Reduction potassium borohydride

Potassium borohydride reduction of runanine (17) yielded dihydro-runanine (24), the H-NMR spectrum of which (Table II) exhibited a triplet (64.25), the proton bearing the hydroxyl group coupling with those of C-5 (35). The optical activity of runanine (17), [a]D —400°, was similar to that of hasubanonine (5), [a]D —214° (3) therefore, it was concluded that the ethylamine linkage must have the same configuration as hasubanonine [C-13 (R) and C-14 (S)]. From these results, structure 17 was proposed for runanine (35) however, no application of mass spectral data to the structure elucidation was presented (35). 

The attack of the borohydride ion at the 4-position of pyridinium ions can be proved in the few instances in which the 1,4-dihydro-pyridines have been isolated. The dihydropyridine formed by the sodium or potassium borohydride reduction of 1-phenylpyridinium chloride (22) was shown to be a mixture of 20% 1,4- and 80% 1,2-... 

Chromatographic methods have also been developed for quantitative determination of the AUC of pectin. Uronic acids have been analyzed using gas-liquid chromatography (GLC) after conversion to L-galactono-1,4-lactone via potassium borohydride reduction and lactonization using methanolic hydrogen chloride. The derived lactone was then analyzed by GLC as the trimethylsilyl derivative (Perry... 

Epivoacristine (19-epivoacangarine) (mp 115° [a]p —55°inCHCl3) had spectrophotometric properties almost indistinguishable from voa-cristine (16). The only important difference was in the chemical shift, a doublet centered at 1.28 ppm (—CHOH-CHs) and found at 1.11 ppm in voacristine. This epi compound had previously been prepared by the potassium borohydride reduction of voacryptine (24). A conclusion as to the absolute configuration of the 19-hydroxyl was reached by using molecular rotation differences. 

In addition to a good yield of SnH4, the potassium borohydride reduction of stannite ion in solution produced the hydride distannane SnzH. This hydride may be distilled in a vacuum system without decomposition provided relatively low pressures are used, but if a vessel containing Sn2Hg is allowed to warm to room temperature it is completely... 

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). 

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... 

The reduction of iminium salts can be achieved by a variety of methods. Some of the methods have been studied primarily on quaternary salts of aromatic bases, but the results can be extrapolated to simple iminium salts in most cases. The reagents available for reduction of iminium salts are sodium amalgam (52), sodium hydrosulfite (5i), potassium borohydride (54,55), sodium borohydride (56,57), lithium aluminum hydride (5 ), formic acid (59-63), H, and platinum oxide (47). The scope and mechanism of reduction of nitrogen heterocycles with complex metal hydrides has been recently reviewed (5,64), and will be presented here only briefly. 

The tosylhydrazone is prepared from the carbonyl compound and then reduced with lithium aluminium hydride, sodium borohydride or potassium borohydride. In this way D-glucose tosylhydrazone was converted into crystalline 1-deoxyglucitol by reduction with potassium borohydride... 

Colloidal metals are usually prepared by reduction of a salt with a reducing agent, such as phosphorus, acetone, tannin, or carbon monoxide. Platinum metals can also be prepared as finely divided very active blacks by reducing the metal salt in an aqueous solution of sodium or potassium borohydride. 

Nickel borides are usually prepared by reduction of nickel salts with sodium or potassium borohydride. Two types are used. PI nickel boride is prepared by the reaction between aqueous solutions of nickel salts and a borohy-... 

Ye et al. reported that the reduction of 2,4-dichlorophenyl-2-chloroethanone 1 with potassium borohydride in dimethylformamide to give 90% a-chloromethyl-2,4-dichlorobenzyl alcohol 2. Alkylation of imidazole with compound 2 in dimethyl formamide in the presence of sodium hydroxide and triethylbenzyl ammonium chloride, gave l-(2,4-dichlorophenyl-2-imidazolyl)ethanol 3 and etherification of 3 with 2,4-dichlorobenzyl chloride under the same condition, 62% yield of miconazole [9]. 

The MPT model was also reported to apply in a number other electroless metal deposition systems, including a) electroless Ni from a citrate-complexant solution with dimethylamine borane (DMAB) reductant, operated at pH = 7 (pH adjusted using NH4OH) and at a temperature (T) = 40 °C [33] b) electroless Au deposition [34] from a KAu(CN)2 containing solution, which utilized potassium borohydride... 

