Metal lithium diisopropylamide

Lithium acetyhde also can be prepared directly in hquid ammonia from lithium metal or lithium amide and acetylene (134). In this form, the compound has been used in the preparation of -carotene and vitamin A (135), ethchlorvynol (136), and (7j--3-hexen-l-ol (leaf alcohol) (137). More recent synthetic processes involve preparing the lithium acetyhde in situ. Thus lithium diisopropylamide, prepared from //-butyUithium and the amine in THF at 0°C, is added to an acetylene-saturated solution of a ketosteroid to directly produce an ethynylated steroid (138). 

The vinyl group has been used to protect the nitrogen of benzimidazole during metalation with lithium diisopropylamide. It is introduced with vinyl acetate [Hg(OAc)2, H2SO4, reflux, 24 h] and cleaved by ozonolysis (MeOH, —78°). ... 

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. 

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. 

Silylnitronates 1 are prepared14-24,25 by metalation of primary nitroalkanes with lithium diisopropylamide and treatment of the lithionitronates with either chlorotrimethylsilane or (/er/-butyldimethyl)chlorosilane. Nonaqueous workup and distillation gives the silylnitronates in >75% yield as moisture sensitive, but thermally stable, products. (e/7-Butyldimethylsilylni-tronates are more stable than the corresponding trimethylsilyl compounds. 

A reported procedure based on lithium diisopropylamide induced double elimination of ethanol from bromoacetaldehyde diethyl acetal also was not very effective for the large scale preparation of phenylthioacetylene.8 Another more recent synthesis of the title compound relies on the reaction of dimethyl(chloroethynyl)carbinol with an alkali metal phenylthiolate, followed by... 

The most direct route towards functionalized aliphatic polyesters is based on the functionalization of polyester chains. This approach is a very appealing because a wide range of functionalized aliphatic polyesters could then be made available from a single precursor. This approach was implemented by Vert and coworkers using a two-step process. Eirst, PCL was metallated by lithium diisopropylamide with formation of a poly(enolate). Second, the poly(enolate) was reacted with an electrophile such as naphthoyl chloride [101], benzylchloroformate [101] acetophenone [101], benzaldehyde [101], carbon dioxide [102] tritiated water [103], ot-bromoacetoxy-co-methoxy-poly(ethylene oxide) [104], or iodine [105] (Fig. 26). The implementation of this strategy is, however, difficult because of a severe competition between chain metallation and chain degradation. Moreover, the content of functionalization is quite low (<30%), even under optimized conditions. 

Direct metalation at the /8-carbon of azoles can also occur, although it is a much less facile process than that for the adjacent a-carbon, because of the greater charge density at what is normally a nucleophilic center in enamine-type reactions. Thus in order for reaction to occur, it is usually necessary to either block the a-position or activate the /3-site. If both factors are accommodated than /8-metalation occurs readily, and thus 3,4-disubstituted-2(3//)-thiazolethiones undergo direct lithiation with lithium diisopropylamide (LDA) at the 5-position, which is activated by the inductive effect of the adjacent sulfur (Scheme 4) (80S800). 

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. 

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). 

The metallation, especially the lithiation, of pyridazines, mentioned briefly in CHEC-II(1996) <1996CHEC-11(6)1 >, has been developed extensively since 1995 by Queguiner and co-workers for the derivatization of pyridazines and benzopyridazines. The bases of choice are usually lithium 2,2,6,6-tetramethylpiperidide (LTMP) and lithium diisopropylamide (EDA). Special efforts have been made to achieve regioselective lithiations. 

Dithiin, 1,4-benzodioxin, and its 2-substituted derivatives can be readly deprotonated and trapped with electrophiles although the reaction is more problematic with 1,4-dioxin. Oxanthrene and phenoxathiin are cleaved with lithium <1996CHEC-II(6)447>. A more recent example deals with the metallation at C-3 of the 1,4-benzodioxane 60 bearing a carboxylic acid function at C-2, with lithium diisopropylamide (EDA) and subsequent quench with iodomethane. The corresponding 3-methylated benzodioxane 61 was isolated in 70% yield (Equation 6) <2000EJM663>. 

