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Lithium, enolates, formation

Wu and co-workers (Wu et al., 1999) have demonstrated a novel chiral lactone enolate-imine process to access 2-azetidinone diols such as 35 (Scheme 13.10). Treatment of 34 with LDA at — 25°C in THF followed by addition of imine 3, afforded only trace product. Addition of HMPA or the less toxic DMPU during the lithium enolate formation step improved the yield and the trans cis diastereoselectivity ( 90 10). Recrystallization improved the purity to >95 5 trans cis 2-azetidinone. Addition of an equivalent of lithium bromide accelerates the rate of ring closure, presumably by destabilizing the intermediate lithium aggregates. Side-chain manipulation of 35 was accomplished by sodium... [Pg.194]

Silyl ketene acetals from esters.1 Ireland has examined various factors in the enolization and silylation of ethyl propionate (1) as a model system. As expected from previous work (6, 276-277), use of LDA (1 equiv.) in THF at —78 -+ 25° results mainly in (E)-2, formed from the (Z)-enolate. The stereoselectivity is markedly affected by the solvent. Addition of TMEDA results in a 60 40 ratio of (Z)- and (E)-2 and lowers the yield significantly. Use of THF/23% HMPA provides (Z)- and (E)-2 in the ratio of 85 15 with no decrease in yield. This system has been widely used for (E)-selective lithium enolate formation from esters and ketones. Highest stereoselectivity is observed by addition of DMPU, recently introduced as a noncar-... [Pg.146]

Lithium enolates, formation, 52,109 preparation and alkylation, 52, 39 reaction with diethyl phosphoro-chloridate, 52,109... [Pg.74]

Interactive mechanism for lithium enolate formation with LDA... [Pg.466]

In a similar way, the lithium enolate derived from (2f ,55)-2-tert-butyl-5-methyl-l,3-thioxolan-4-one leads to the predominant formation of one diastereomer when treated with cyclo-hexenone. The diastereomeric ratio is 75 25 (main product/sum of the other stereoisomers)114. [Pg.511]

The lithium enolate 2a (M = Li ) prepared from the iron propanoyl complex 1 reacts with symmetrical ketones to produce the diastercomers 3 and 4 with moderate selectivity for diastereomer 3. The yields of the aldol adducts are poor deprotonation of the substrate ketone is reported to be the dominant reaction pathway45. However, transmetalation of the lithium enolate 2a by treatment with one equivalent of copper cyanide at —40 C generates the copper enolate 2b (M = Cu ) which reacts with symmetrical ketones at — 78 °C to selectively produce diastereomer 3 in good yield. Diastereomeric ratios in excess of 92 8 are reported with efficient stereoselection requiring the addition of exactly one equivalent of copper cyanide at the transmetalation step45. Small amounts of triphcnylphosphane, a common trace impurity remaining from the preparation of these iron-acyl complexes, appear to suppress formation of the copper enolate. Thus, the starting iron complex must be carefully purified. [Pg.541]

When chiral enolates or chiral Michael acceptors are used, for instance, when stereogenic centers are present in the substrate or when X or Y are chiral auxiliaries, both simple and induced diastereoselectivity is observed. This results, in principle, in the formation of four diastereomers 1 -4. The diastereoselectivity in the Michael addition of lithium enolates to enones can be rationalized by consideration of chelated transition states A-D372. [Pg.954]

As an alternative to lithium enolates. silyl enolates or ketene acetals may be used in a complementary route to pentanedioates. The reaction requires Lewis acid catalysis, for example aluminum trifluoromethanesulfonate (modest diastereoselectivity with unsaturated esters)72 74 antimony(V) chloride/tin(II) trifluoromethanesulfonate (predominant formation of anti-adducts with the more reactive a,/5-unsaturated thioesters)75 montmorillonite clay (modest to good yields but poor diastereoselectivity with unsaturated esters)76 or high pressure77. [Pg.961]

