Sodium borohydride pyridines

Sodium borohydride-Pyridine, 360 Sodium bromate, 81 Sodium-Chlorotrimethylsilane, 356 Sodium cyanoborohydride, 33, 168, 236,... 

Both furospongin-2 (72) and its A -c/5-isomer isofurospongin-2 (73), distinguishable by the resonances of the 13-methyl signals in their n.m.r. spectra (5 2.11 in the spectrum of 72, and 1.83 in the spectrum of 73), gave, on sodium borohydride-pyridine reduction, an alcohol identical with furospongin-1 (70). 

Reduction. Quinoline may be reduced rather selectively, depending on the reaction conditions. Raney nickel at 70—100°C and 6—7 MPa (60—70 atm) results in a 70% yield of 1,2,3,4-tetrahydroquinoline (32). Temperatures of 210—270°C produce only a slightly lower yield of decahydroquinoline [2051-28-7]. Catalytic reduction with platinum oxide in strongly acidic solution at ambient temperature and moderate pressure also gives a 70% yield of 5,6,7,8-tetrahydroquinoline [10500-57-9] (33). Further reduction of this material with sodium—ethanol produces 90% of /ra/ j -decahydroquinoline [767-92-0] (34). Reductions of the quinoline heterocycHc ring accompanied by alkylation have been reported (35). Yields vary widely sodium borohydride—acetic acid gives 17% of l,2,3,4-tetrahydro-l-(trifluoromethyl)quinoline [57928-03-7] and 79% of 1,2,3,4-tetrahydro-l-isopropylquinoline [21863-25-2]. This latter compound is obtained in the presence of acetone the use of cyanoborohydride reduces the pyridine ring without alkylation. 

A solution of 7.2 g of sodium borohydride (analyzing at 87 % purity) in 300 ml of pyridine is added dropwise, with vigorous stirring, over 7 hr to a solution of 50 g of pregnane-3,11,20-trione in 100 ml of pyridine and 18 ml of water. The temperature is kept at 18-20°. The stirring at this temperature is continued for another 2 hr, after which the reaction mixture is poured slowly into dilute hydrochloric acid (575 ml of cone hydrochloric acid in 5.2 liters of water) and the stirring continued for 1 hr. The precipitate is filtered, washed with... 

The azidohydrins obtained by azide ion opening of epoxides, except for those possessing a tertiary hydroxy group, can be readily converted to azido mesylates on treatment with pyridine/methanesulfonyl chloride. Reduction and subsequent aziridine formation results upon reaction with hydrazine/ Raney nickel, lithium aluminum hydride, or sodium borohydride/cobalt(II)... 

Dihydro- and 1,4-dihydro derivatives are formed as intermediates in the reduction of quaternary pyridine salts and their homologues with sodium borohydride or formic acid. A proton is added to the present enamine grouping and the formed immonium salts are reduced to the l-methyl-l,2,5,6-tetrahydropyridine derivatives (157) and to completely saturated compounds (158) (254) (Scheme 14). 

Quatemization of pyridine derivatives 271 with methyl iodide in acetone gave salts, which were reduced with sodium borohydride to tetrahydropyridines 272... 

The key intermediate 21 is in principle accessible in any of several ways. Thus reaction of thiophenecarbox-aldehyde with amninoacetal would lead to the Schiff base 20 treatment with acid would result in formation of the fused thiophene-pyridine ring (21). Alkylation of that intermediate with benzyl chloride gives the corresponding ternary imini urn salt 23. Treatment with sodium borohydride leads to reduction of the quinolinium ring and thus formation of ticlopidine (24). ... 

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. 

Preparation of the acetate derivative Concentrate the aqueous mixture of saccharides to approximately 0.5 ml in a 20-50 ml container. Reduce the saccharides by adding 20 mg of sodium borohydride that has been dissolved carefully into 0.5 ml of water and let the reducing mixture stand at room temperature for at least 1 hour. Destroy the excess sodium borohydride by adding acetic acid until the gas evolution stops. Evaporate the solution to dryness with clean nitrogen. Add 10 ml of methanol and evaporate the solution to dryness. Acetylate with 0.5 ml (three parts acetic anhydride and two parts pyridine) overnight. Evaporate to a syrupy residue and add 1 ml of water. Evaporate again to dryness to remove the excess acetic anhydride. Dissolve the residue in 250 /d methylene chloride. 

