Borohydride aluminum, reduction with

Reduction to alcohols (Section 15 2) Aide hydes are reduced to primary alcohols and ketones are reduced to secondary alcohols by a variety of reducing agents Catalytic hydrogenation over a metal catalyst and reduction with sodium borohydride or lithium aluminum hydride are general methods... 

In certain cases this reduction (with lithium aluminum hydride) takes a different course, and olefins are formed. The effect is dependent on both the reagent concentration and the steric environment of the hydrazone. Dilute reagent and hindered hydrazone favor olefins borohydride gives the saturated hydrocarbon. The hydrogen picked up in olefin formation comes from solvent, and in full reduction one comes from hydride and the other from solvent. This was shown by deuteriation experiments with the hydrazone (150) ... 

Studies of reductions with metal hydndes have concentrated on improvements in selectivity or conditions Replacement of the usual lithium aluminum hydnde-ether combination with potassium borohydride-methanol results m high yields of alcohol from ester [76] and less hazard [77] (equation 62) Reduction of a... 

Although isolated fluonne atoms can survive reductions with hthium aluminum hydnde when they are not m a position a to an ester or nitnle group [79] (equauons 63a and 63b), those in an a position arc reducti vely cleaved The milder borohydride reagents convert an a fluorocarboxylate ester to the corresponding alcohol without loss of fluonne [501 (equation 64)... 

The reduction of the double bond of an enamine is normally carried out either by catalytic hydrogenation (MS) or by reduction with formic acid (see Section V.H) or sodium borohydride 146,147), both of which involve initial protonation to form the iminium ion followed by hydride addition. Lithium aluminum hydride reduces iminium salts (see Chapter 5), but it does not react with free enamines except when unusual enamines are involved 148). 

J -Dehydroquinolizidine reacts with the enantiomeric (—)- and (-l-)-menthyl chloroformates forming (—)- and (-l-)-menthoxycarbonyl- -dehydroquinolizidines. These can be reduced as such or in the form of their immonium salts with sodium borohydride to (—)- and (+)-l-menthoxy-carbonylquinolizidines, which give (+)- and (-)-lupinin, respectively, on reduction with lithium aluminum hydride (243). The optical yield of the asymmetric reduction is about 10%. 

Lithium aluminum hydride reduction of oxychelerythrine (232) gave 6-hydroxydihydrochelerythrine (235), recrystallization of which in methanol afforded 6-methoxydihydrochelerythrine (agoline) (236). Both compounds have been isolated from plants, but they are probably artifacts arising during isolation. On reduction with sodium borohydride or dehydration with 10% hydrochloric acid, 235 was converted to dihydrochelerythrine (203) or chelerythrine (205), respectively (130,131). 

Carbonyl compounds addition to, 73 659 a-alkylation of, 73 658s reduction with alumina—sodium borohydride, 76 572-573 reduction with aluminum alkoxides, 76 572... 

The neutralization values were influenced by reduction with strong reducing agents, lithium aluminum hydride, sodium borohydride, and amalgamated zinc plus hydrochloric acid (35, 46). For the most part, the consumption of NajCOj and of NaOEt decreased in equivalent amounts. This is further confirmation of the assumption that lactones of the fluorescein type or of the lactol type are present. The reaction with sodium ethoxide was shown to be no true neutralization, that is, exchange of H+for Na+, at all, but an addition reaction w ith the formation of the sodium salt of a semi-acetal or ketal ... 

Reductions with hydrides and complex hydrides are usually carried out by mixing solutions. Only sodium borohydride and some others are sometimes added portionwise as solids. Since some of the complex hydrides such as lithium aluminum hydride are not always completely pure and soluble without residues, it is of advantage to place the solutions of the hydrides in the reaction flask and add the reactants or their solutions from separatory funnels or by means of hypodermic syringes. 

The pyridine ring is easily reduced in the form of its quaternary salts to give hexahydro derivatives by catalytic hydrogenation [446], and to tetrahydro and hexahydro derivatives by reduction with alane aluminum hydride) [447], sodium aluminum hydride [448], sodium bis 2-methoxyethoxy)aluminum hydride [448], sodium borohydride [447], potassium borohydride [449], sodium in ethanol [444, 450], and formic acid [318]. Reductions with hydrides give predominantly 1,2,5,6-tetrahydro derivatives while electroreduction and reduction with formic acid give more hexahydro derivatives [451,452]. 

Reduction of quinoxalines was carried out by catalytic hydrogenation [491, 492,493,494], with sodium borohydride [490] or with lithium aluminum hydride [476] to different stages of saturation. 

