With Lithium Aluminium Hydride

Silicon, unlike carbon, does notiorm a very large number of hydrides. A series of covalently bonded volatile hydrides called silanes analogous to the alkane hydrocarbons is known, with the general formula Si H2 + 2- I uf less than ten members of the series have so far been prepared. Mono- and disilanes are more readily prepared by the reaction of the corresponding silicon chloride with lithium aluminium hydride in ether ... 

Pure phosphine can be prepared by the reduction of a solution of phosphorus trichloride in dry ether with lithium aluminium hydride ... 

For reduction with lithium aluminium hydride, see Section VI,10. 

Note. Both tetramethylene glycol (1 4-butanediol) and hexamethylene glycol (1 6 hexaiiediol) may be prepared more conveniently by copper-chromium oxide reduction (Section VI,6) or, for small quantities, by reduction with lithium aluminium hydride (see Section VI,10). 

It is of interest to note that reduction of p-nitrostyrene with lithium aluminium hydride (compare Section VI, 10) gives p-phenylethylamine CgHgCHjCHjNHj. 

The following intermediate compounds in some reductions with lithium aluminium hydride have been formulated ... 

Thiazole acids may undergo many different types of reduction. Chemical reduction of thiazolecarboxy lic acids and of their derivatives to yield the corresponding alcohols can be accomplished with lithium aluminium hydride in ether solution (53). 

Reduction with sodium in alcohol was unsuccessful (54). The introduction of lithium aluminium hydride has provided an elegant method for the reduction of thiazole esters to hydroxythiazoles for example, ethyl 2-methyl-4-thiazolecarboxylate (11 with lithium aluminium hydride in diethyl ether gives 2-methyl-4-(hydroxymethyl)thiazole (12) in 66 to 69% yield (Scheme 7) (53),... 

Reductions carried out with lithium aluminium hydride are not always so successful. As noted by Sprague (46) the esters of 2-aminothiazole carboxylic acids behave somewhat differently with AlLiH4 (55). 

The purification of diethyl ether (see Chapter 4) is typical of liquid ethers. The most common contaminants are the alcohols or hydroxy compounds from which the ethers are prepared, their oxidation products (e.g. aldehydes), peroxides and water. Peroxides, aldehydes and alcohols can be removed by shaking with alkaline potassium permanganate solution for several hours, followed by washing with water, concentrated sulfuric acid [CARE], then water. After drying with calcium chloride, the ether is distilled. It is then dried with sodium or with lithium aluminium hydride, redistilled and given a final fractional distillation. The drying process should be repeated if necessary. 

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... 

Reduction of epoxide 21 with lithium aluminium hydride gave a crystalline branched-chain methyl heptoside derivative 24. The NMR spectra of compounds 21 and 24 were very similar. In the spectrum of compound 24 the disappearance of the two sharp doublets at r 6.80 and 7.45 (2 protons) and the appearance of a singlet at r 8.65 (3 protons) is consistent with the reductive cleavage of epoxide 21 to give a substance 24 with a methyl substituent. The multiplet at r 7.40-8.50 ( 5 protons ) was assigned to the four protons of the two methylene groups and the hydroxylic proton. 

The Mitsunobu reaction was also applied to the synthesis of [ 1,2,4]triaz-ino[4,5-n]indoles (84AG517). Thus, reaction of the 2-acylindoles 127 with sodium borohydride in methanol or with lithium aluminium hydride in tetrahydrofuran gave the corresponding alcohols 128. Their cyclization with diethyl azodicarboxylate in the presence of triphenyl-phosphine gave the triazinoindoles 129. Acid treatment of the latter afforded 130 (Scheme 30). 

GEP2811780 79JCS(P1)1120 80EUP9384 80JCS(P1)1139], Reduction of the carbonyl function of 529 to provide 530 was best achieved with lithium aluminium hydride in 1,2-dimethoxyethane. Dehydrogenation of 530 over palladium on charcoal afforded 531. They were prepared for use as muscle relaxants and bronchodilators (Scheme 110). 

W.G. Brown, Reduction with Lithium Aluminium Hydride, Org. Reactions 6, 469 (1951). 

The reduction of optically active methylphenyl-n-propylphosphine sulphide with lithium aluminium hydride proceeds with 100% retention, whereas the reaction of phosphine oxides with lithium aluminium hydride leads to racemization. ... 

