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Hydrazones lithium salts

Tosyl hydrazone lithium salt was prepared as the product of Step 1. [Pg.487]

A solution of copper(II)acetylacetonate (5 mg), 4-chloro-benxaldehyde and tosyl hydrazone lithium salt (2.5 eq) were mixed and heated to 45 °C 3 hours, cooled, and 1ml EtOAc/water, 1 1, added. The epoxide was isolated as a white solid in 54% yield with a trans/cis ratio of 2.8 1, respectively. [Pg.487]

In an altogether different type of approach, the hydrazone is formed in situ as a lithium salt. Wilson et al. (80JHC389) described this approach in the one-pot synthesis of 5-aryl-2-phenylpyrazol-3-ones 72a-f from the corresponding hydrazones 65a-f (Scheme 20). The latter were obtained by condensing ketones 64a-f with phenylhydrazine. Treatment of hydrazones 65a-f with n-butyllithium in dry THF, followed by the addition of half a molar equivalent of diethyl carbonate 67 and then quenching the reaction mixture with hydrochloric acid, produced pyrazol-3-ones 72a-f, along with products 71. The yields of the products 72 are in the range 22-97%. Four intermediates—66a-f, 68a-f, 69a-f, and 70a-f— were proposed for this reaction. [Pg.89]

The same type of reaction occurs in the work of Hauptman (76T1293), who, studying the chemistry of diethynylcarbenes, found that the pyrolysis of the lithium salts of diethynylketone tosylhydrazones 5 (140-150°C) in the presence of olefins leads to cyclopropanes. This process results in the formation of the corresponding 3-ethynylpyrazoles. The formation of l-p-tolylsulfonyl-3-alkynylpyrazoles from hydrazone runs in milder conditions (50°C, 14 h) (Scheme 24). [Pg.12]

Hydrazones can also be deprotonated to give lithium salts that are reactive toward alkylation at the (3-carbon. Hydrazones are more stable than alkylimines and therefore have some advantages in synthesis.119 The A N-dimcthyl hydrazones of methyl ketones are kinetically deprotonated at the methyl group. This regioselectivity is independent... [Pg.52]

Fig. 1.7. Crystal structure of lithium salt of SAMP hydrazone of 2-acetylnaphthalene. Two molecules of THF are present. Reproduced from Angew. Chem. Int. Ed. Engl., 27, 1522 (1988), by permission of Wiley-VCH. Fig. 1.7. Crystal structure of lithium salt of SAMP hydrazone of 2-acetylnaphthalene. Two molecules of THF are present. Reproduced from Angew. Chem. Int. Ed. Engl., 27, 1522 (1988), by permission of Wiley-VCH.
Precursors for this task were obtained by addition of /-butylmagnesium bromide to the central bond of [1.1.1 ]propellane 40a followed by conversion of the 3-f-butylbicyclo[ 1.1.1 Jpentyl-1 -y 1-magnesium bromide (88) into the ketones 89 by standard methods.27 Reaction of ketones 89 with tosyl hydrazide afforded the hydrazones 90, which gave the corresponding lithium salts 91 by reaction with MeLi in ether. These salts were dried under high vacuum and then pyrolized at 4 x 10 5 torr in the temperature range of 100-130°C and the volatile products condensed in a liquid nitrogen-cooled trap. [Pg.283]

Chiral hydrazones have also been developed for enantioselective alkylation of ketones. The hydrazones can be converted to the lithium salt, alkylated, and then hydrolyzed to give alkylated ketone in good chemical yield and with high enantioselec-tivity83 (see entry 4 in Table 1.3). [Pg.38]

Lithium salts of ketone derivatives such as imines, oximes and hydrazones have also been used for directed aldol reactions (Scheme 103).374 375 A recent example involves triple coordination of lithium in a very rigid transition state, to lead to regiospecificity in the product (Scheme 104).376... [Pg.218]

