Sodium borohydride, reaction with aldehydes

Sodium borohydride, reaction with ketones and aldehydes,... 

Sodium borohydride is one of the weakest hydride donors available. The feet that it can be used in water is evidence of this as more powerful hydride donors such as lithium aluminium hydride, LiAlI-fe, react violently with water. Sodium borohydride reacts with both aldehydes and ketones, though the reaction with ketones is slower for example, benzaldehyde is reduced about 400 times faster than acetophenone in isopropanol. 

Diselenanes (27) are available through the reactions of 1,3-propanediselenols with aldehydes and ketones in the presence of a Lewis acid such as zinc(II) chloride (Equation (3)) <85T4793, 93TL8517>. The diselenols are normally synthesized from the corresponding diselenocyanates by reduction with, for example, sodium borohydride, or with sodium in liquid ammonia <71BSB639>. 

Chitosan is a multi-nucleophilic polymer due to the presence of the NH2 and OH functional groups. The initial sites where substitution occurs are the more nucleophilic amino groups. However, the experimental conditions and protection of the NH2 groups reduces the intermolecular hydrogen bonding and creates space for water molecules to fill in and solvate the hydrophilic groups of the polymer backbone (Sashiwa and Shigemasa 1999). A -alkylated derivatives can be obtained by the treatment of chitosan with aldehydes or ketones via formation of Schiff base intermediates, aldimines (from reactions with aldehydes), or ketimines (from reactions with ketones) followed by reduction of the imine with sodium borohydride. 

In Chapter 19 (Section 19.2), lithium aluminum hydride and sodium borohydride reacted with ketones or aldehydes via acyl addition to reduce the carbonyl to the corresponding alcohol. This reaction is complicated by the presence of a conjugating n-bond. When cyclohexenone reacts with LiAlH4, the product is a mixture of cyclohexenol (66) and cyclohexanol (67). Cyclohexenol results from 1,2 addition of the hydride, but 67 results from 1,4 addition and 1,2 addition. 

Pyridoxal Derivatives. Various aldehydes of pyridoxal (Table 3) react with hemoglobin at sites that can be somewhat controlled by the state of oxygenation (36,59). It is thereby possible to achieve derivatives having a wide range of functional properties. The reaction, shown for PLP in Figure 3, involves first the formation of a Schiff s base between the amino groups of hemoglobin and the aldehyde(s) of the pyridoxal compound, followed by reduction of the Schiff s base with sodium borohydride, to yield a covalendy-linked pyridoxyl derivative in the form of a secondary amine. 

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). ... 

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). 

Sodium hydrogen telluride, (NaTeH), prepared in situ from the reaction of tellurium powder with an aqueous ethanol solution of sodium borohydride, is an effective reducing reagent for many functionalities, such as azide, sulfoxide, disulfide, activated C=C bonds, nitroxide, and so forth. Water is a convenient solvent for these transformations.28 A variety of functional groups including aldehydes, ketones, olefins, nitroxides, and azides are also reduced by sodium hypophosphite buffer solution.29... 

Nitromethylation of aldehydes has been carried out in a one pot procedure consisting of the Henry reaction, acetylation, and reduction with sodium borohydride, which provides a good method for the preparation of l-nitroalkanes.16b 79 It has been improved by several modifications. The initial condensation reaction is accelerated by use of KF and 18-crown-6 in isopropanol. Acetylation is effected with acetic anhydride at 25 °C and 4-dimethylaminopyridine (DMAP) as a catalyst. These mild conditions are compatible with various functional groups which are often... 

The Vilsmeier-Haack reaction of 2,6-dimethylimidazo[2,T. ][l,3,4]thiadiazole 169 gives aldehyde 170, which after reduction with sodium borohydride affords 2,6-dimethyl-5-hydroxymethylimidazo[2,TA [l,3,4]thiadiazole 171 (Scheme 2) <2000AF550, 2006BMC3069, 2006TL2811>. 

Phosphorylated allenes 195 (R1 = H or Me) are a source of secondary ( )-allylamines. The allenes are treated with an amine R2NH2 (R2 = t-Bu or 4-MeCgH4 and the products, which exist as equilibrium mixtures of enamines 196 and imines 197, are olefinated by successive reaction with methyllithium and an aldehyde R3CHO (R = i-Bu, 4-MeCgH4, PhCH2CH2 etc). Reduction with sodium borohydride finally yields the... 

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