Bases Lithium diisopropylamide

Metallation of 3,4-dimethyl-l,2,5-thiadiazole (55) to the anion (56) was accomplished with the use of a nonnucleophilic base, lithium diisopropylamide <82JHC1247>. Nucleophilic attack at sulfur resulted in an alkyllithium reagent <70CJC2006>. The lithiomethyl derivative (56) was carboxylated to (57) with carbon dioxide and converted to the vinyl derivative (58) via an esterification, reduction, mesylation, and base elimination sequence (Scheme 12). 

This important synthetic problem has been satisfactorily solved with the introduction of lithium dialkylamide bases. Lithium diisopropylamide (LDA, Creger s base ) has already been mentioned for the a-alkylation of acids by means of their dianions1. This method has been further improved through the use of hexamethylphosphoric triamide (HMPA)2 and then extended to the a-alkylation of esters3. Generally, LDA became the most widely used base for the preparation of lactone enolates. In some cases lithium amides of other secondary amines like cyclo-hexylisopropylamine, diethylamine or hexamethyldisilazane have been used. The sodium or potassium salts of the latter have also been used but only as exceptions (vide infra). Other methods for the preparation of y-Iactone enolates. e.g., in a tetrahydrofuran solution of potassium, containing K anions and K+ cations complexed by 18-crown-6, and their alkylation have been successfully demonstrated (yields 80 95 %)4 but they probably cannot compete with the simplicity and proven reliability of the lithium amide method. 

In a different type of procedure, 2 + 3 cycloadditions are performed with ally lie anions. Such reactions are called 1,3-anionic cycloadditions.915 For example, a-methylstyrene adds to stilbene on treatment with the strong base lithium diisopropylamide.916... 

Synthesis routes used in the work involved condensation of l-benzyl-4-piperidone with an appropriately substituted propionamide promoted by a strong base (lithium diisopropylamide, LDI), with subsequent alkylation of anilino nitrogen (if necessary) and replacement of N-benzyl by the 2-arylethyl substituent. Direct use of the N-arylethyl-4-piperidone was also made. 

Lithium enolates of uusymmetrical ketones. House et al. find that the less highly substituted lithium enolates of unsyinmetrical ketones are best obtained by kinetically controlled deprotonation of the ketone with the hindered base lithium diisopropylamide. Thus treatment of 1 -decalonc (1) with 1.03 eq. of the base in 1,2-dimethoxyethane for 10 min, gives predominantly the lithium enolate (2) alkylation of the mixture with a... 

The use of other mixed reagents to promote acylation and subsequent enolization of the ketone during its formation have been reported by Fehr. The success of the method depends on the ease of ketone deprotonation and thus was limited to substituted allylic nucleophiles. The final product was obtained entirely in the form of the a. -unsaturated ketone. A combination of the nucleophilic Grignard reagent and the nonnucleophilic base lithium diisopropylamide converts sterically hinder ester (50) into a-damas-cone (52) via (51) (Scheme 16). The ratio of ketone to tertiary alcohol was 98 2 (many cases gave selectivity greater than 9 1) however, a few examples showed a substantial amount of tertiary alcohol formation. 

Alkylation a to a cyclopropane ring has also been achieved using activation by the triphenyl-phosphonio and diphenylphosphoryl groups and an aromatic function attached to a carbon atom a to the ring. Reaction of these compounds with a strong base (lithium diisopropylamide or phenyllithium) resulted in anion formation, the anions were treated with benzophenone, iodomethane, and methyl chloroformate, e.g. reaction of 5 with aceto-phenone. ... 

Introduction. Potassium f-butoxide is intermediate in power among the bases which are commonly employed in modem organic synthesis. It is a stronger base than the alkali metal hydroxides and primary and secondary alkali metal alkoxides, but it is a weaker base than the alkali metal amides and their alkyl derivatives, e.g. the versatile strong base Lithium Diisopropylamide. ... 

The conjugate acid of butyllithium is butane. Butane has a pK > 40, so it is a much weaker acid than diisopropyl amine with a pK of about 25. If butane is a much weaker acid than diisopropyl amine, for the reaction will be large (equilibrium is pushed to the right), facilitating the deprotonation reaction of the amine to give the conjugate base, lithium diisopropylamide. 

A similar route was used by us to synthesize pincer complexes with the monoanionic CNC ligand 5 (bimca, l,8-bis(imidazolin-2-yliden-l-yl)carbazolide). Three equivalents of the base (lithium diisopropylamide (LDA), MeLi) are necessary to obtain the in situ formed Li(bimca) complex 23 (Scheme 9.2). Salt metathesis and ligand exchange with [Rh(CO)2(p-Cl)]2 afforded the Rh(CO)(bimca) complex 24 in good yields. 

