Oxalyl chloride , reduction with

Acylation. Acylation is the most rehable means of introducing a 3-substituent on the indole ring. Because 3-acyl substituents can be easily reduced to 3-aLkyl groups, a two-step acylation—reduction sequence is often an attractive alternative to direct 3-aLkylation. Several kinds of conditions have been employed for acylation. Very reactive acyl haUdes, such as oxalyl chloride, can effect substitution directiy without any catalyst. Normal acid chlorides are usually allowed to react with the magnesium (15) or 2inc (16) salts. The Vilsmeier-Haack conditions involving an amide and phosphoms oxychloride, in which a chloroiminium ion is the active electrophile, frequentiy give excellent yields of 3-acylindoles. 

Halogenation of 106 with triphenylphosphine, iodine, and imidazole provided the iodo derivative 109. On treatment with lithium aluminum hydride, 109 was converted into two endocyclic alkenes, 110 and di-O-isopro-pylidenecyclohexanetetrol, in the ratio of 2 1. Oxidation of 110 with dimethyl sulfoxide - oxalyl chloride afforded the enone 111.1,4-Addition of ethyl 2-lithio-l,3-dithiane-2-carboxylate provided compound 112. Reduction of 112 with lithium aluminum hydride, and shortening of the side-chain, gave compound 113, which was converted into 114 by deprotection. ... 

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). 

Ketoester 208 derived from l-(2-nitrophenyl)-lH-pyrrole and ethyl oxalyl chloride can be selectively reduced at the keto group with zinc iodide and sodium cyanoborohydride. Further reduction of the nitro group and cyclization to lactam 209 has been accomplished by treatment with stannous chloride in refluxing ethanol (Scheme 43 (2003BMCL2195)). 

In the following year, this method was also applied to the total synthesis of tjipanazole FI (371) (784). For this synthesis, the required bisindole 1444 was obtained starting from 5-chloroindole (1440) in three steps and 47% overall yield. Acylation of 1440 with oxalyl chloride led to the glyoxylic acid chloride 1441. Transmetalation of indolylmagnesium bromide with zinc chloride, followed by addition of the acid chloride, provided the ot-diketone 1443. Exhaustive reduction of 1443 with lithium aluminum hydride (LiAlFl4) afforded the corresponding bisindolylethane 1444. Executing a similar reaction sequence as shown for the synthesis of tjipanazole F2 (372) (see Scheme 5.243), the chloroindoline (+ )-1445 was transformed to tjipanazole FI (371) in two steps and 50% overall yield (784) (Scheme 5.244). 

Replacement of the chlorine in 487b with isopropylamine is accomplished, then the secondary amine product is acylated with ethyl oxalyl chloride (Equation 184). Again reduction of the nitro group allows cyclization to 489 to occur <2001H(55)1963>. 

Most of the early syntheses of psilocin and psilocybin employ the O-benzyl ether as a protecting group. This provides more stability to the chemical intermediates, but also requires the additional step of reductive debenzylation. The flow chart of this process is conversion of 4-hydroxyindole to 4-benzyloxyindole via the sodium salt, with benzyl chloride the conversion of this with oxalyl chloride to 4-benzyloxyindole-3-glyoxylchloride the conversion of this to 4-benzyloxy-3-(N,N-dimethyl-glyoxamide with anhydrous dimethylamine the conversion of this to... 

There is the raw stuff potentially available to answer this question. There are a couple of compounds known with the sulfur in the 4-position, which is the location of the oxygen atom in psilocybin. The 4-thio analogues have been synthesized from 4-methylthio-indole, via the oxalyl chloride method and reaction with the appropriate amine. With dimethylamine, the indoleglyoxylamide was made in a 43% yield and had a mp 163-164 °C. With diisopropylamine, the amide was made in a 27% yield and had a mp 190-192 °C. The final amines were prepared by the reduction of these amides with LAH in THF. N,N-Dimethyl-4-thiotryptamine (4-MeS-DMT) was obtained in a 68% yield and melted at 108-110 °C N,N-diisopropyl-4-methylthiotryptamine (4-MeS-DIPT) was obtained in a 61% yield and melted at 92-94 °C. In animal studies of behavioral disruption with these three compounds, there was systematic drop of potency in going from the 5-MeS-DMT to 4-MeS-DMT to 4-MeS-DIPT. 

EXTENSIONS AND COMMENTARY N-Methyltryptamine (monomethyltryptamine, NMT) is an alkaloid that has been found in the bark, shoots and leaves of several species of Virola, Acacia and Mimosa. However, the major snuffs associated with these plant have been shown to also contain 5-MeO-DMT and are discussed there. NMT has been synthesized in a number of ways. One can react 3-(2-bromoethyl)indole with methylamine. NMT can be isolated as the benzoyl derivative from the methylation of tryptamine with methyl iodide followed by reaction with benzoyl chloride, with the hydrolysis of this amide with alcoholic KOH. It can also be synthesized from indole with oxalyl chloride, with the resulting glyoxyl chloride reacting with methylamine in ether to give indol-3-yl N-methylglyoxalylamide (mp 223-224 °C from IPA) which is obtained in a 68% yield, which is reduced to NMT to give the amine hydrochloride (mp 175-177 °C from ) in a 75% yield. The most simple and direct synthesis is the formamide reduction given above. 

A convenient and efficient synthetic route to a new class of macrocyclic aryl ether ether sulfide oligomers was reported. The process is shown in Fig. 28. This new class of cyclic oligomers is prepared in excellent yield by quantitative chemical reduction of macrocyclic aryl ether ether sulfoxide oligomers with oxalyl chloride and tetrabutylammonium iodide. The cyclic sulfoxide oligomeric precursors are prepared in high yields by an aromatic nucleophilic substitution reaction from bis(4-fluorophenyl) sulfoxide with potassium salts of bisphenols under high-dilution conditions [99]. 

Acylation of the C3 position can also be accomplished with acid chlorides, as illustrated in the synthesis of indole 7.34, a drug for the treatment of depression. Reaction of indole 7.31 with oxalyl chloride affords C3-substituted product 7.32 even though the benzene ring is very electron-rich. Conversion to amide 7.33 is followed by reduction with lithium aluminium hydride which removes both carbonyl groups, affording the target indole 7.34. 

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