that is followed when Brpnsted acids are present is outlined in Scheme 2.311-327 328... 

Nucleophilic additions to carbonyl groups lead to alcohols which on dehydration, furnish alkenes70,71. This two-step protocol has been extremely useful for diene and polyene synthesis with wide variation in the carbonyl substrate and the nucleophilic addendum. Diene synthesis using aldol-type condensation as well as phenyl sulphonyl carbanion (the Julia reaction) are also discussed in this section. 

In addition to carbonyl substrates, imines have been used extensively with phosphorus-halogen reagents for the preparation of a variety of phosphonates and phosphinates. Combined in a reaction medium, secondary amines react with formaldehyde and phosphorus trichloride134 135 or alkyldichlorophosphines136 to produce N,N-disubstituted aminomethylphosphonates or -phosphinates. These reactions occur under mild conditions with good yield. Similarly, aliphatic carboxylic amides react with aldehydes to generate imines, which can be used in situ with diphenylchlorophosphine to produce... 

The R,S-family 33, and of course its enantiomer, provide high enantioselectiv-ities and activities for the reductions of itaconic and dehydroamino acid derivatives as well as imines [141], The JosiPhos ligands have found industrial applications for reductions of the carbon-carbon unsaturation within a,/ -unsaturated carbonyl substrates [125, 127, 131, 143-149]. In contrast, the R,R-diastereoisomerof30 does not provide high stereoselection in enantioselective hydrogenations [125, 141]. 

Carbonyl compounds including ketones, aldehydes and carboxylic acid derivatives constitute a class of carbon acids, the acidity of which falls in the pifa range of 25 to 35 in dimethylsulfoxide (DMSO). Representative values for selected carbonyl substrates are summarized in Table 2-1.1 Different methods may be invoked for generating the enolates according to the pifa value of their parent compounds. 

To generate an enolate from a carbonyl substrate, a suitable base should be chosen to meet two criteria ... 

The enolization product depends on the structure of the carbonyl substrate When //-OH is present in the carbonyl compound, (Z)-enolate is the major product due to the metal ion chelation,200 whereas (fs)-enolate is the major product in the absence of a //-OH group.22 It is worth noting that the yield is normally low for //-OH carbonyl substrates because of the tendency for //-elimination. 

Nucleophilic addition of metal alkyls to carbonyl compounds in the presence of a chiral catalyst has been one of the most extensively explored reactions in asymmetric synthesis. Various chiral amino alcohols as well as diamines with C2 symmetry have been developed as excellent chiral ligands in the enantiose-lective catalytic alkylation of aldehydes with organozincs. Although dialkylzinc compounds are inert to ordinary carbonyl substrates, certain additives can be used to enhance their reactivity. Particularly noteworthy is the finding by Oguni and Omi103 that a small amount of (S)-leucinol catalyzes the reaction of diethylzinc to form (R)-l-phenyl-1 -propanol in 49% ee. This is a case where the... 

Following their success with chiral ketone-mediated asymmetric epoxidation of unfunctionalized olefins, Zhu et al.113 further extended this chemistry to prochiral enol silyl ethers or prochiral enol esters. As the resultant compounds can easily be converted to the corresponding a-hydroxyl ketones, this method may also be regarded as a kind of a-hydroxylation method for carbonyl substrates. Thus, as shown in Scheme 4-58, the asymmetric epoxidation of enol silyl... 

See Chapdelaine, M. J. Huke, M. Tandem Vicinal Difunctionalization / -Addition to a, /MJnsaturated Carbonyl Substrates Followed by a-Functionaliza-tion in Paquette, L. A. ed. Org. React. John Willey Sons, New York, 1990, p. 38. 

In recent years, extensive attention has been focused on finding cultured plant cells that can be used as catalysts for organic functional group transformations. A number of transformations employing freely suspended or immobilized plant cell cultures have been reported.24 For example, Akakabe et al.25 report that immobilized cells of Daucus carota from carrot can be used to reduce prochiral carbonyl substrates such as keto esters, aromatic ketones, and heterocyclic ketones to the corresponding secondary alcohols in ( -configuration with enantiomeric excess of 52-99% and chemical yields of 30 63%). 

Darzens reaction, the reaction between a carbonyl compound and an a-halo ester in the presence of a base, consists of an initial aldol-type addition and a subsequent intramolecular Sn2 reaction, forming an epoxide as its final product. Its high stereoselectivity thus relies on the stereoselectivity of the nucleophilic addition of an a-halo ester onto the carbonyl substrate, which can be either an aldehyde or a ketone. 

COPPER-CATALYZED CONJUGATE ADDITION OF ORGANOMANGANESE CHLORIDES, RMnCI, TO ot.p UNSATURATED CARBONYL SUBSTRATES IN THF... 

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