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Lithium aluminum hydride in reduction

Aluminum chloride, 45, 109 with lithium aluminum hydride, in reduction of l,4-dioxaspiro[4 5] decane 47, 37... [Pg.120]

Lithium aluminum hydride, in reduction of 3-ethoxy-2-cyclohexenone to 2-cyclohexenone, 40, 14 Lithium ethoxide in condensation of benzaldehyde with tripbenylcin-namylphosphonium chloride to form 1,4-diphenyl-l, 3-butadiene,... [Pg.117]

Aluminum amalgam in reduction of oximinomalononitrile, 48, 2 Aluminum chloride, 46, 109 in conversion of tetramethy 1-1,3-cyclobutanedione to dimethyl-ketene d-lactone dimer, 48, 72 with lithium aluminum hydride, in reduction of l,4-dioxaspiro[4.5 -decane, 47, 37... [Pg.127]

Lithium aluminum hydride in reduction of 3-ethoxy-2-cyclohexenone to... [Pg.57]

High yields of optically active cyanohydrins have been prepared from hydrogen cyanide and carbonyl compounds using an enzyme as catalyst. Reduction of these optically active cyanohydrins with lithium aluminum hydride in ether affords the corresponding substituted, optically active ethanolamine (5) (see Alkanolamines). [Pg.411]

The azido mesylate may also be reduced with lithium aluminum hydride in the same manner as previously described for iodo azide reductions. The sodium borohydride/cobalt(II)tris(a,a -dipyridyl)bromide reagent may be used, but it does not seem to offer any advantages over the more facile lithium aluminum hydride or hydrazine/Raney nickel procedures. [Pg.36]

Reductive Opening of a 17a,20-Epoxide 17a,20-Oxidopregn-4-en-3-one (0.7 g) in 90 ml of dioxane (previously distilled over sodium) is added gradually to a solution of 1 g of lithium aluminum hydride in 50 ml of dry ether. [Pg.164]

Lithium aluminum hydride reduction of pyridinium salts is very similar to sodium horohydride reduction and gives similar products, but the ratio of 1,2- and 1,4-dihydro- or tetrahydropyridines differs considerably (5). Isoquinolinium salts are reduced hy sodium borohydride or lithium aluminum hydride in a manner identical to pyridinium salts (5). Quino-linium salts are reduced by sodium borohydride to give primarily tetra-hydroquinolines (72) as shown by the conversion of 33 to 34 and 35. When lithium aluminum hydride is used, the product is usually the dihydroquinoline (73) as shown in the conversion of 36 to 37 and 38. [Pg.186]

LY311727 is an indole acetic acid based selective inhibitor of human non-pancreatic secretory phospholipase A2 (hnpsPLA2) under development by Lilly as a potential treatment for sepsis. The synthesis of LY311727 involved a Nenitzescu indolization reaction as a key step. The Nenitzescu condensation of quinone 4 with the p-aminoacrylate 39 was carried out in CH3NO2 to provide the desired 5-hydroxylindole 40 in 83% yield. Protection of the 5-hydroxyl moiety in indole 40 was accomplished in H2O under phase transfer conditions in 80% yield. Lithium aluminum hydride mediated reduction of the ester functional group in 41 provided the alcohol 42 in 78% yield. [Pg.150]

Compound 7 is reduced to 2-benzamidocinnamyl alcohol by calcium borohydride in hydroxylic solvents at low temperatures. This reduction had been accomplished previously using lithium aluminum hydride in tetrahydrofuran. [Pg.94]

Tetrahydro derivatives are formed when either quinoxaline or 6-chloroquinoxaline is reduced with lithium aluminum hydride in ethereal solution. Similar reduction of 2,3-dimethylquinoxaline gives the meso-(cts)-1,2,3,4-tetrahydro derivative. This is shown to be a stereospecific reduction since lithium aluminum hydride does not isomerize the dl-(trans)-compound. Low temperature, platinum catalyzed, hydrogenation of 2,3-dimethylquinoxaline in benzene also gives meso (cis) -l,2,3,4-tetrahydro-2,3-dimethylquinoxaline. ... [Pg.214]

Reduction of ethyl l//-azepine-l-carboxylate (1) with lithium aluminum hydride in diethyl ether at — 15°C yields l-(hydroxymethyl)-l//-azepine (2) as a thermally unstable, yellow oil, whereas reduction in refluxing diethyl ether yields the equally unstable 1-methyl-l//-azepine (3)-231... [Pg.170]

Remarkable solvent effects on the selective bond cleavage are observed in the reductive elimination of cis-stilbene episulfone by complex metal hydrides. When diethyl ether or [bis(2-methoxyethyl)]ether is used as the solvent, dibenzyl sulfone is formed along with cis-stilbene. However, no dibenzyl sulfone is produced when cis-stilbene episulfone is treated with lithium aluminum hydride in tetrahydrofuran at room temperature (equation 42). Elimination of phenylsulfonyl group by tri-n-butyltin hydride proceeds by a radical chain mechanism (equations 43 and 44). [Pg.772]

