Reduction reactions borohydride

This is not strictly correct, in that hydride, from say sodium hydride, never acts as a nucleophile, but because of its small size and high charge density it always acts as a base. Nevertheless, there are a number of complex metal hydrides such as lithium aluminium hydride (LiAlHj LAH) and sodium borohydride (NaBH4) that deliver hydride in such a manner that it appears to act as a nucleophile. We have already met these reagents under nucleophilic substitution reactions (see Section 6.3.5). Hydride is also a very poor leaving group, so hydride reduction reactions are also irreversible (see Section 7.1.2). 

Enzymes can also undergo other side reactions under conditions that divert a chemically reactive intermediate from its usual catalytic function. Again, glutamine synthetase is an excellent example (see figure above), because its side reactions include acyl-phosphate reduction by borohydride, pyroglutamate formation, and the formation of y-glutamyl hydroxamate in the presence of hydroxylamine and arsenate. 

Peroxynitrite reacts with the active site of superoxide dismutase (SOD) to form a nitronium-like species (Fig. 37), analogous to the Fe EDTA reactions described earlier. However, copper in the active site of superoxide dismutase was necessary for the formation of the adduct. Removing copper from the active site by reduction with borohydride and dialysis against 50 mM KCN resulted in no adduct being formed, while restoration of copper to the active site gave back full enzyme activity. To account for the essential role of copper in the active site and the subsequent formation of 3-nitrotyrosine located 18-21 A distal from the active site, we proposed that peroxynitrite is attracted by the same electrostatic force field that draws superoxide into the active site (Beckman et al., 1992 Ischiropoulos et al., 1992b). Peroxynitrite appears to bind to copper in the active site to form a transient cuprous adduct as shown. 

Reduction reactions of nickel(If) compounds. The reduction of nickel(II) compounds to yield nickel(0) phosphine complexes has been carried out using a variety of reducing agents such as sodium amalgam, sodium sand, sodium borohydride, sodium naphthalenide and aluminum trialkyls. In some cases the phosphine ligand itself was found to act as the reducing agent. 

Oxidation reactions r-Butyl hydroperoxide-Dialkyl tar-trate-Titanium(IV) isopropoxide, 51 m-Chloroperbenzoic acid, 76 Reduction reactions Chlorodiisopinocampheylborane, 72 Diisobutylaluminum hydride-Tin(II) chloride- (S) -1 - [ l-Methyl-2-pyrrolidi-nyljmethylpiperidine, 116 Lithium borohydride, 92 Lithium tri-sec-butylborohydride, 21 B-3-Pinanyl-9-borabicyclo[3.3.1]-nonane, 249... 

The Cannizzaro reaction, that is, the base-catalysed disproportionation of a carbonyl compound to an alcohol and a carboxylic acid, has gained some importance as an economically viable alternative to the reduction with borohydrides. However, the reaction is restricted to carbonyl compounds without any a-hydrogen, which do not undergo competing aldol reactions. Thus, mainly aromatic aldehydes are used for this kind of transformation. The protocols developed for microwave applications typically involve solvent-free conditions using alumina as the solid support. Under these conditions, a significant acceleration of the reaction was achieved. 

Liquid injection molding, for silicone rubbers, 3, 674—675 Liquid ligands, in metal vapor synthesis, 1, 229 Liquid-phase catalysis, supported, for green olefin hydroformylation, 12, 855 Lithiacarbaboranes, preparation, 3, 114 Lithiation, arene chromium tricarbonyls, 5, 236 Lithium aluminum amides, reactions, 3, 282 Lithium aluminum hydride, for alcohol reductions, 3, 279 Lithium borohydride, in hydroborations, 9, 158 Lithium gallium hydride, in reduction reactions, 9, 738 Lithium indium hydride, in carbonyl reductions, 9, 713—714... 

In addition to the hydration reaction described in Section 11.3, the oxymercuration-reduction reaction can be used to add the elements of water to a carbon-carbon double bond in a two-step process. First the alkene is reacted with mercuric acetate, Hg(02CCH3)2, in water, followed by treatment with sodium borohydride in sodium hydroxide solution ... 

Which sugar alcohols can you identify on your chromatogram Was the reduction reaction with sodium borohydride complete Explain. 

The following data were obtained in a sodium borohydride reduction reaction as performed in this experiment. The reaction contained a single carbohydrate and the 14C-labeled internal control ... 

Gallenbeck et al. (25) has summarized the work on reductive alkylation using formaldehyde and sodium borohydride to yield dimethylated proteins. Oxidation and reduction reactions involving thiol and disulfide groups have been discussed by Ryan (13) and Feeney (11). 

The reagent is prepared by reaction or toluene with hexane, ng agent comparable to other lithium VC 1,2-rcduction of enoncs. Reduction proceeds at —78°. However, ketones cr. Esters arc reduced to a mixture of in alcohol can be effected by reduction sodium borohydride. Tertiary amides Ics in generally high yield. Selective ondary halides is possible. 

The behavior of 3-acetyl-l,2,5 thiadiazole (87) in several reduction reactions was also studied. The Leukart reaction produced the expected product, l-[3-(l,2,5-thiadiazolyl)]ethylamine, but the Wolff-Kishner reaction failed to yield any ethylthiadiazole under various conditions examined. Sodium borohydride smoothly reduced both acetyl- and benzoylthiadiazole to the corresponding carbinols. 

Another potential side reaction of the enediol(ate) intermediate is formation of the dicarbonyl compound, l-deoxy-D-glycero-2,3-pentodiulose 5-phosphate, resulting from p-elimination of the Cl-phosphate due to improper stabilization and/or premature dissociation of enediol(ate) from the enzyme active site. This compound has been characterized by reduction with borohydride, oxidation with H2O2, complexation with o-phenylenediamine, and 13C-NMR (23, 34). The p-elimination product is not detected in reactions with wild-type R. rubrum Rubisco but is formed in substantial amounts with mutants in which the Cl-phosphate ligands are substituted, demonstrating the required role of these amino acid side chains in stabilizing the enediol(ate) intermediate (34-35). 

Figure 2. Product analysis of K329A turnover reactions in the absence of amine (A) or in the presence of 400 mM ethylamine (B). Other reaction constituents at pH 8 were 20 pM K329A protomer, 1 mM EDTA, 10 mM MgCl2, 415 mM bicine, 19.6 mM NaHC03, 10% glycerol, and 250 pM [l- H]RuBP. Reactions were quenched after 4 h by reduction with borohydride.

Conversion of keto and quinone groups to hydroxyl and phenol groups by sodium borohydride reduction is a possible approach toward decreasing hydrogen bonding by conversion of basic functional groups to weak-acid groups that become the predominant characteristic after reduction. Sodium borohydride reduction is performed under conditions shown in reaction (5) ... 

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