Alkyl chlorides are with a few exceptions not reduced by mild catalytic hydrogenation over platinum [502], rhodium [40] and nickel [63], even in the presence of alkali. Metal hydrides and complex hydrides are used more successfully various lithium aluminum hydrides [506, 507], lithium copper hydrides [501], sodium borohydride [504, 505], and especially different tin hydrides (stannanes) [503,508,509,510] are the reagents of choice for selective replacement of halogen in the presence of other functional groups. In some cases the reduction is stereoselective. Both cis- and rrunj-9-chlorodecaIin, on reductions with triphenylstannane or dibutylstannane, gave predominantly trani-decalin [509]. 

Complex hydrides can be used for the selective reduction of the carbonyl group although some of them, especially lithium aluminum hydride, may reduce the a, -conjugated double bond as well. Crotonaldehyde was converted to crotyl alcohol by reduction with lithium aluminum hydride [55], magnesium aluminum hydride [577], lithium borohydride [750], sodium boro-hydride [751], sodium trimethoxyborohydride [99], diphenylstarmane [114] and 9-borabicyclo[3,3,l]nonane [764]. A dependable way to convert a, -un-saturated aldehydes to unsaturated alcohols is the Meerwein-Ponndorf reduction [765]. 

More reliable therefore is reduction with lithium aluminum hydride, lithium borohydride or calcium borohydride, which do not hydrogenolyze hydroxy groups [92]. 

Usually alcohols accompany aldehydes in reductions with lithium aluminum hydride [1104] or sodium bis 2-methoxyethoxy)aluminum hydride [544], or in hydrogenolytic cleavage of trifluoroacetylated amines [7772]. Thus terr-butyl ester of. -(. -trifluoroacetylprolyl)leucine was cleaved on treatment with sodium borohydride in ethanol to rerr-butyl ester of A7-prolylleucine (92% yield) and trifluoroethanol [7772]. During catalytic hydrogenations over copper chromite, alcohols sometimes accompany amines that are the main products [7775]. 

In the reductions with borohydrides and boranes the isolation of products differs from that used in the reductions with lithium aluminum hydride, the... 

Thioamides were converted to aldehydes by cautious desulfurization with Raney nickel [1137, 1138] or by treatment with iron and acetic acid [172]. More intensive desulfurization with Raney nickel [1139], electroreduction [172], and reduction with lithium aluminum hydride [1138], with sodium borohydride [1140] or with sodium cyanoborohydride [1140] gave amines in good to excellent yields. 

Conversion of the keto ketoxime 1 to the exo-exo-amino alcohol 2 has been accomplished by hydrogenation over Adams catalyst and by reduction with lithium aluminum hydride. Amino alcohol 2 has also been prepared from 1 by a two-stage process in which selective reduction of the ketone is carried out with sodium borohydride, and the resultant hydroxy oxime is reduced with lithium aluminum hydride or by hydrogenation over Adams catalyst. ... 

A different approach to enantiotopic group differentiation in bicyclic anhydrides consists of their two-step conversion, first with (/ )-2-amino-2-phcnylethanol to chiral imides 3, then by diastereoselective reduction with sodium bis(2-methoxyethoxy)aluminum hydride (Red-Al) to the corresponding chiral hydroxy lactames 4, which may be converted to the corresponding lactones 5 via reduction with sodium borohydride and cyclization of the hydroxyalkyl amides 101 The overall yield is good and the enantioselectivity ranges from moderate to good. Absolute configurations of the lactones are based on chemical correlation. 

Acylmetallocenes undergo many reactions shown by acylbenzenes (35, 87, 91, 116, 124), but a detailed discussion is not presented here. Reductions with either lithium aluminum hydride or sodium borohydride give the corresponding carbinols, while Clemmensen reduction, reduction with lithium aluminum hydride plus aluminum chloride, catalytic hydrogenation, etc., yield corresponding alkyl derivatives. Acetylferrocenes undergo a variety of base condensation reactions and can be oxidized to ferrocenecarboxylic acids without apparent oxidation of the iron atom. 

Polystyrene-bound carboxylic esters have been reduced with diisobutylaluminum hydride or lithium aluminum hydride. Use of the latter reagent can, however, lead to the formation of insoluble precipitates, which could readily cause problems if reactions are performed in fritted reactors. An alternative procedure for reducing carboxylic esters to alcohols involves saponification, followed by activation (e.g. as the mixed anhydride) and reduction with sodium borohydride (Entries 10 and 11, Table... 

In the similar structure of l.l,1,2,4,4,4-heptafluoro-3-phenylbut-2-ene, the reduction with sodium borohydride takes place readily under mild conditions and both products of vinylic and allylic Sn2 displacement are obtained the relative amounts of the products can be controlled by adding triphenylphosphane to the mixture80 (Table 2). The nonfluorinated chain in Hpenta-fluorophenyl)-2-phenylethane (12) selectively activates the para C-F bond to reduction by lithium aluminum hydride, giving the monoreduced product 13 in high yield.81... 

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