Benzylic alcohols reduction

Decy 1-5-methoxy-1 -naphthol reduction procedure, benzyl alcohol reduction, 121... 

Ring-substituted benzyl alcohols, reduction reactions, 18... 

The diversity of the products obtained by the three-component domino-Knoevenagel-hetero-Diels-Alder reaction can be further increased by a different work-up of the formed cycloadduct 141. Thus, hydrogenolytic removal of the Cbz-group in 141 led to 151 with a lactam and an aldehyde moiety by reaction of the formed secondary amine with the lactone moiety followed by elimination of benzyl alcohol. Reduction of 151 with lithium aluminum hydride gave benzoquinolizidine 152 (Scheme 5.30). Alkaloids of this type have so far not been found in nature, but it can be assumed that they might exist, since they could easily be formed from deacetylisopecoside 153, which is an intermediate in the biosynthesis of emetine 111. 

The only industrially important processes for the manufacturing of synthetic benzaldehyde involve the hydrolysis of benzal chloride [98-87-3] and the air oxidation of toluene. The hydrolysis of benzal chloride, which is produced by the side-chain chlorination of toluene, is the older of the two processes. It is no longer utilized ia the United States. Other processes, including the oxidation of benzyl alcohol, the reduction of benzoyl chloride, and the reaction of carbon monoxide and benzene, have been utilized ia the past, but they no longer have any iadustrial appHcation. 

Certain functional groups may be protected from reduction by conversion to anions that resist reduction. Such anions include the alkoxides of allylic and benzylic alcohols, phenoxide ions, mercaptide ions, acetylide ions, ketone carbanions, and carboxylate ions. Except for the carboxylate, phenoxide, and mercaptide ions, these anions are sufficiently basic to be proton-ated by an alcohol, so they are useful for protective purposes only in the... 

The use of benzyl alcohol as solvent produces the dibenzyl acetal at C-21, and this can be reductively removed to produce the 21-hydroxy compound... 

Displacement of bromine on phenacyl halide with imidazole gives Reduction with sodium borohydride followed by displacement with 2,6-dichloro-benzyl alcohol in HMPA then produces antifungal orconazole (37). ... 

An unusual by-product was obtained in small yield in palladium-catalyzed reduction of 2-amino-4,5-dimethoxyindanone hydrochloride, The reduction was done in two stages first, a rapid absorption of 1 mol of hydrogen at 38 C to give the amino alcohol, and then a much slower reduction in the presence of HCIO4 at 70 "C. The rearranged by-product was shown to arise from attack of acid on the amino alcohol (50), Resistance to hydrogenolysis is characteristic of / -amino aromatic alcohols (56), a fact that makes reduction of aromatic oximino ketones to amino benzyl alcohols a useful synthetic reaction. 

In general, an ethyl(monoalkoxy)zinc is formed with amino alcohols6. Therefore, in the presence of an equimolar amount of chiral amino alcohol, a slow reduction of benzaldehyde to benzyl alcohol is observed rather than alkylation1. Alkylation only occurs with a ratio of diethylzinc to amino alcohol greater than equimolar. Consequently, a two-zinc species is postulated to be the actual catalyst1, n. 

The chemistry of indium metal is the subject of current investigation, especially since the reactions induced by it can be performed in aqueous solution.15 The selective reductions of ethyl 4-nitrobenzoate (entry 1), 2-nitrobenzyl alcohol (entry 2), l-bromo-4-nitrobenzene (entry 3), 4-nitrocinnamyl alcohol (entry 4), 4-nitrobenzonitrile (entry 5), 4-nitrobenzamide (entry 6), 4-nitroanisole (entry 7), and 2-nitrofluorenone (entry 8) with indium metal in the presence of ammonium chloride using aqueous ethanol were performed and the corresponding amines were produced in good yield. These results indicate a useful selectivity in the reduction procedure. For example, ester, nitrile, bromo, amide, benzylic ketone, benzylic alcohol, aromatic ether, and unsaturated bonds remained unaffected during this transformation. Many of the previous methods produce a mixture of compounds. Other metals like zinc, tin, and iron usually require acid-catalysts for the activation process, with resultant problems of waste disposal. 

The mechanisms of most alcohol reductions are obscure. Hydrogenolysis of benzyl alcohols can give inversion or retention of configuration, depending on the catalyst. - ... 

However, none of these compounds can be easily resolved except TM (16) Itself. Me prefer to resolve as early as possible, (page T 94), so It is better to carry out the Diels-Alder reaction with acrylic acid and resolve acid (19) before adding the phenyl group by a Grignard reaction. The benzylic alcohol group in (20) can be taken out by metal-anunonia reduction. Syrithesis ... 

Synthetic routes that access appropriately substituted thienobenzazepines are also quite important for medicinal chemistry stracture activity relationship studies, and many involve similar bond connectivity strategies. One notable example employs the use of conunercially available 4-methyl-3-nitrophenol (Scheme 6.3). Methylation of the phenol followed by bromination, hydrolysis, and oxidation of the benzylic alcohol afforded aldehyde 9 in quantitative yield. Treatment of this aldehyde with 5-lithio-2-methylthiophene provided, after dehydroxylation, nitro intermediate A in good overall yield. Reduction of the nitro functionality and treatment with phosgene presented the corresponding isocyanide which upon cychzation using aluminum trichloride in a Friedel-Crafts fashion afforded the... 

Shenlin Huang has implemented method C with 2,4-bis-OBoc-3-bromobenzyaldehyde 27 (Fig. 4.22) and 2-(trimethylsilyl)ethoxy]methyl-lithium 38 at —78 °C in THF.24 Surprisingly, lithium-halogen exchange does not happen and the intermediate benzyl alcohol undergoes reduction with sodium borohydride in the same pot to afford the desired bromophenol 39 in 68% yield. This material... 

The drug candidate 1 was prepared from chiral cyclopentanol 10 as shown in Scheme 7.3. Reaction of 10 with racemic imidate 17, prepared from the corresponding racemic benzylic alcohol, in the presence of catalytic TfOH furnished a 1 1 mixture of diastereomers 18 and 19 which were only separated from one another by careful and tedious chromatography. Reduction of ester 18 with LiBH4 and subsequent Swern oxidation gave aldehyde 20 in 68% yield. Reductive animation of 20 with (R)-ethyl nipecotate L-tartrate salt 21 and NaBH(OAc)3 and subsequent saponification of the ester moiety yielded drug candidate 1. 

The presence of water is essential for the success of these reductions. In anhydrous THF, for example, treatment of iV-benzoylimidazole with NaBH4 leads to benzyl benzoate as the main product (73%), along with 19% benzyl alcohol.[33] Other reports, however, describe the conversion of carboxylic acid imidazolides to the corresponding alcohols by complex hydrides in organic solvents. Further alcohols have been synthesized via imidazolides ... 

Devaky and Rajasree have reported the production of a polymer-bound ethylenediamine-borane reagent (63) (Fig. 41) for use as a reducing agent for the reduction of aldehydes.87 The polymeric reagent was derived from a Merrifield resin and a 1,6-hexanediol diacrylate-cross-linked polystyrene resin (HDODA-PS). The borane reagent was incorporated in the polymer support by complexation with sodium borohydride. When this reducing agent was used in the competitive reduction of a 1 1 molar mixture of benzaldehyde and acetophenone, benzaldehyde was found to be selectively reduced to benzyl alcohol. 

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