Carba-sugars of the a-L-altro and P-D-gluco modifications were prepared from 149 by way of 155. 0-Mesylation of 155 with an excess of mesyl chloride and pyridine resulted in formation of the cyclohexenealdehyde 159, accompanied by y -elimination. Reduction of 159 with sodium borohydride gave the cyclohexenemethanol 160, which is the antipode oP 141. 

Section V,F,3) was treated with trifluoroacetic anhydride in pyridine at room temperature followed by work-up with aqueous ammonia to rearrange to the spirobenzylisoquinoline 317 in 86% yield (Scheme 59). The product was reduced with sodium borohydride to afford ( )-raddeanine (318) which was also obtained similarly from the dihydroxyindenobenzazepin 319. 

Williams and Rastetter also accomplished an elegant synthesis of ( )-hyalodendrin (83) in 1980 [39]. Beginning with the sarcosine anhydride-derived enolic aldehyde 78, silyl protection of the enal enabled alkylation of the glycine center with benzyl bromide and thiolation using LDA and monoclinic sulfur a la Schmidt. After protection of the thiol with methylsulfenyl chloride and deprotection of the silyl ether, the enol was sulfenylated with triphenylmethyl chlorodisulfide to afford bis(disulfide) 82 as a 2 1 mixture of diastereomers favoring the anti isomer. Reduction of the disulfides with sodium borohydride and oxidation with KI3 in pyridine afforded ( )-hyalodendrin (83) in 29 % yield (Scheme 9.4). 

Another classic reaction of pyridinium salts is reduction of the pyridine ring. Donohoe and co-workers reported the partial reduction of A-alkylpyridinium salts <060BC1071>, which is accompanied by subsequent alkylation and hydrolysis to furnish a range of 2,3-dihydropyrid-4-ones. This sequence has the potential to introduce a variety of functional groups at the C-2 position of 2,3-dihydropyrid-4-ones. Reduction of pyridinium ylides with sodium borohydride has also been reported in fair to good yields <06JHC709>. 

Transformations of Methyl 5-0-Benzyl-2-0-methyl-/3-I)-glueofuranosidurono-6,3-lae-tone (86) to Dimethyl (Z,E)-2-Methoxy-5-(phenylmethoxy)-2,4-hexadienedioatevl (87). ( Elimination employing DBU b oxidation with silver oxide-sodium hydroxide followed by diazomethane esterification c acidic glycoside cleavage, oxidation by dimethyl sulfoxide-acetic anhydride with formation of 5-0-benzyl-2-0-methyI-D-glucaro-1,4 6,3-dilactone, elimination by using DBU, followed by short treatment with diazomethane d elimination by DBU with subsequent diazomethane esterification e sodium borohydride in hexamethylphosphoric triamide 1 catalytic oxidation followed by short treatment with diazomethane " dimethyl sulfoxide-sulfur trioxide-pyridine-triethylamine.150)... 

If the perhydrooxazolo[3,2- ]pyridine now possesses a nitrile at C-5, the aminonitrile can be reduced with sodium borohydride as exemplified in Scheme 89 <1998T8783>. Another option is to generate an intermediate iminium ion and to further reduce it with zinc borohydride <1998T8783>. 

Addition of lithiated heterocycles to aldonolactones yields carbon-linked nucleosides (56). Thus, the reaction of 2,3 5,6-di-O-isopropylidene-L-gu-lono-1,4-lactone (9b) or 2,3-O-isopropylidene-D-ribono-l,4-lactone (16a) with various lithiated heterocycles gave gulofuranosyl derivatives 53a-g or ribofuranosyl derivatives 54b,c. Gulonolactols 53a-g and ribonolactols 54b,c were acetylated with acetic anhydride in pyridine to yield their acetyl derivatives. The stereochemistry of compounds 53a-g and 54b,c was discussed in terms of the Cotton effect of circular-dichroism curves of the ring-opened alcohols formed upon reduction by sodium borohydride. The configuration at C-l of 53g was proved by means of X-ray analysis (57,58). 

It is quite difficult to reduce benzene or pyridine, because these are aromatic stmctures. However, partial reduction of the pyridine ring is possible by using complex metal hydrides on pyridinium salts. Hydride transfer from lithium aluminium hydride gives the 1,2-dihydro derivative, as predictable from the above comments. Sodium borohydride under aqueous conditions achieves a double reduction, giving the 1,2,5,6-tetrahydro derivative, because protonation through the unsaturated system is possible. The final reduction step requires catalytic hydrogenation (see Section 9.4.3). The reduction of pyridinium salts is of considerable biological importance (see Box 11.2). 

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]. 

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