6-Methoxy-1-indanone

Trost and Latimer reported the clean generation of ketone ,/ -dianion of 6-methoxy-indanone. They used two equivalents of LDA as a base and THF as a solvent6. Alkylation with one equivalent of ethyl iodide gave 89% yield of 3-ethyl-6-methoxy-l-indanone. For the alkylation, the ambident character of the dianion was evident, although negligible, since the formation of 3-ethyl-3-hydroxy-6-methoxy-l-indene was confirmed (Scheme 11). 

Many patents have been issued on the use of pyrogaUol derivatives as pharmaceuticals. PyrogaUol has been used extemaUy in the form of an ointment or a solution in the treatment of skin diseases, eg, psoriasis, ringworm, and lupus erythematosus. GaUamine triethiodide (16) is an important muscle relaxant in surgery it also is used in convulsive-shock therapy. Trimethoprim (2,4-diamino-5-(3,4,5-trimethoxybenzyl)pyrimidine) is an antimicrobial and is a component of Bactrin and Septra. Trimetazidine (l(2,3,4-trimethoxybenzyl)piperazine (Vastarel, Yosimilon) is used as a coronary vasodilator. l,2,3,4-Tetrahydro-6-methoxy-l-(3,4,5-trimethoxyphenyl)-9JT-pyrido[3,4- ]indole hydrochloride is useful as a tranquilizer (52) (see Hypnotics, sedatives, ANTICONVULSANTS, AND ANXIOLYTICS). Substituted indanones made from pyrogaUol trimethyl ether depress the central nervous system (CNS) (53). Tyrosine-and glycine(2,3,4-trihydroxybenzyl)hydrazides are characterized by antidepressant and anti-Parkinson activity (54). 

Methoxy-l-indanone [13623-25-1] M 162.2, m 151-153°. Crystd from MeOH, then sublimed in a high vacuum. 

In 1986 Yamashida et al. found that the reaction of the (morpholino)phenyl-carbene complex 46 with symmetric alkynes 47 gave the morpholinylindene derivatives 48 and 49, as well as the indanones 50 derived from the latter by hydrolysis, in excellent yields (Scheme 9) [54]. This contrasts with the behavior of the corresponding (methoxy)phenylcarbene complex, which solely undergoes the Dotz reaction [55]. This transformation of the amino-substituted complex 46 apparently does not involve a CO insertion, which is an important feature of the Dotz benzannelation. 

Dihydro-1-vinylnaphthalene (67) as well as 3,4-dihydro-2-vinylnaphtha-lene (68) are more reactive than the corresponding aromatic dienes. Therefore they may also undergo cycloaddition reactions with low reactive dienophiles, thus showing a wider range of applications in organic synthesis. The cycloadditions of dienes 67 and 68 and of the 6-methoxy-2,4-dihydro-1-vinylnaphthalene 69 have been used extensively in the synthesis of steroids, heterocyclic compounds and polycyclic aromatic compounds. Some of the reactions of dienes 67-69 are summarized in Schemes 2.24, 2.25 and 2.26. In order to synthesize indeno[c]phenanthrenones, the cycloaddition of diene 67 with 3-bromoindan-l-one, which is a precursor of inden-l-one, was studied. Bromoindanone was prepared by treating commercially available indanone with NBS [64]. 

Prepare 6-methoxy-l-indanone (I) (JCS 1986(1962)) using polyphosphoric acid made by diluting 500 g of the commercial acid with 120 g 85% phosphoric acid. 2.5 g (I) in 176 ml ether and reflux one hour with 0.27 g lithium aluminum hydride. Cool and carefully add water and filter when bubbling stops (can use Celite filter aid). Dry and evaporate in vacuum and store twelve hours at -15° (under N2 if possible) to precipitate the white 6-methoxy-l-indanol (II) (recrystallize-n-hexane). 2.5 g (II) in 73 ml benzene and reflux one-half hour with 0.2 g p-toluenesulfonic acid. Cool, add water and separate the phases. Extract the aqueous phase with ether and combine with benzene phase and dry, evaporate in vacuum to get 5-methoxy-indene (III) (can distill 110-45/10). 1.53 g (III) and 1.39 g N.N-diethyl-aminoethyl-Cl.HCI in benzene (prepare the free base in benzene as described previously). Reflux four hours with 0.42 g sodamide, cool, wash with water and dry, evaporate in vacuum to get the indene analog of 6-methoxy DET as a dark liquid (can crystallize as oxalate). Alternatively, dissolve 2.51 g (III) in ether and treat (under N if possible) with 12 ml 1.6M buty-Li in hexane at 0-10°. After two hours cool to -30° and add 12 ml more of butyl-Li. Add ether suspension of 2.5 g N,N-diethylaminoethyl-CI. HCI over one-half hour and warm to room temperature. Filter, evaporate in vacuum to get the 6-methoxy-DET analog. 

D. L. Hughes, U.-H. Dolling, K M Ryan, R F. Schoene-waldt, E. I. J. Grabowski, A Kinetic and Mechanistic Study of the Enantioselective Phase-Transfer Methyla-tion of 6,7-Dichloro-5-methoxy-2-phenyl-l-indanone , J. Org. Chem. 1987, 52, 4745-4752... 