In practice, the strong base lithium diisopropylamide [LiN(i-C3H7)2 abbreviated LDA] is commonly used for making enolate ions. As the lithium salt of the weak acid diisopropylamine, pl a = 36, LDA can readily deprotonate most carbonyl compounds. It is easily prepared by reaction of butyllithium with diisopropylamine and is soluble in organic solvents because of its two alkyl groups. 

Lithium diisopropylamide is a strong enough base to abstract a proton from the a carbon atom of an ester but because it is so sterically hindered it does not add readily to the carbonyl group To illustrate... 

Section 21 10 It is possible to generate ester enolates by deprotonation provided that the base used is very strong Lithium diisopropylamide (LDA) is often used for this purpose It also converts ketones quantitatively to their enolates... 

Many organic syntheses requHe the use of stericaHy hindered and less nucleophilic bases than //-butyUithium. Lithium diisopropylamide (LDA) and lithium hexamethyldisilazide (LHS) are often used (140—142). Both compounds are soluble in a wide variety of aprotic solvents. Presence of a Lewis base, most commonly tetrahydrofuran, is requHed for LDA solubdity in hydrocarbons. A 30% solution of LHS can be prepared in hexane. Although these compounds may be prepared by reaction of the amine with //-butyUithium in the approprite medium just prior to use, they are also available commercially in hydrocarbon or mixed hydrocarbon—THF solvents as 1.0—2.0 M solutions. 

Although less researched than the 2-position, modifications at the 6-position of intact penems have been reported. Generation of the dianion of the penem (52, R = CH ) using a strong base such as / -butyUithium or lithium diisopropylamide, followed by reaction with electrophiles yields 6-substituted 2-methylpenems in moderate yield (128). The enhanced acidity of the 6-proton in the bromopenem (88) [114409-16-4] h.a.s been exploited to prepare the... 

The reaction of 3,5-diphenyl-2-isoxazoline with lithium diisopropylamide produced with 2 equivalents of base a chalcone oxime, while in the presence of 1 equivalent and an alkyl iodide, ring alkylation occurred at the 4-position of the nucleus (Scheme 48) (80LA80, 78TL3129). 

Because carbonyl compounds are only weakly acidic, a strong base is needed for enolate ion formation. If an alkoxide such as sodium ethoxide is used as base, deprotonation takes place only to the extent of about 0. l% because acetone is a weaker acid than ethanol (pKa - 16). If, however, a more powerful base such as sodium hydride (NaH) or lithium diisopropylamide ILiNO -CjHy ] is used, a carbonyl compound can be completely converted into its enolate ion. Lithium diisopropylamide (LDA), which is easily prepared by reaction of the strong base butyllithium with diisopropylamine, is widely used in the laboratory as a base for preparing enolate ions from carbonyl compounds. 

Alpha hydrogen atoms of carbonyl compounds are weakly acidic and can be removed by strong bases, such as lithium diisopropylamide (LDA), to yield nucleophilic enolate ions. The most important reaction of enolate ions is their Sn2 alkylation with alkyl halides. The malonic ester synthesis converts an alkyl halide into a carboxylic acid with the addition of two carbon atoms. Similarly, the acetoacetic ester synthesis converts an alkyl halide into a methyl ketone. In addition, many carbonyl compounds, including ketones, esters, and nitriles, can be directly alkylated by treatment with LDA and an alkyl halide. 

There is no simple answer to this question, but the exact experimental conditions usually have much to do with the result. Alpha-substitution reactions require a full equivalent of strong base and are normally carried out so that the carbonyl compound is rapidly and completely converted into its enolate ion at a low temperature. An electrophile is then added rapidly to ensure that the reactive enolate ion is quenched quickly. In a ketone alkylation reaction, for instance, we might use 1 equivalent of lithium diisopropylamide (LDA) in lelrahydrofuran solution at -78 °C. Rapid and complete generation of the ketone enolate ion would occur, and no unreacled ketone would be left so that no condensation reaction could take place. We would then immediately add an alkyl halide to complete the alkylation reaction. 

In addition to their behavior as bases, primary and secondary amines can also act as very weak acids because an N-H proton can be removed by a sufficiently strong base. We ve seen, for example, how diisopropylamine (pK-A 40) reacts with butyilithium to yield lithium diisopropylamide (LDA Section 22.5). Dialkylamine anions like LDA are extremely powerful bases that are often used... 