Another example of a [4S+1C] cycloaddition process is found in the reaction of alkenylcarbene complexes and lithium enolates derived from alkynyl methyl ketones. In Sect. 2.6.4.9 it was described how, in general, lithium enolates react with alkenylcarbene complexes to produce [3C+2S] cycloadducts. However, when the reaction is performed using lithium enolates derived from alkynyl methyl ketones and the temperature is raised to 65 °C, a new formal [4s+lcj cy-clopentenone derivative is formed [79] (Scheme 38). The mechanism proposed for this transformation supposes the formation of the [3C+2S] cycloadducts as depicted in Scheme 32 (see Sect. 2.6.4.9). This intermediate evolves through a retro-aldol-type reaction followed by an intramolecular Michael addition of the allyllithium to the ynone moiety to give the final cyclopentenone derivatives after hydrolysis. The role of the pentacarbonyltungsten fragment seems to be crucial for the outcome of this reaction, as experiments carried out with isolated intermediates in the absence of tungsten complexes do not afford the [4S+1C] cycloadducts (Scheme 38). [Pg.87]

Lithium enolates of carboxylic acids such as phenylacetic acid or of amides such as N-methyl-N-phenylvaleric acid amide 1974 are oxidized by BTSP 1949 to a-hydroxy acids, which are isolated after esterification, e.g., to 1973, or to a-hydroxyamides such as 1975 [155] (Scheme 12.43) (cf. also the formation of 3-hydroxybutyrolactam 1962). [Pg.287]

It is also possible to achieve enantioselective enolate formation by using chiral bases. Enantioselective deprotonation requires discrimination between two enantiotopic hydrogens, such as in d.v-2,6-dimethylcyclohexanone or 4-(/-butyl)cyclohcxanonc. Among the bases that have been studied are chiral lithium amides such as A to D.22... [Pg.13]

Ester enolates are somewhat less stable than ketone enolates because of the potential for elimination of alkoxide. The sodium and potassium enolates are rather unstable, but Rathke and co-workers found that the lithium enolates can be generated at -78° C.69 Alkylations of simple esters require a strong base because relatively weak bases such as alkoxides promote condensation reactions (see Section 2.3.1). The successful formation of ester enolates typically involves an amide base, usually LDA or LiHDMS, at low temperature.70 The resulting enolates can be successfully alkylated with alkyl bromides or iodides. HMPA is sometimes added to accelerate the alkylation reaction. [Pg.31]

The stereochemistry of the silyl ketene acetal can be controlled by the conditions of preparation. The base that is usually used for enolate formation is lithium diisopropyl-amide (LDA). If the enolate is prepared in pure THF, the F-enolate is generated and this stereochemistry is maintained in the silyl derivative. The preferential formation of the F-enolate can be explained in terms of a cyclic TS in which the proton is abstracted from the stereoelectronically preferred orientation perpendicular to the carbonyl plane. The carboxy substituent is oriented away from the alkyl groups on the amide base. [Pg.568]

In the presence of zinc chloride, stereoselective aldol reactions can be carried out. The aldol reaction with the lithium enolate of /-butyl malonate and various a-alkoxy aldehydes gave anti-l,2-diols in high yields, and 2-trityloxypropanal yielded the syn-l,2-diol under the same conditions.633 Stoichiometric amounts of zinc chloride contribute to the formation of aminoni-tropyridines by direct amination of nitropyridines with methoxyamine under basic conditions.634 Zinc chloride can also be used as a radical initiator.635... [Pg.1202]

Palladium-catalyzed bis-silylation of methyl vinyl ketone proceeds in a 1,4-fashion, leading to the formation of a silyl enol ether (Equation (47)).121 1,4-Bis-silylation of a wide variety of enones bearing /3-substituents has become possible by the use of unsymmetrical disilanes, such as 1,1-dichloro-l-phenyltrimethyldisilane and 1,1,1-trichloro-trimethyldisilane (Scheme 28).129 The trimethylsilyl enol ethers obtained by the 1,4-bis-silylation are treated with methyllithium, generating lithium enolates, which in turn are reacted with electrophiles. The a-substituted-/3-silyl ketones, thus obtained, are subjected to Tamao oxidation conditions, leading to the formation of /3-hydroxy ketones. This 1,4-bis-silylation reaction has been extended to the asymmetric synthesis of optically active /3-hydroxy ketones (Scheme 29).130 The key to the success of the asymmetric bis-silylation is to use BINAP as the chiral ligand on palladium. Enantiomeric excesses ranging from 74% to 92% have been attained in the 1,4-bis-silylation. [Pg.745]

