Amides lithiation

A nionic telomerizations of conjugated diolefins with hydrocarbon acids - are known but suffer from very low catalytic efficiencies. Morton et al. (I) and, later, Pappas et al. (2) used unchelated organosodium compounds to telomerize conjugated diolefins with weak hydrocarbon acids but obtained very low catalyst efficiencies (about 5 grams/gram catalyst). More recently, the anionic telomerization of butadiene and toluene by sodium on oxide supports (3) and sodium in tetrahydrofuran (4) was studied .also, a potassium amide/lithiated alumina catalyst was used to telomerize butadiene (5). 

IG level. Geometries of precomplexation (using lithium amide), lithiation transition states, and end complexes (containing one molecule of NH3 coordinated to Li) have also been studied <2003TFI1>. 

The mechanism of the dearomatization-cyclization of aromatic amides takes place by initial lithiation at the ortho position of the aromatic ring. This species is in equilibrium with the more stable a-amide lithiated compound, which forms the final product by means of a 6n electrocyclic ring closure. 

Poly(phenylene oxide)s undergo many substitution reactions (25). Reactions involving the aromatic rings and the methyl groups of DMPPO include bromination (26), displacement of the resultant bromine with phosphoms or amines (27), lithiation (28), and maleic anhydride grafting (29). Additional reactions at the open 3-position on the ring include nitration, alkylation (30), and amidation with isocyanates (31). 

Beyer synthesis, 2, 474 electrolytic oxidation, 2, 325 7r-electron density calculations, 2, 316 1-electron reduction, 2, 282, 283 electrophilic halogenation, 2, 49 electrophilic substitution, 2, 49 Emmert reaction, 2, 276 food preservative, 1,411 free radical acylation, 2, 298 free radical alkylation, 2, 45, 295 free radical amidation, 2, 299 free radical arylation, 2, 295 Friedel-Crafts reactions, 2, 208 Friedlander synthesis, 2, 70, 443 fluorination, 2, 199 halogenation, 2, 40 hydrogenation, 2, 45, 284-285, 327 hydrogen-deuterium exchange, 2, 196, 286 hydroxylation, 2, 325 iodination, 2, 202, 320 ionization constants, 2, 172 IR spectra, 2, 18 lithiation, 2, 267... 

Uneyama et al. have shown that enantiopure trifluoromethyloxirane (193) can be lithiated and stereoselectively trapped with a variety of electrophiles to give substituted trifluoromethyloxiranes such as 195 (Scheme 5.46) [70] the use of a Weinreb amide as the electrophile is unusual. 

Use of LTMP as base [52] in situ with Me3SiCl allows straightforward access to a variety of synthetically useful a, 3-epoxysilanes 232 at near ambient temperature directly from (enantiopure) terminal epoxides 231 (Scheme 5.55) [81]. This reaction relies on the fact that the hindered lithium amide LTMP is compatible with Me3SiCl under the reaction conditions and that the electrophile trapping of the nonstabilized lithiated epoxide intermediate must be very rapid, since the latter are usually thermally very labile. 

The aldol reaction of 2,2-dimethyl-3-pentanone, which is mediated by chiral lithium amide bases, is another route for the formation of nonracemic aldols. Indeed, (lS,2S)-l-hydroxy-2,4,4-trimethyl-l-phenyl-3-pentanone (21) is obtained in 68% ee, if the chiral lithiated amide (/ )-A-isopropyl-n-lithio-2-methoxy-l-phenylethanamine is used in order to chelate the (Z)-lithium cnolate, and which thus promotes the addition to benzaldehyde in an enantioselective manner. No anti-adduct is formed25. 

These phosphinous amide anions are presumably responsible for the formation of the by-products AT-phosphino phosphinous amides 11 and mono-phosphazenes derived from diphosphanes 12 in the sequential treatment of primary amines with n-BuLi and chlorophosphanes for preparing NH phosphinous amides [75,88] (Scheme 14). Compounds 11 and 12 are presumably derived from anions 9 and 10, respectively, generated by deprotonation of the newly formed phosphinous amide with the lithiated amine R NHLi. In solution, 9 can establish a metallotropic equilibrium with 10. 

Weinreb amides of aziridinecarboxylic acids readily react with orfho-lithiated 0-methoxymethyl phenols. The thus produced benzoylaziridine 43 undergoes an intramolecular ring expansion upon treatment with acid in ethanol. Base treatment leads to benzofuranones as shown in Scheme 34 [44]. 

Lithiation of alkyl groups is also possible and again a combination of donor chelation and polar stabilization of anionic character is required. Amides and carbamates can be lithiated a to the nitrogen. 

Tertiary amides with carbanion stabilization at the (3-carbon give (3-lithiation.61... 

Lithiation has also been observed for deprotonated secondary amides of 3-phenylpro-panoic acid. 

Tertiary amides 9-1, 9-2, and 9-3 are lithiated at the (3-carbon, rather than the a-carbon by s-butyllithium-TMEDA. It is estimated that the intrinsic acidity of the a-position exceeds that of the (3-position by about 9 pK units. What causes the (3-deprotonation to be kinetically preferred ... 

These efforts began with directed lithiation [53] of commercially available 4-methoxybenzaldehyde dimethyl acetal (117, Scheme 1.12), followed by quenching with amide 118 to produce chloro acetophenone 119 (52 %). Conversion... 

Other tin reagents have found use in Pd-catalyzed cross-couplings with halopyridines as well. The Stille coupling of 3-iodopyridine with ethoxy(tributylstannyl)acetylene gave rise to 3-ethoxyethynylpyridine (100), which was then hydrolyzed to the corresponding ethyl 3-pyridylacetate (101) [88], Carbamoylstannane 102 was prepared by sequential treatment of lithiated piperidine with carbon monoxide and trimethyltin chloride. Stille coupling of carbamoylstannane 102 and 3-bromopyridine provided a unique entry to amide 103 [89],... 

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