Still s synthesis of monensin (1) is based on the assembly and union of three advanced, optically active intermediates 2, 7, and 8. It was anticipated that substrate-stereocontrolled processes could secure vicinal stereochemical relationships and that the coupling of the above intermediates would establish remote stereorelationships. Scheme 3 describes Still s synthesis of the left wing of monensin, intermediate 2. This construction commences with an aldol reaction between the (Z) magnesium bromide enolate derived from 2-methyl-2-trimethylsilyloxy-3-pentanone (21) and benzyloxymethyl-protected (/ )-/ -hydroxyisobutyraldehyde (10).2° The use of intermediate 21 in aldol reactions was first reported by Heathcock21 and, in this particular application, a 5 1 mixture of syn aldol diastereoisomers is formed in favor of the desired aldol adduct 22 (85% yield). The action of lithium diisopropylamide (LDA) and magnesium(n) bromide on 21 affords a (Z) magnesium enolate that... 

When 2-lithio-2-(trimethylsilyl)-l,3-dithiane,9 formed by deprotonation of 9 with an alkyllithium base, is combined with iodide 8, the desired carbon-carbon bond forming reaction takes place smoothly and gives intermediate 7 in 70-80% yield (Scheme 2). Treatment of 7 with lithium diisopropylamide (LDA) results in the formation of a lactam enolate which is subsequently employed in an intermolecular aldol condensation with acetaldehyde (6). The union of intermediates 6 and 7 in this manner provides a 1 1 mixture of diastereomeric trans aldol adducts 16 and 17, epimeric at C-8, in 97 % total yield. Although stereochemical assignments could be made for both aldol isomers, the development of an alternative, more stereoselective route for the synthesis of the desired aldol adduct (16) was pursued. Thus, enolization of /Mactam 7 with LDA, as before, followed by acylation of the lactam enolate carbon atom with A-acetylimidazole, provides intermediate 18 in 82% yield. Alternatively, intermediate 18 could be prepared in 88% yield, through oxidation of the 1 1 mixture of diastereomeric aldol adducts 16 and 17 with trifluoroacetic anhydride (TFAA) in... 

Several reviews cover hetero-substituted allyllic anion reagents48-56. For the preparation of allylic anions, stabilized by M-substituents, potassium tm-butoxide57 in THF is recommended, since the liberated alcohol does not interfere with many metal exchange reagents. For the preparation of allylic anions from functionalized olefins of medium acidity (pKa 20-35) lithium diisopropylamide, dicyclohexylamide or bis(trimethylsilyl)amide applied in THF or diethyl ether are the standard bases with which to begin. Butyllithium may be applied advantageously after addition of one mole equivalent of TMEDA or 1,2-dimethoxyethane for activation when the functional groups permit it, and when the presence of secondary amines should be avoided. 

The induced stereoselectivity in these aldol additions with (///S)-2Tiydroxy-l,2,2-triphenylethyl acetate is improved by the use of an excess of base (e.g.. 3 equiv of lithium diisopropylamide or lithium hexamethyldisilazane) in the deprotonation step89. 

Table 10 shows examples of. vvn-sclcctive enolate condensations with imines using different types of enolates. All enolates used in these experiments were prepared based on the corresponding lithium enolate by treatment with different Lewis acids, where the lithium enolates themselves were generated with lithium diisopropylamide (LDA) at — 78 °C. 

When 2,2-dimethylpropanal is used to prepare the azomethine moiety, the corresponding azaallyl anion may be obtained when l,8-diazabicyclo[5.4.0]undec-7-ene/lithium bromide is used as base. The subsequent addition to various enones or methyl ( )-2-butenoate proceeds with anti selectivity, presumably via a chelated enolate. However, no reaction occurs when triethylamine is used as the base, whereas lithium diisopropylamide as the base leads to the formation of a cycloadduct, e.g., dimethyl 5-isopropyl-3-methyl-2,4-pyrrolidinedicarboxylate using methyl ( )-2-butenoate as the enone84 89,384. 

An excellent synthetic method for asymmetric C—C-bond formation which gives consistently high enantioselectivity has been developed using azaenolates based on chiral hydrazones. (S)-or (/ )-2-(methoxymethyl)-1 -pyrrolidinamine (SAMP or RAMP) are chiral hydrazines, easily prepared from proline, which on reaction with various aldehydes and ketones yield optically active hydrazones. After the asymmetric 1,4-addition to a Michael acceptor, the chiral auxiliary is removed by ozonolysis to restore the ketone or aldehyde functionality. The enolates are normally prepared by deprotonation with lithium diisopropylamide. 

---