A thio-substituted, quaternary ammonium salt can be synthesized by the Michael addition of an alkyl thiol to acrylamide in the presence of benzyl trimethyl ammonium hydroxide as a catalyst [793-795]. The reaction leads to the crystallization of the adducts in essentially quantitative yield. Reduction of the amides by lithium aluminum hydride in tetrahydrofuran solution produces the desired amines, which are converted to desired halide by reaction of the methyl iodide with the amines. The inhibitor is useful in controlling corrosion such as that caused by CO2 and H2S. [Pg.92]

Low-temperature reduction of 4-aryl-substituted 3-butyn-l-ols with lithium aluminum hydride in THF solvent gave m-olefin resulting from the hydride addition at the -carbon of the triple bond.134 This was in contrast to the propargyl alchohol that gives the trans-product resulting from the 7-addition. [Pg.279]

Another hydride, magnesium hydride prepared in situ from lithium aluminum hydride and diethylmagnesium, reduced terminal alkynes to 1-alkenes in 78-98% yields in the presence of cuprous iodide or cuprous r rt-butoxide, and 2-hexyne to pure cij-2-hexene in 80-81% yields [///]. Reduction of alkynes by lithium aluminum hydride in the presence of transition metals gave alkenes with small amounts of alkanes. Internal acetylenes were reduced predominantly but not exclusively to cis alkenes [377,378]. [Pg.44]

Double bonds conjugated with benzene rings are reduced electrolytically [344] (p. 23). Where applicable, stereochemistry can be influenced by using either catalytic hydrogenation or dissolving metal reduction [401] (p. 24). Indene was converted to indane by sodium in liquid ammonia in 85% yield [402] and acenaphthylene to acenaphthene in 85% yield by reduction with lithium aluminum hydride in carbitol at 100° [403], Since the benzene ring is not inert toward alkali metals, nuclear reduction may accompany reduction of the double bond. Styrene treated with lithium in methylamine afforded 25% of 1-ethylcyclohexene and 18% of ethylcyclohexane [404]. [Pg.49]

Replacement of an allylic hydroxyl without saturation or a shift of the double bond was achieved by treatment of some allylic-type alcohols with triphenyliodophosphorane (PhjPHI), triphenyldiiodophosphorane (PhsPIj) or their mixture with triphenyl phosphine (yields 24-60%) [612]. Still another way is the treatment of an allylic alcohol with a pyridine-sulfur trioxide complex followed by reduction of the intermediate with lithium aluminum hydride in tetrahydrofuran (yields 6-98%) [67 J]. In this method saturation of the double bond has taken place in some instances [675]. [Pg.78]

Aliphatic and aromatic sulfides undergo desulfurization with Raney nickel [673], with nickel boride [673], with lithium aluminum hydride in the presence of cupric chloride [675], with titanium dichloride [676], and with triethyl phosphite [677]. In saccharides benzylthioethers were not desulfurized but reduced to toluene and mercaptodeoxysugars using sodium in liquid ammonia [678]. This reduction has general application and replaces catalytic hydrogenolysis, which cannot be used [637]. [Pg.86]

Alkylaminotetrahydropyrans may be considered derivatives of aldehydes. They are reductively cleaved by lithium aluminum hydride to amino alcohols. Thus 2-(iV-piperidyl)tetrahydropyran afforded, after refluxing for 2 hours with 2 mol of lithium aluminum hydride in ether, 5-piperidino-l-pentanol in 82% yield [507]. [Pg.105]

For example, reduction of 2-alkylcycloalkanones with lithium aluminum hydride in tetrahydrofuran gave the following percentage proportions of the less stable cu-2-alkylalkanol (with axial hydroxyl) 2-methylcyclobutanol 25%, 2-methylcyclopentanol 21%, 2-methylcyclohexanol 25%, 2-methylcy-cloheptanol 73%, and 2-methylcyclooctanol 73% (the balance to 100% being the other, trans, isomer) [837. ... [Pg.114]

Reduction of unsaturated ketones to saturated alcohols is achieved by catalytic hydrogenation using a nickel catalyst [49], a copper chromite catalyst [50, 887] or by treatment with a nickel-aluminum alloy in sodium hydroxide [555]. If the double bond is conjugated, complete reduction can also be obtained with some hydrides. 2-Cyclopentenone was reduced to cyclopentanol in 83.5% yield with lithium aluminum hydride in tetrahydrofuran [764], with lithium tris tert-butoxy)aluminium hydride (88.8% yield) [764], and with sodium borohydride in ethanol at 78° (yield 100%) [764], Most frequently, however, only the carbonyl is reduced, especially with application of the inverse technique (p. 21). [Pg.121]

Reduction of cyclohexanone oxime with lithium aluminum hydride in tetra-hydrofuran gave cyclohexylamine in 71% yield [809], and reduction of ketoximes with sodium in methanol and liquid ammonia [945] or in boiling ethanol [946] afforded alkyl amines, usually in good to high yields. Stannous chloride in hydrochloric acid at 60° reduced the dioxime of 9,10-phenanthra-... [Pg.132]


See other pages where Lithium aluminum hydride in reduction is mentioned: [Pg.163]    [Pg.100]    [Pg.105]    [Pg.197]    [Pg.38]    [Pg.608]    [Pg.23]    [Pg.20]    [Pg.154]    [Pg.82]    [Pg.3]    [Pg.256]    [Pg.434]    [Pg.44]    [Pg.15]    [Pg.44]    [Pg.89]    [Pg.94]    [Pg.105]   


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