Lithium diisopropylamide ketones

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... 

The i -alkoxycarbonyhnethylxanthate esters treated with lithium diisopropylamide (LDA) and an aldehyde or ketone give excellent yields of a,P-unsaturated esters (56) ... 

In general the reaction of an aldehyde with a ketone is synthetically useful. Even if both reactants can form an enol, the a-carbon of the ketone usually adds to the carbonyl group of the aldehyde. The opposite case—the addition of the a-carbon of an aldehyde to the carbonyl group of a ketone—can be achieved by the directed aldol reaction The general procedure is to convert one reactant into a preformed enol derivative or a related species, prior to the intended aldol reaction. For instance, an aldehyde may be converted into an aldimine 7, which can be deprotonated by lithium diisopropylamide (EDA) and then add to the carbonyl group of a ketone ... 

Good yields are usually obtained with aromatic aldehydes or ketones. Aliphatic aldehydes are poor substrates for the ordinary procedure, but react much better if the halo ester is first deprotonated with lithium diisopropylamide (LDA) in tetrahydrofuran at -78 °C, prior to addition of the aldehyde. 

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. 

Very high levels of induced diastereoselectivity are also achieved in the reaction of aldehydes with the titanium enolate of (5)-l-rerr-butyldimethylsiloxy-1-cyclohexyl-2-butanone47. This chiral ketone reagent is deprotonated with lithium diisopropylamide, transmetalated by the addition of triisopropyloxytitunium chloride, and finally added to an aldehyde. High diastereoselectivities are obtained when excess of the titanium reagent (> 2 mol equiv) is used which prevents interference by the lithium salt formed in the transmetalation procedure. Under carefully optimized conditions, diastereomeric ratios of the adducts range from 70 1 to >100 1. 

Chiral oxazolidines 6, or mixtures with their corresponding imines 7, are obtained in quantitative yield from acid-catalyzed condensation of methyl ketones and ( + )- or ( )-2-amino-l-phcnylpropanol (norephedrine, 5) with azeotropic removal of water. Metalation of these chiral oxazolidines (or their imine mixtures) using lithium diisopropylamide generates lithioazaeno-lates which, upon treatment with tin(II) chloride, are converted to cyclic tin(II) azaenolates. After enantioselective reaction with a variety of aldehydes at 0°C and hydrolysis, ft-hydroxy ketones 8 are obtained in 58-86% op4. 

Metalation ofa-sulfinyl dimethylhydrazones with terf-butylmagnesium bromide, butyllithium or lithium diisopropylamide, and reaction of the generated azaenolates with aldehydes, provides aldol adducts (e.g., 6) as mixtures of diastereomers. Reductive desulfurization leads to fi-hydroxy dimethylhydrazones (e.g., 7) which are cleaved to the desired /(-hydroxy ketones in 25% overall yield10 u. The enantiomeric excesses are about 50%, except for (- )-3-hydroxy-4-methyl-1-phenyl-1-pentanone (8) which was obtained in 88% ee. 

Formation of a-Sulfinyl Anions with Lithium Diisopropylamide and Subsequent Addition to a,/ -Unsaturatcd Ketones General Procedure1 ... 

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. 

The enol acetates, in turn, can be prepared by treatment of the parent ketone with an appropriate reagent. Such treatment generally gives a mixture of the two enol acetates in which one or the other predominates, depending on the reagent. The mixtures are easily separable. An alternate procedure involves conversion of a silyl enol ether (see 12-22) or a dialkylboron enol ether (an enol borinate, see p. 560) to the corresponding enolate ion. If the less hindered enolate ion is desired (e.g., 126), it can be prepared directly from the ketone by treatment with lithium diisopropylamide in THE or 1,2-dimethoxyethane at —78°C. ... 

Treatment of a-dichloromethyl phenyl sulfoxide with lithium diisopropylamide in THF gave monolithiated derivative 122, which upon further treatment with aldehyde afforded the )S-hydroxy-a-dichlorosulfoxide 123. Thermolysis of 123 gave dichloroketone 124, by extruding benzenesulfenic acid as shown below . Similarly, in the reaction of lithio-a-fluoromethyl phenyl sulfoxide and aldehyde, fluoromethyl ketone 126 was obtained, after thermolysis of the hydroxy intermediate 125. Diethylphosphorylmethyl methyl sulfoxide was shown by Miko/ajczyk and coworkers to be lithiated with n-BuLi to intermediate 127, which upon treatment with carbonyl compounds afforded the corresponding a, -unsaturated sulfoxides 128 in good yields. 

Rates of deprotonation of a simple ketone (89) by lithium diisopropylamide (LDA) in THF at -78 °C show a first-order dependence on ketone, and an order of 0.58 ( 0.06) in base. Alternative pathways involving the LDA monomer and its solvent-complexed dimer (90) are considered. 

Darzens reaction of (-)-8-phenylmethyl a-chloroacetate (and a-bromoacetate) with various ketones (Scheme 2) yields ctT-glycidic esters (28) with high geometric and diastereofacial selectivity which can be explained in terms of both open-chain or non-chelated antiperiplanar transition state models for the initial aldol-type reaction the ketone approaches the Si-f ce of the Z-enolate such that the phenyl ring of the chiral auxiliary and the enolate portion are face-to-face. Aza-Darzens condensation reaction of iV-benzylideneaniline has also been studied. Kinetically controlled base-promoted lithiation of 3,3-diphenylpropiomesitylene results in Z enolate ratios in the range 94 6 (lithium diisopropylamide) to 50 50 (BuLi), depending on the choice of solvent and temperature. ... 