Bromodesilylation T-methoxy-l-indanones. Cyclization contrary to the normal para-selectivity of anisole derivatives can be effected by temporary use of an ort/jo-trimethylsilyl group introduced by directed orf/io-metallation (11,75). Thus the anisole derivative 1 undergoes bromodesilylation and hydrolysis to provide 2. This product undergoes cyclization to 3 in good yield on conversion to the lithio salt followed by bromine-lithium exchange (8,65-66). 

Catalytic asymmetric methylation of 6,7-dichloro-5-methoxy-2-phenyl-l-indanone with methyl chloride in 50% sodium hydroxide/toluene using M-(p-trifluoro-methylbenzyDcinchoninium bromide as chiral phase transfer catalyst produces (S)-(+)-6,7-dichloro-5-methoxy-2-methyl-2--phenyl-l-indanone in 94% ee and 95% yield. Under similar conditions, via an asymmetric modification of the Robinson annulation enqploying 1,3-dichloro-2-butene (Wichterle reagent) as a methyl vinyl ketone surrogate, 6,7 dichloro-5-methoxy 2-propyl-l-indanone is alkylated to (S)-(+)-6,7-dichloro-2-(3-chloro-2-butenyl)-2,3 dihydroxy-5-methoxy-2-propyl-l-inden-l-one in 92% ee and 99% yield. Kinetic and mechanistic studies provide evidence for an intermediate dimeric catalyst species and subsequent formation of a tight ion pair between catalyst and substrate. 

There are only a few reports on chiral phase transfer mediated alkylations". This approach, which seems to offer excellent opportunities for simple asymmetric procedures, has been demonstrated in the catalytic, enantioselective alkylation of racemic 6,7-dichloro-5-methoxy-2-phenyl-l-indanone (1) to form ( + )-indacrinone (4)100. /V-[4-(tnfluoromethyl)phenylmethyl]cinchoninium bromide (2) is one of the most effective catalysts for this reaction. The choice of reaction variables is very important and reaction conditions have been selected which afford very high asymmetric induction (92% cc). A transition state model 3 based on ion pairing between the indanone anion and the benzylcinchoninium cation has been proposed 10°. 

Indanyl)-phenol 16 was obtained by reacting p-methoxy-phenyl-acetic acid ethyl ester with benzylchloride to form a-benzyl-p-methoxyphenyl ethyl acetate, saponification into the acid, conversion of the acid with thionylchloride into the chloride, cyclization to 2-p-methoxy-phenyl-l-indanone, NaBH4 reduction to 2-p-methoxyphenyl-l-indanole, dehydration with p-toluene-sulphonic acid in toluene to 2-p-methoxyphenyl-indene, catalytic hydrogenation to 2-p-methoxyphenyl-indene, and treating the ether with HBr [Eq. (5)]. 

Indanones also undergo reductive alkylation, although not as well as 1-tetralones. Good yields were obtained with methyl iodide and 1-indanone as well as its 4-, 6- or 7-methoxy derivatives to give the di-hydroindanones (173) to (176). ... 

FVP experiments were carried out between 500 and 800 °G on 3(5)-phenyl- and 3(5)-methylpyrazolinones and on 3(5)-methoxy-5(3)-phenylpyrazole < 1999J(P2)211 >. The origin of the isolated products (mainly indanone, hydroxy-alkynes, and a,/ -unsaturated aldehydes) were explained as arising from the hydroxy tautomers of pyrazolinones. Temperature effects on the tautomeric equilibrium of 1-phenyl-3-methylpyrazolinone in solution show that the percentage of the GFI tautomer increased with increasing temperature. 

The pentamethinium salt needed for the preparation of the 9H-indeno(2,l-b)pyridine (217), mp. 79—81°, could not be obtained by condensation of 2-indanone, but was obtained by substitution of 2-dimethylaminoindene with dimethyi-3-methoxy-allylideneammonium methylsulfate (the adduct of dimethylsulfate and 3-dimethyl-aminoacroleine) (see also Section III. D. 2.)6. ... 

In 1984, the first successful monumental use of cinchona PTC for asymmetric a-substitution of carbonyls was reported by Dolling and coworkers of the Merck research group (Scheme 6.1) [8], In this work, cinchoninium salt (1) was employed in the catalytic asymmetric methylation of 6,7-dichloro-5-methoxy-2-phenyl-l-indanone (2) under phase-transfer conditions. The methylated product 3, which was finally transformed to (+ )-indacrinone through three further steps, was obtained in 95% conversion with 92% enantiomeric excess (ee). Through the systematic investigation, the group reported the relationship between the chemical/optical yield and the reaction variables (e.g., amount or concentration of each chemical species, halide of... 

On the contrary. Conn et al. [99] observed and explained an opposite behaviour by postulating tt- tt interactions between enolate and catalyst during Michael addition of 6,7-dichloro-5-methoxy-l-indanone to methyl vinyl ketone... 

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