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Ketones sodium borohydride

Potassium and sodium borohydride show greater selectivity in action than lithium aluminium hydride thus ketones or aldehydes may be reduced to alcohols whilst the cyano, nitro, amido and carbalkoxy groups remain unaffected. Furthermore, the reagent may be used in aqueous or aqueous-alcoholic solution. One simple application of its use will be described, viz., the reduction of m-nitrobenzaldehyde to m-nitrobenzyl alcohol ... [Pg.881]

For most laboratory scale reductions of aldehydes and ketones catalytic hydro genation has been replaced by methods based on metal hydride reducing agents The two most common reagents are sodium borohydride and lithium aluminum hydride... [Pg.628]

Sodium borohydride is especially easy to use needing only to be added to an aque ous or alcoholic solution of an aldehyde or a ketone... [Pg.628]

Sodium borohydride and lithium aluminum hydride react with carbonyl compounds in much the same way that Grignard reagents do except that they function as hydride donors rather than as carbanion sources Figure 15 2 outlines the general mechanism for the sodium borohydride reduction of an aldehyde or ketone (R2C=0) Two points are especially important about this process... [Pg.629]

The mechanism of lithium aluminum hydride reduction of aldehydes and ketones IS analogous to that of sodium borohydride except that the reduction and hydrolysis... [Pg.629]

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... [Pg.713]

Other Borohydrides. Potassium borohydride was formerly used in color reversal development of photographic film and was preferred over sodium borohydride because of its much lower hygroscopicity. Because other borohydrides are made from sodium borohydride, they are correspondingly more expensive. Generally their reducing properties are not sufficiently different to warrant the added cost. Zinc borohydride [17611-70-0] Zn(BH 2> however, has found many appHcations in stereoselective reductions. It is less basic than NaBH, but is not commercially available owing to poor thermal stabihty. It is usually prepared on site in an ether solvent. Zinc borohydride was initially appHed to stereoselective ketone reductions, especially in prostaglandin syntheses (36), and later to aldehydes, acid haHdes, and esters (37). [Pg.304]

A McMurry coupling of (176, X = O Y = /5H) provides ( )-9,ll-dehydroesterone methyl ether [1670-49-1] (177) in 56% yield. 9,11-Dehydroestrone methyl ether (177) can be converted to estrone methyl ether by stereoselective reduction of the C —double bond with triethyi silane in triduoroacetic acid. In turn, estrone methyl ether can be converted to estradiol methyl ether by sodium borohydride reduction of the C17 ketone (199,200). [Pg.436]

Since ivermectin (= 22,23-dihydroavermectin B ) is obtained by catalytic reduction of avermectin B, the same procedure using tritium gas convenientiy affords tritiated ivermectin (22,23- [JT]-22,23-dihydroavermectin B ). The preparation of a tritiated derivative containing a 22,23-double bond starts with the readily available 5-ketone, which is reduced with [JT]-sodium borohydride stereospecificaHy to a 5- [JT]-derivative (40). Carbon-14 labeled avermectins can be obtained by a biosynthetic process using sodium (l- C)propionate as labeled precursor (48). [Pg.284]

Greater selectivity in purification can often be achieved by making use of differences in chemical properties between the substance to be purified and the contaminants. Unwanted metal ions may be removed by precipitation in the presence of a collector (see p. 54). Sodium borohydride and other metal hydrides transform organic peroxides and carbonyl-containing impurities such as aldehydes and ketones in alcohols and ethers. Many classes of organic chemicals can be purified by conversion into suitable derivatives, followed by regeneration. This chapter describes relevant procedures. [Pg.53]

Potassium borohydride is similar in properties and reactions to sodium borohydride, and can similarly be used as a reducing agent for removing aldehydes, ketones and organic peroxides. It is non-hygroscopic and can be used in water, ethanol, methanol or water-alcohol mixtures, provided some alkali is added to minimise decomposition, but it is somewhat less soluble than sodium borohydride in most solvents. For example, the solubility of potassium borohydride in water at 25° is 19g per lOOmL of water (as compared to sodium borohydride, 55g). [Pg.56]

Table 8.3. Rates of Reduction of Aldehydes and Ketones by Sodium Borohydride... Table 8.3. Rates of Reduction of Aldehydes and Ketones by Sodium Borohydride...
A solution of 1 g of the ethyleneketal of the trione in 40 ml of methanol is treated with 0.2 g of sodium borohydride and the mixture is stirred at 20° for 2 hr. Slow drop wise addition of water precipitates the reaction product as crystals. These are filtered, washed with water and dried, to give 1.02 g of hydroxy ketone, which after crystallization from methylene dichloride-hexane has mp 182-184° (reported 184-186°) -23° (CHCI3). [Pg.95]

A solution of 0.25 g sodium borohydride in 140 ml of ethanol is added to a stirred solution of 0.56 g of calcium chloride in 60 ml of ethanol at —25°. The vigorously stirred mixture is treated dropwise at —25° over 5 min with 4.87 g of 1 la-hydroxy-5/S-pregnane-3,20-dione in 100 ml of ethanol. After a further 3 hr at —20°, 10 ml of 40% aqueous acetic acid is added and the mixture is evaporated to dryness under vacuum. The residue is dissolved in 150 ml of ether and the ethereal solution is washed with 30 ml of 2 A hydrochloric acid and twice with 30 ml of water and dried over Na2S04. Removal of the solvent gives 4.6 g of crystals, which are recrystallized from 20 ml of ether to yield 2.9 g (60%) of the dihydroxy ketone, mp 182-184° [aj 110° (ethanol). [Pg.97]