Two contrasting conclusions have been reported in the reactions of lithium aluminium hydride in THF with phosphine oxides and phosphine sulphides respectively. The secondary oxide, phenyl-a-phenylethylphos-phine oxide (42), has been found to be racemized very rapidly by lithium aluminium hydride, and this observation casts some doubt on earlier reports of the preparation of optically active secondary oxides by reduction of menthyl phosphinates with this reagent. A similar study of the treatment of (/ )-(+ )-methyl-n-propylphenylphosphine sulphide (43) with lithium aluminium hydride has revealed no racemization. These results have been rationalized on the basis of the preferred site of attack of hydride on the complexed intermediate (44), which, in the case of phosphine oxides (X = O), is at phosphorus, and in the case of the sulphides (X = S), is at sulphur. Such behaviour is comparable to that observed during the reduction of phosphine oxides and sulphides with hexachlorodisilane. ... 

The seco amide alkaloids have been subjected to various transformations, mainly for structure elucidation purposes. When treated with lithium aluminium hydride, arnottianamide (206) was converted to the tertiary amine, deoxyarnottianamide (224), which on methylation with the Rodionow reagent gave deoxy-O-methylarnottianamide (225) (172,175). Arnottianamide (206) could be O-acetylated (174) as well as O-methylated with diazomethane in HMPA (172). Isoarnottianamide (208) was O-methylated to trimethoxy derivative 226, which under Bischler-Napieralski conditions recyclized to the benzophenantridine alkaloid, chelilutine (227) (176) (Scheme 33). 

Brown, H. C., and Ch. J. Shoaf Selective Reductions. III. Further Studies of the Reaction of Alcohols with Lithium Aluminium Hydride as a Route to the Lithium Alkoxyaluminiumhydrides. J. Amer. chem. Soc. 

Ozonolysis of alkene 446 in the presence of acetaldehyde afforded diketone 448 through the intermediacy of 447. Ring expansion through Beckmann rearrangement took place when bis-oxime 449 was mesylated and warmed in aqueous tetrahydrofuran (THF). The bis-lactam so formed gave piperidinediol 450 on reduction with lithium aluminium hydride, and this compound was transformed into ( )-sparteine by treatment with triphenylphosphine, CCI4, and triethylamine (Scheme 105) <20050BC1557>. 

Allylpiperidines were formed from 3-iodomethylperhydropyrido[l,2-f][l,3]oxazin-l-ones by treatment with Zn in AcOH <2002OL3459>. l-Methyl-2-(2-hydroxyalkyl)piperidines were prepared from 3-substituted perhydropyr-ido[l,2-tf][l,3]oxazin-l-ones with lithium aluminium hydride (LAH) in boiling THF and EtzO <2005T1595>. Reaction of 8-methylperhydropyrido[ 1,2-r [ 1.3 ]oxazine-1,3-dione 103 with PhCH2NH2, then PhCOCl and 4-meth-oxyphenol afforded ring-opened products 104 and 105, respectively (Scheme 8) <2000JA11009>. 

Azatriquinadiene (2,3-dihydroazatriquinacene) 39 has been efficiently synthesized from enamine 389. Enamine 389 on treatment with bromine followed by aqueous work-up afforded the tetrabromohemiaminal 390. Dehydrohalogenation of 390 with potassium hexamethyldisilazide (KHMDS) and compound 391 on reduction with lithium aluminium hydride yielded the target molecule azatriquinadiene 39 in good overall yield (Scheme 85) <2000JOC7253>. 

The enantiomerically pure indolizidine (—)-422 has been synthesized starting from L-malic acid diethyl ester 407. The hydroxyl function of L-malic acid diethyl ester 407 has been protected as dihydropyranyl ether 408 with 2/7-dihydropyran and Amberlyst 15 in pentane at room temperature. The diethyl ester 408 was then reduced with lithium aluminium hydride in diethyl ether under reflux and the newly generated hydroxyl functions then protected with mesyl chloride in the presence of triethylamine in dichloromethane at 0°C. This was converted into newly protected pyrroline nitrone 409 in 44% overall yield through a well-established method (Scheme 90). The regio-isomeric 5-pyrroline-iV-oxide 410 formed in 4% overall yield was easily separated by column chromatography <20000L2475>. 

Because of their interest in physiologically active selenophenes, Magde-sieva and co-workers147 I4S have prepared some a-amino alcohols (115). Ketones (114) were nitrosated and the oximes thus obtained were reduced with lithium aluminium hydride. 

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