Metalation of 2 with lithium diisopropylamide (LDA) generates diazo(trimethyl-silyl)methyl hthium (3), which reacts with a,p-unsaturated nitrile 36 and phenyl-sulfones (37) to form 3(or 5)-trimethylsilyl-l//-substituted pyrazole 4 that can be desilylated to furnish pyrazoles 5 (Scheme 8.3). 

The key reagents for the deprotonation of esters, acids and carbonyl compounds in general are the hindered metal amides, such as lithium diisopropylamide (1), lithium cyclohexyliso-propylamide (2) and lithium, sodium and potassium hexamethyldisilazanides (3). 

Rhenium-acyl complexes, such as 1, are isoelectronic with the iron-acyl complexes discussed above and many reactivity patterns are common to the two groups of compounds. Treatment of complex 1 with strong bases, such as butyllithium or lithium diisopropylamide, results in abstraction of a cyclopentadienyl proton which is followed by rapid migration of the acyl ligand to the cyclopentadienyl ring to produce the metal-centered anion 384. Alkylation of 3generates a metal-alkyl species, such as 4. 

A solution of 1.05 equiv of lithium diisopropylamide in diethyl ether (4-7 mL/mmol) is prepared as above. 1 Equiv of the a-alkylated hydrazone is added and the mixture is stirred for 5 h at 20°C. The solution of the metalated hydrazone is cooled to — 110 °C, 1.1 equiv of the electrophile are added dropwise, and the mixture is stirred for an additional 3 h at this temperature. After the mixture has warmed up slowly (15 h) to 20 "C, diethyl ether (40 mL/mmol) is added and the mixture is worked up as above. 

A variety of 2-alkyl-4,5-dihydrooxazoles were prepared from the corresponding chiral 2-methyl-4,5-dihydrooxazole by metalation with butyllithium or lithium diisopropylamide. followed by alkylation with the appropriate alkyl iodide, alkyl bromide or benzyl chloride2. 

As for their achiral analogues13, metalation of chiral 4,5-dihydrooxazoles can be performed with butyllithium, ATt-butyllithium, or lithium diisopropylamide at —78 °C in tetrahydrofuran. 

The treatment of thiazole with n-butyl- or phenyllithium leads to exclusive deprotonation at C-2. When the 2-position is blocked, deprotonation occurs selectively at C-5. However, if the substituent at C-2 is an alkyl group, the kinetic acidities of the protons at the a-position and at the 5-position are similar. The reaction of 2,4-dimethylthiazole with butyllithium at -78°C yields the 5-lithio derivative (289) as the major product but if the reaction is carried out at higher temperature the thermodynamically more stable 2-lithiomethyl derivative (290) is obtained (Scheme 37). The metallation at these two positions is also dependent on the strength and bulk of the base employed (74JOC1192) lithium diisopropylamide is preferred for selective deprotonations at the 5-position. 

A convenient procedure for preparing dialkylphosphinic acids 62 involves addition of H-phosphinic acids and esters to conjugated double bonds via the silyl 87-89 or metal phos-phonite 61,[90 94] as illustrated in Scheme 21. The silyl phosphonite intermediates 61 (M = TMS) are typically formed either from phosphinic acids or esters using chlorotri-methylsilane or bis(trimethylsilyl)acetamide. The metal phosphonite intermediates 61 (Y = Li, Na, etc.) are prepared by deprotonation of the acids with a base such as sodium hydride, sodium methoxide, or lithium diisopropylamide. The conjugated double bonds are typically acrylic acids and esters substituted in the a-position with the appropriate amino acid side chain. After appropriate protecting group manipulations, additional amino acids... 

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