Enamines of A" -3-ketones (45) are stable to lithium aluminum hydride, but lithium borohydride reduces the 3,4-double bond of the enamine system." In the presence of acetic acid the enamine (45) is reduced by sodium borohydride to the A -3-amine (47) via the iminium cation (46). ... [Pg.386]

The success of the halo ketone route depends on the stereo- and regio-selectivity in the halo ketone synthesis, as well as on the stereochemistry of reduction of the bromo ketone. Lithium aluminum hydride or sodium borohydride are commonly used to reduce halo ketones to the /mm-halohydrins. However, carefully controlled reaction conditions or alternate reducing reagents, e.g., lithium borohydride, are often required to avoid reductive elimination of the halogen. [Pg.15]

The properties of chlorine azide resemble those of bromine azide. Pon-sold has taken advantage of the stronger carbon-chlorine bond, i.e., the resistance to elimination, in the chloro azide adducts and thus synthesized several steroidal aziridines. 5a-Chloro-6 -azidocholestan-3 -ol (101) can be converted into 5, 6 -iminocholestan-3l -ol (102) in almost quantitative yield with lithium aluminum hydride. It is noteworthy that this aziridine cannot be synthesized by the more general mesyloxyazide route. Addition of chlorine azide to testosterone followed by acetylation gives both a cis- and a trans-2iddMct from which 4/S-chloro-17/S-hydroxy-5a-azidoandrostan-3-one acetate (104) is obtained by fractional crystallization. In this case, sodium borohydride is used for the stereoselective reduction of the 3-ketone... [Pg.25]

FIGURE 15.2 Mechanism of sodium borohydride reduction of an aldehyde or ketone. [Pg.630]

Conjugate addition of methyl magnesium iodide in the presence of cuprous chloride to the enone (91) leads to the la-methyl product mesterolone (92) Although this is the thermodynamically unfavored axially disposed product, no possibility for isomerization exists in this case, since the ketone is once removed from this center. In an interesting synthesis of an oxa steroid, the enone (91) is first oxidized with lead tetraacetate the carbon at the 2 position is lost, affording the acid aldehyde. Reduction of this intermediate, also shown in the lactol form, with sodium borohydride affords the steroid lactone oxandrolone... [Pg.174]

In a similar vein, acylation of the corticoid 50 with furoyl chloride gives the diacyl derivative 51. Reduction with sodium borohydride serves to convert the 11-ketone to the alcohol 52. Hydrolysis under mild acid conditions preferentially removes the acyl group at the less hindered 21 position. The hydroxyl group in that derivative (53) is then converted to the mesylate 54. Replacement by chlorine affords mometasone (55) [12]. [Pg.73]

Ketones undergo a reduction when treated with sodium borohydride, NaBH What is the structure of the compound produced by reaction of 2-butanone with NaBH4 if it has an IR absorption at 3400 cm-1 and M+ = 74 in the mass spectrum ... [Pg.439]

Literally dozens of reagents are used in the laboratory to reduce aldehydes and ketones, depending on the circumstances, but sodium borohydride, NaBH4, is usually chosen because of its safety and ease of handling. Sodium borohydride... [Pg.609]

Sodium borohydride, reaction with ketones and aldehydes,... [Pg.1315]

The final stages of the successful drive towards amphotericin B (1) are presented in Scheme 19. Thus, compound 9 is obtained stereoselectively by sodium borohydride reduction of heptaenone 6a as previously described. The formation of the desired glycosida-tion product 81 could be achieved in dilute hexane solution in the presence of a catalytic amount PPTS. The by-product ortho ester 85 was also obtained in approximately an equimolar amount. Deacetylation of 81 at C-2, followed sequentially by oxidation and reduction leads, stereoselectively, to the desired hydroxy compound 83 via ketone 82. The configuration of each of the two hydroxylbearing stereocenters generated by reduction of carbonyls as shown in Scheme 19 (6—>9 and 82->83) were confirmed by conversion of 83 to amphotericin B derivative 5 and comparison with an... [Pg.446]


See other pages where Ketones sodium borohydride is mentioned: [Pg.137]    [Pg.137]    [Pg.213]    [Pg.303]    [Pg.438]    [Pg.439]    [Pg.283]    [Pg.79]    [Pg.170]    [Pg.55]    [Pg.62]    [Pg.92]    [Pg.483]    [Pg.42]    [Pg.141]    [Pg.99]    [Pg.33]    [Pg.4]    [Pg.242]    [Pg.443]    [Pg.16]   
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See also in sourсe #XX -- [ Pg.9 ]

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See also in sourсe #XX -- [ Pg.39 , Pg.40 , Pg.41 , Pg.42 , Pg.43 , Pg.49 , Pg.50 , Pg.51 , Pg.52 , Pg.53 ]

See also in sourсe #XX -- [ Pg.8 , Pg.9 ]

See also in sourсe #XX -- [ Pg.100 ]




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Ketone reduction with sodium borohydride

Ketones borohydride

Ketones conjugate reductions, sodium borohydride

Ketones reduction by sodium borohydride

Sodium Borohydride Reduction of an Aldehyde or Ketone

Sodium borohydride aliphatic ketones

Sodium borohydride cyclic ketone reduction

Sodium borohydride ketones, aryl

Sodium borohydride nitro ketones

Sodium borohydride of aldehydes and ketones

Sodium borohydride saturated ketones

Sodium borohydride selective ketone reduction

Sodium borohydride unsaturated ketones

Sodium borohydride, reaction with ketones

Sodium borohydride, reaction with ketones and aldehydes

Sodium ketones

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