Sodium borohydride reduction with

Sodium bisulphite reagent, 332 Sodium borohydride, reductions with, 881-882... 

Hyperforin is not reduced by sodium borohydride. Reduction with hydride-transfer reagents such as lithium aluminium hydride (LAH), RED-AL, and DIBAL-H, gave varied products in good yields. Its two dicarbonyl systems are amenable to reduction or deoxygenation upon treatment with alane reducing agents and pave the way to new and interesting modifications of the natural product.301... 

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... 

Nucleophilic addition to carbonyl groups sometimes leads to a mixture of stereoisomeric products The direction of attack is often controlled by stenc factors with the nude ophile approaching the carbonyl group at its less hindered face Sodium borohydride reduction of 7 7 dimethylbicyclo[2 2 IJheptan 2 one illustrates this point... 

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). 

The reduction of 3,5-diphenylisoxazoline with sodium cyanoborohydride produced a mixture of isomeric 3,5-diphenylisoxazolidines. The H and NMR spectra were utilized to distinguish the isomers SOLAIOI). Sodium borohydride reductions likewise reduce isoxazolines to isoxazolidines (equation 56) (80JA4265). 

The carbonyl group of carbohydrates can be reduced to an alcohol function. Typical procedures include catalytic hydrogenation and sodium borohydride reduction. Lithium aluminum hydride is not suitable, because it is not compatible with the solvents (water, alcohols) that are requited to dissolve caibohydrates. The products of caibohydrate reduction aie called alditols. Because these alditols lack a car bonyl group, they aie, of course, incapable of forming cyclic hemiacetals and exist exclusively in noncyclic forms. 

Friedel-Crafts alkylation of 8-hydroxycarbostyrils, such as leads to substitution at the C-5 position, namely, In this case an a-haloacyl reagent is employed. Displacement with isopropylamine and careful sodium borohydride reduction (care is... 

This was converted to its imine with methylamine catalyzed by titanium tetrachloride and then sodium borohydride reduction produced 17 as a mixture of diastereomers. This was resolved by column chromatography to give sertraline [5]. Dextrorotatory cis sertraline is substantially more potent than its isomers. 

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... 

All that remains before the final destination is reached is the introduction of the C-l3 oxygen and attachment of the side chain. A simple oxidation of compound 4 with pyridinium chlorochro-mate (PCC) provides the desired A-ring enone in 75 % yield via a regioselective allylic oxidation. Sodium borohydride reduction of the latter compound then leads to the desired 13a-hydroxy compound 2 (83% yield). Sequential treatment of 2 with sodium bis(trimethylsilyl)amide and /(-lactam 3 according to the Ojima-Holton method36 provides taxol bis(triethylsilyl ether) (86 % yield, based on 89% conversion) from which taxol (1) can be liberated, in 80 % yield, by exposure to HF pyridine in THF at room temperature. Thus the total synthesis of (-)-taxol (1) was accomplished. 

Sodium borohydride reductions of gold(I) complexes give Au clusters at RT if sodium borohydride in ethanol is dropped slowly into a suspension of the Au(I) complex in the same solvent. The immediate coloring of the reaction mixture (mostly red), even after only a few drops of the borohydride have been added, indicates fast formation of Au clusters. In view of the complicated composition of these compounds the fast formation is surprising. The use of H2 and CO with HjO as reducing agents in the synthesis of gold clusters has been described (see Table 1, Method A, 8.2.2.2). 

The reaction of the aldehyde 174, prepared from D-glucose diethyl dithio-acetal by way of compounds 172 and 173, with lithium dimethyl methyl-phosphonate gave the adduct 175. Conversion of 175 into compound 176, followed by oxidation with dimethyl sulfoxide-oxalyl chloride, provided diketone 177. Cyclization of 177 with ethyldiisopropylamine gave the enone 178, which furnished compounds 179 and 180 on sodium borohydride reduction. 0-Desilylation, catalytic hydrogenation, 0-debenzyIation, and acetylation converted 179 into the pentaacetate 93 and 5a-carba-a-L-ido-pyranose pentaacetate (181). 

The first conversion of protoberberines to phthalideisoquinoline alkaloids was achieved by Moniot and Shamma (88,89). 8-Methoxyberberinephenol-betaine (131), derived from berberine (15) (Section III,B,2), is an attractive compound having a carboxyl group masked as an imino ether in ring B. The masking was uncovered by hydration with water-saturated ether to furnish dehydronorhydrastine methyl ester (367) (Scheme 65). On N-methylation (68%) and subsequent sodium borohydride reduction (90%), 367 provided (+ )-/ -hydrastine (368) and ( )-a-hydrastine (369) in a 2 1 ratio. Compound 367 was converted to dehydrohydrastine (370), which also afforded 368 and 369 by catalytic hydrogenation. 

Keto acids can be dehydrated to enol lactones (Section III,A,1). They may also undergo esterification with alcohols e.g., /V-methylhydrasteine (104) in methanol at room temperature gave the expected keto ester 126 (R + R = CH2, R1 = CH3) (5,87). Sodium borohydride reduction of keto acid 104 supplies the saturated y-lactone 132 identical with that obtained from enol lactone 98 (5). 

The structure of narlumidine (119) was established by Dasgupta et al. (117,119) on the basis of spectral data, particularly by comparison with spectra of bicucullinine (108), and also on chemical grounds. On hydrolysis followed by oxidation-methylation, narlumidine (119) was converted to ester 147, which was also obtained from 108 by N.O-methylation. Sodium borohydride reduction gave lactone 145, identical to the lactone obtained from 108. 

Several syntheses of secoquettamines have been performed. Seco compounds 234 and 235 were semisynthesized from quettamine (236) by Hofmann and Emde degradations, respectively (179). Chattopadhyay and Shamma (184) conducted a total synthesis of these bases with the intermediacy of quettamine (236) (Scheme 36). In this approach Reissert compound 237 served as substrate. On reaction with 4-benzyloxybenzaldehyde 237 supplied the addition product 238, which after N-methylation and sodium borohydride reduction afforded amino carbinol 239. Compound 239 was cyclized to... 

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