A recent application of the furan-carbonyl photocycloaddition involved the synthesis of the mycotoxin asteltoxin (147)." Scheme 16 shows the synthetic procedure that began with the photoaddition of 3,4-dimethylfuran and p-benzyloxypropanal to furnish photoaldol (148), which was epoxidized with MCPBA to afford the functionalized product (149) in 50% overall yield. Hydrolysis (THF, 3N HCl) provided the monocyclic hemiacetal which was protected as its hydrazone (150). Chelation-controlled addition of ethylmagnesium bromide to the latent a-hydroxy aldehyde (150) and acetonide formation produced compound (151), which was transformed through routine operations to aldehyde (152). Chelation-controlled addition of the lithium salt of pentadienyl sulfoxide (153) followed by double 2,3-sigma-tropic rearrangement provided (154) as a 3 1 mixture of isomers (Scheme 17). Acid-catalyzed cyclization of (154) (CSA/CH2CI2) gave the bicyclic acetal (155), which was transformed in several steps to ( )-asteltoxin (147). ... [Pg.172]

Photodecomposition of sodium salts of toluene-p-sulphonylhydrazones is a well-established route for the generation of carbenes. Irradiation of the lithium salt of the hydrazone (150) or the diazoalkenyl ether (151) derived from it afforded... [Pg.491]

Several new syntheses of vinylsilanes have been described. Tris(trimethyl-silyl)aluminium undergoes 5yn-addition to alkynes alternatively the same -isomers can be obtained by photochemical isomerisation of Z-1-alkenyl-silanes. Other methods described involve treatment of the lithium salts of hydrazones with trimethylsilyl chloride, Wurtz-type coupling with vinyl bromides, and reaction of acetylenes with a silyl-copper reagent followed by an electrophile. Using the hydrazone method, a route has been devised for 1,2-carbonyl transposition within ketones (Scheme 17). ... [Pg.242]

Lucifer Yellow CH is soluble in aqueous solution, and it should be stable for awhile if protected from light. The reagent is available as three different salts of the sulfonate groups. The ammonium salt of the fluorophore is soluble to a level of 9 percent in water, while the lithium and potassium salts have a solubility of 5 and 1 percent, respectively. A concentrated stock solution of the fluorophore may be prepared in water and an aliquot added to a buffered reaction medium to facilitate the transfer of small quantities. For aqueous reactions, a pH range of 5-9 will result in efficient hydrazone formation with aldehyde or ketone residues. [Pg.461]

The deuteriated (97%) imines 363 and 365, and the hydrazone 364 have been prepared396-399 by treating 2,6,6-trideuterio-2-methylcyclohexanone and 2,2,6,6-tetradeuteriocyclohexanone with the corresponding deuteriated ammonium salts (RND3CI) and used in the KIE studies of the metalation of the above C=N compounds with lithium diisopropylamide (LDA) in THF, in N, N, N A -tetramethyl ethylenediamine (TMEDA) and in dimethylethylamine (DMEA) solvents (equation 200). The rates, d[imine]/dt of that of imines 363 and 364 metalation are zero order with respect to [THF], [TMEDA]... [Pg.1020]

In a comprehensive study, using -NMR measurements and trapping product analysis, that was designed for understanding the stereoselectivity in electrophilic substitutions of hydrazones that underwent lithiation, it was found that lithium di-methylhydrazone salts of aldehydes are obtained as a mixture of two stereoisomers 52 and 53107,108 (equation 31). [Pg.1522]

Epoxidations were also performed using lithium or ammonium benzaldehyde tosyl hydrazone salts as described by the author. [Pg.487]

See other pages where Hydrazones lithium salts is mentioned: [Pg.53]    [Pg.1508]    [Pg.75]    [Pg.777]    [Pg.538]    [Pg.1508]    [Pg.507]    [Pg.507]    [Pg.349]    [Pg.331]    [Pg.7196]    [Pg.293]    [Pg.309]    [Pg.777]    [Pg.3]    [Pg.89]    [Pg.507]    [Pg.276]    [Pg.791]    [Pg.554]    [Pg.296]   


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Lithium hydrazones

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