Ketones, catalytic hydrogenation

For most laboratory-scale reductions of aldehydes and ketones, catalytic hydrogenation has been replaced by methods based on metal hydride reducing agents. The two most common reagents are sodium borohydride and lithium aluminum hydride. 

This most versatile of amine syntheses can be used to make primary, secondary or tertiary amines providing only that an imine can be formed with an aldehyde or ketone. But tertiary carbon atoms cannot be joined to nitrogen by reductive amination as a tertiary carbon atom cannot have a carbonyl group. The method works by selective reduction of the imine 28 in the presence of the aldehyde 27 or ketone. Catalytic hydrogenation reduces the imine 28 preferentially as the C=N bond of the imine is weaker than the C—O bond of the aldehyde or ketone. 

Alkylphosphonate esters. The carbanion generated from dechlorination with BuLi condenses with aldehydes (and some ketones). Catalytic hydrogenation of the (chlorovinyl)phosphonate products affords phosphonates. 

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... 

A class of nitrogen containing compounds that was omitted from the section just dis cussed includes mines and their derivatives Immes are formed by the reaction of aide hydes and ketones with ammonia Immes can be reduced to primary amines by catalytic hydrogenation... 

DIBK can be produced by the hydrogenation of phorone which, in turn, is produced by the acid-catalyzed aldol condensation of acetone. It is also a by-product in the manufacture of methyl isobutyl ketone. Diisobutyl ketone ( 1.37/kg, October 1994) is produced in the United States by Union Carbide (Institute, West Virginia) and Eastman (Kingsport, Teimessee) (47), and is mainly used as a coating solvent. Catalytic hydrogenation of diisobutyl ketone produces the alcohol 2,6-dimethyl-4-heptanol [108-82-7]. 

Reaction of (T)-(-)-2-acetoxysuccinyl chloride (78), prepared from (5)-mahc acid, using the magnesiobromide salt of monomethyl malonate afforded the dioxosuberate (79) which was cyclized with magnesium carbonate to a 4 1 mixture of cyclopentenone (80) and the 5-acetoxy isomer. Catalytic hydrogenation of (80) gave (81) having the thermodynamically favored aH-trans stereochemistry. Ketone reduction and hydrolysis produced the bicycHc lactone acid (82) which was converted to the Corey aldehyde equivalent (83). A number of other approaches have been described (108). 

The N,]S -dialkyl-/)-PDAs are manufactured by reductively alkylating -PDA with ketones. Alternatively, these compounds can be prepared from the ketone and -lutroaruline with catalytic hydrogenation. The /V-alkyl-/V-aryl- -PDAs are made by reductively alkylating -nitro-, -nitroso-, or /)-aminodipheny1 amine with ketones. The AijAT-dialkyl- PDAs are made by condensing various anilines with hydroquinone in the presence of an acid catalyst (see Amines-aromatic,phenylenediamines). 

Photoketone (118) has served as the key intermediate in a relatively simple transformation of 3-keto-10/ -steroids to 3-keto-lOa-isomers without the assistance of other functional groups suitably situated next to the ring junction—a task that appears difficult to attempt by other methods. Optimal yields of (118) are achieved by catalytic hydrogenation of the unsaturated ketone (175), the photoisomer of 1-dehydrotestosterone acetate (see section III-C). In this way, a 6-step conversion of 1-dehydrotestosterone acetate (174) to IOa-testosterone acetate (127 acetate) is achieved in good yield. ° ... 

Reductive amination (Section 22.10) Method for the preparation of amines in which an aldehyde or a ketone is treated with ammonia or an amine under conditions of catalytic hydrogenation. 

The use of primary amines instead of ammonia affords l,2-dialkyl-/l -pyrrolines or l,2-dialkyl-/l -piperideines. Amino ketones with a primary amino group are intermediates in the reduction of y-nitropropylalkyl ketones (14,15) or S-nitrobutylalkyl ketones (16-18) by catalytic hydrogenation over Raney nickel or with zinc and hydrochloric acid (Scheme 1). 

The intramolecular cyclization of enolate of l-tryptophyl-3-((3-ketobutyl) pyridinium bromide (160) afforded enamine 161, which undergoes stereoselective acid cyclization with cone. HCl to give the pentacyclic ketone 162 (Catalytic hydrogenation of 162 led to (d,l)-pseudoyohimbone (163) (76JA3645). Again, H3-H15 were found to have the tmns configuration in 162. 

In much the same vein, the Mannich product from acetophenone with formaldehyde and pyrrolidine (44b) affords procyclidine (49) Dn reaction with cyclohexylmagnesium bromide. In an interesting variation, the ketone is first reacted with phenylmagnesium bromide. Catalytic hydrogenation of the carbinol (50) thus obtained iTin be stopped after the reduction of only one aromatic ring. ... 

Acylation of ami noketone 8 with the acid chloride from p-toluic acid affords the corresponding ester (10) catalytic hydrogenation leads to the bronchodilator bitolerol (11). An analogous scheme starting from the N-methyl ketone (12) and pivaloyl chloride gives ami noalcohol (14). This compound is then resolved to isolate the levorotatory isomer. There is thus obtained the drug dipivefrin. 

Synthesis of the prototype begins with Friedel Crafts acetylation of salicylamide ( ). Bromination of the ketone (25) followed by displacement with amine gives the corresponding ami noketone ( ). Catalytic hydrogenation to the ami noalcohol completes the synthesis of labetolol (24). The presence of two chiral centers at remote positions leads to the two diastereomers being obtained in essentially equal amounts. 

Note that the Wolff-Kishner reduction accomplishes the same overall trans-fonnation as the catalytic hydrogenation of an acylbenzene to yield an alkyl-benzene (Section 16.10). The Wolff-Kishner reduction is more general and more useful than catalytic hydrogenation, however, because it works well with both alkyl and atyl ketones. 

We can extend this kind of reasoning even further by imagining that subsequent transformations might be carried out on the aldol products. For example, a saturated ketone might be prepared by catalytic hydrogenation of the enone product. A good example can be found in the industrial preparation of 2-ethyl-... 

The enantiomerically pure (/ )- and (iS )-ketones are prepared from the corresponding enantiomer of mandelic acid by catalytic hydrogenation, treatment of the resulting hexahydroman-delic acid with ethyllithium, and subsequent introduction of the silyl protecting group33. 

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