The study of Fuji et al. shows that the addition of lithium enolate 75 to ni-troamine 74 is readily reversible quenching conditions are thus essential for getting a good yield of product 76. An equilibrium mixture of the adducts exists in the reaction mixture, and the elimination of either the prolinol or lactone moiety can take place depending on the workup condition (Scheme 2-34). A feature of this asymmetric synthesis is the direct one pot formation of the enantiomer with a high ee value. One application of this reaction is the asymmetric synthesis of a key intermediate for indole type Aspidosperma and Hun-teria alkaloids.68 Fuji69 has reviewed the asymmetric creation of quaternary carbon atoms. [Pg.101]

Studies show that the Zr-bearing bulky ligand is exclusively located in the bottom hemisphere with respect to the plane of the (Z)-enolate. The aldehyde molecule coordinates with the Zr atom and approaches from the same side, adopting a chair-like transition state. This leads to the formation of erythro-aldols (Scheme 3-9 and 23). For lithium enolate, the attack of alkyl or acyl halides in alkylation or acylation occurs directly on the top face of the enolate. [Pg.142]

The addition of carbonyl compounds towards lithiated 1-siloxy-substituted allenes does not proceed in the manner described above for alkoxyallenes. Tius and co-work-ers found that treatment of 1-siloxy-substituted allene 67 with tert-butyllithium and subsequent addition of aldehydes or ketones led to the formation of ,/i-unsaturated acyl silanes 70 (Scheme 8.19) [66]. This simple and convenient method starts with the usual lithiation of allene 67 at C-l but is followed by a migration of the silyl group from oxygen to C-l, thus forming the lithium enolate 69, which finally adds to the carbonyl species. Transmetalation of the lithiated intermediate 69 to the corresponding zinc enolate provided better access to acylsilanes derived from enolizable aldehydes. For reactions of 69 with ketones, transmetalation to a magnesium species seems to afford optimal results. [Pg.436]

In contrast to these transformations, Michael additions of simple enolates to acceptor-substituted dienes often yield mixtures of 1,4- and 1,6-addition products27-30. For example, a 70 30 mixture of 1,4- and 1,6-adducts was isolated from the reaction of the lithium enolate of methyl propionate with methyl sorbate30. This problem can be solved by using the corresponding silyl ketene acetal in the presence of clay montmorillonite as acidic promoter under these conditions, almost exclusive formation of the 1,4-addition product (syn/anti mixture) was observed (equation ll)30. Highly regioselective 1,4-additions... [Pg.650]

Three tactical approaches were surveyed in the evolution of our program. As outlined in Scheme 2.7, initially the aldol reaction (Path A) was performed direcdy between aldehyde 63 and the dianion derived from tricarbonyl 58. In this way, it was indeed possible to generate the Z-lithium enolate of 58 as shown in Scheme 2.7 which underwent successful aldol condensation. However, the resultant C7 P-hydroxyl functionality tended to cyclize to the C3 carbonyl group, thereby affording a rather unmanageable mixture of hydroxy ketone 59a and lactol 59b products. Lac-tol formation could be reversed following treatment of the crude aldol product under the conditions shown (Scheme 2.7) however, under these conditions an inseparable 4 1 mixture of diastereomeric products, 60 (a or b) 61 (a or b) [30], was obtained. This avenue was further impeded when it became apparent that neither the acetate nor TES groups were compatible with the remainder of the synthesis. [Pg.19]


See other pages where Lithium, enolates, formation is mentioned: [Pg.131]    [Pg.655]    [Pg.655]    [Pg.288]    [Pg.113]    [Pg.115]    [Pg.588]    [Pg.625]    [Pg.967]    [Pg.131]    [Pg.655]    [Pg.655]    [Pg.288]    [Pg.113]    [Pg.115]    [Pg.588]    [Pg.625]    [Pg.967]    [Pg.903]    [Pg.246]    [Pg.903]    [Pg.241]    [Pg.650]    [Pg.108]    [Pg.113]    [Pg.66]    [Pg.6]    [Pg.43]    [Pg.168]   
See also in sourсe #XX -- [ Pg.52 , Pg.109 ]

See also in sourсe #XX -- [ Pg.52 , Pg.109 ]

See also in sourсe #XX -- [ Pg.52 , Pg.109 ]




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Enol formation

Enolate formation

Enolate lithium

Enolates formation

Enolates lithium

Ester Lithium enolate formation

Lithium 2,2,6,6-tetramethylpiperidide enolate formation

Lithium diisopropylamide enolate formation with

Lithium formate

Lithium formation

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