The importance of reactions with complex, metal hydrides in carbohydrate chemistry is well documented by a vast number of publications that deal mainly with reduction of carbonyl groups, N- and O-acyl functions, lactones, azides, and epoxides, as well as with reactions of sulfonic esters. With rare exceptions, lithium aluminum hydride and lithium, sodium, or potassium borohydride are the... 

According to another approach, treatment of A-[2-(indol-3-yl)ethyl]-l,2,5,6-tetrahydropyridine (137), obtained from the corresponding pyridinium salt 136 by borohydride reduction, first with potassium rerf-butoxide, and then with acetic acid, led to ( )-l via key intermediate 135 in 78% yield (102). 

The optimal reaction conditions for the generation of the hydrides can be quite different for the various elements. The type of acid and its concentration in the sample solution often have a marked effect on sensitivity. Additional complications arise because many of the hydrideforming elements exist in two oxidation states which are not equally amenable to borohydride reduction. For example, potassium iodide is often used to pre-reduce AsV and SbV to the 3+ oxidation state for maximum sensitivity, but this can also cause reduction of Se IV to elemental selenium from which no hydride is formed. For this and other reasons Thompson et al. [132] found it necessary to develop a separate procedure for the determination of selenium in soils and sediments although arsenic, antimony and bismuth could be determined simultaneously [133]. A method for simultaneous determination of As III, Sb III and Se IV has been reported in which the problem of reduction of Se IV to Se O by potassium iodide was circumvented by adding the potassium iodide after the addition of sodium borohydride [134], Goulden et al. [123] have reported the simultaneous determination of arsenic, antimony, selenium, tin and bismuth, but it appears that in this case the generation of arsine and stibene occurs from the 5+ oxidation state. 

A useful method for the reductive conversion of elemental tellurium into Te anions employs complex hydrides such as sodium or potassium borohydride and tetraalkyl ammonium borohydride as reducing agents. 

Reaction of vindoline (3) with the chloroindolenines derived from vin-cadifformine (127a), iJ -vincadifformine (133), -tabersonine (133a), or synthetic pandoline (34) (7/5, 116), followed by reduction of the resulting imines 145 and 145a (Scheme 40) with potassium borohydride, had given... 

Reaction of the imine-indoline products 157 and 158 with potassium borohydride in acetic acid resulted in rupture of the C-3 -C-7 bond and reduction of the resulting imonium function (Scheme 45). While the initial C-I6 -C-14 PARF imine-indolines 157 and 158 can be isolated, they are less stable on silica gel chromatography than the corresponding l -vincad-ifformine-derived C-16 -C-14 PREF compounds 145, and consequently purification of the vindoline coupling products and separation of dia-stereomers were best carried out at the indole-indoline stage (162, 163). 

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]. 

Ketimines are reduced to amines very easily by catalytic hydrogenation, by complex hydrides and by formic acid. They are intermediates in reductive amination of ketones (p. 134). An example of the reduction of a ketimine is conversion of 3-aminocarbonyl-2,3-diphenylazirine to the corresponding aziridine by sodium borohydride (yield 73%), by potassium borohydride (yield 71%) and by sodium bis (2-methoxyethoxy) aluminum hydride (yield 71%) [939]. 

Bobowsky and Shavel found an interesting intramolecular reductive transacylation reaction, in which substituted cyclopent[e][l,3]oxazin-2-ones and l,3-perhydrobenzoxazin-2-ones (90) were formed (80JHC277). In the reactions of 4-(2 -oxocycloalkyl)-3,4-dihydro-3-methyl-2//-l,3-benzoxazin-2-ones 88 and potassium borohydride, the 2 -hydroxycycloalkyl products 89 obtained underwent intramolecular transacylation reactions, resulting in the dihydro-1,3-oxazine derivatives 90. In this way, the 4-(2 -oxocycloalkyl)... 

Reticuline (38), one of the most important intermediates in the biosynthesis of opium alkaloids, has been synthesized in racemic form (Scheme 7) (78). 6-Methoxy-7-benzyloxyisoquinoline (39), prepared from O-benzylisovanillin via a modified Pomeranz-Fritsch isoquinoline synthesis, was treated with benzoyl chloride and potassium cyanide to obtain Reissert compound 40. Alkylation of the anion generated from 40 with 3-benzyloxy-4-methoxybenzyl chloride gave the corresponding 1-substituted Reissert compound 41 which was hydrolyzed in alkaline medium to 1-benzylisoquinoline derivative 42. Quatemarization of 42 with methyl iodide followed by sodium borohydride reduction and debenzylation led to ( )-reticuline (38) in about 25% overall yield from 39. 

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