The loss of optical activity accompanying deprotonation of (/f)-2,2,6-trimethyl-cyclohexanone by lithium diisopropylamide (LDA, which exists as a dimer) in THF is governed by the rate equation v = /c [ketone] [LDA]°-, which is consistent with a rate-determining proton transfer involving amine monomer. ... 

If this precaution is not followed, partial or complete equilibration of the enolates will occur because of proton transfers between the enolates and the excess un-ionized ketone. In an experiment where a slight excess of ketone was added, the distilled, monoalkylated product (40% yield) contained 77% of the undesired 2,2-isomer and only 23% of the desired 2,6-isomer. However, it is also important in this preparation not to allow a large excess of lithium diisopropylamide to remain in the reaction mixture this base reacts with benzyl bromide to form iraws-stilbene which is difficult to separate from the reaction product. 

The reason why the carbonyl group in -santonin remained intact may be that, after the reduction of the less hindered double bond, the ketone was enolized by lithium amide and was thus protected from further reduction. Indeed, treatment of ethyl l-methyl-2-cyclopentanone-l-carboxylate with lithium diisopropylamide in tetrahydrofuran at — 78° enolized the ketone and prevented its reduction with lithium aluminum hydride and with diisobutyl-alane (DIBAL ). Reduction by these two reagents in tetrahydrofuran at — 78° to —40° or —78° to —20°, respectively, afforded keto alcohols from several keto esters in 46-95% yields. Ketones whose enols are unstable failed to give keto alcohols [1092]. 

To obtain complete conversion of ketones to enolates, it is necessary to use aprotic solvents so that solvent deprotonation does not compete with enolate formation. Stronger bases, such as amide anion ( NH2), the conjugate base of DMSO (sometimes referred to as the dimsyl anion),2 and triphenylmethyl anion, are capable of effecting essentially complete conversion of a ketone to its enolate. Lithium diisopropylamide (LDA), which is generated by addition of w-butyllithium to diisopropylamine, is widely used as a strong... 

Ring protons of 1,2,3-thiadiazoles are known to undergo rapid deuterium exchange under basic conditions, yet to date there have been no published estimates or experiments to determine the pA of these protons. Few attempts have even been made to metalate and alkylate this heterocycle. One study <85S945> found that metalation of 5-phenyl-1,2,3-thiadiazole (25) with methyllithium gives 4-lithio-5-phenyl-l,2,3-thiadiazole, which is stable and reacts with aldehydes and ketones in high yields (Equation (11)). Also, treatment of 4-phenyl-1,2,3-thiadiazole with lithium diisopropylamide, in the presence of TMS-Cl, affords 4-phenyl-5-trimethylsilyl-1,2,3-thiadiazole. 

Kinetic control can be achieved by slow addition of the ketone to an excess of strong base in an aprotic solvent. Kinetic control requires a rapid, quantitative and irreversible deprotonation reaction 2-6. The use of a very strong, sterically hindered base, such as lithium diisopropylamide or triphenylmethyllithium (trityllithium), at low temperature (— 78 °C) in an aprotic solvent in the absence of excess ketone has become a general tool for kinetic control in selective enolate formation. It is important to note that the nature of the counterion is sometimes important for the regioselectivity. Thus, lithium is usually better than sodium and potassium for the selective generation of enolates by kinetic control. 

An oven-dried. 50-mL, 3-necked flask equipped wilh a pressure-equalizing dropping funnel, reflux condenser, nitrogen inlet, magnetic stirrer, and vacuum takeoff adapter is evacuated (vacuum pump) and refilled three times with nitrogen. 10 mL of THF and 0.735 mL (5.25 mmol) of diisopropylamine are then added via a double-ended needle. The solution is cooled to 0"C and 2.2 mL of a 2.4 M solution of butyllithium (5.25 mmol) in hexane are added. The lithium diisopropylamide is allowed to form at 0 °C for 15 min and is then cooled to — 20 C. 5 mmol of the chiral acyclic ketone iminc in 5 mL of THF are added (5 min) and anion formation allowed to continue for 1 h at 20 C. The anion solution is then heated to reflux for 2 h and cooled to —78 C. A solution of 5.25 mmol of the iodoalkane in 5 mL of THF is then added, and alkylation is allowed to proceed at — 78 °C for 1 h. Workup and hydrolysis, as described for the cyclic ketones (see Section 1.1.1.4.1.2.L), yields the a-alkylatcd acyclic ketones (see Table 4). 

Alkyl-bromide (bzw. Allyl-bromid) sowie Ketone reagieren mit dem aus Benzophenon-methylimin und Lithium-diisopropylamid gebildeten l,l-Diphenyl-2-aza-allyl-lithium un-ter Substitution zu l-(Diphenylmethylen-amino)-alkanen bzw. l-(Diphenylme-thylen-amino)-2-hydroxy-alkanen, deren saure Hydrolyse 1-Amino-alkane bzw. 1-Ami no-2-hydroxy-alkane ergibt1. 

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