2-methyl tetralone

Methyl-1-tetralone, 3S, 96 Methyl 2-thienyl sdleide, 35, 85 Methyl S-thiodipeopionate, 30, 65... 

Chloro-5-methylnaphtho[l,2-c]-l,2-dithiolium chloride reacted similarly with 4-methyl-1-naphthol and with 4-methyl-1-tetralone. 

The favourable effect of lithium bromide on facial enantioselective protonation of methyl tetralone enolate by a-sulfinyl alcohols has been attributed to coordination of lithium to both enolate and sulfinyl alcohol followed by competition between diastere-omeric paths involving intramolecular proton transfer the proposed transition-state model is supported by results of PM3 semiempirical calculations. ... 

Chiral a-sulfinyl alcohol (S,i s)-ll was also shown to be a promising chiral proton donor in catalytic protonation of 2-methyl tetralone enolate by Asen-sio s group [19]. 

However, after boron and tin enolates and their ate complexes had been successfully applied in the palladium-catalyzed allylic alkylation [9, 11], Trost and Schroeder reported in 1999 [12a] the first enantioselective catalytic variant wherein the tin enolate 13a derived from 2-methyl tetralone was reacted with allyl acetate. The use of the Cj-symmetric ligand (5, 5 )-14 ( Trost s ligand )... 

Trost and coworkers had noticed that the topicity in the approach of the allyl unit to the lithium (or tin) enolate of 2-methyl tetralone is opposite to that in the decarboxylative allylation procedures (Scheme 5.39). Thus, the major enantiomer of allylated tetralone 15 in the reaction of the lithium enolate 13b is (JJ)-configured when the reaction was catalyzed with (5,5)-ligand 14. The same enantiomer of the product, (f )-15, results in the decarboxylative protocol, catalyzed however by (f ,7 )-ligand 69 [35]. 

The highly electrophilic cationic bis(8-quinolinolato)aluminum complex 407 enabled Yamamoto and coworkers to perform Mukaiyama-Michael additions of silyl enol ethers to crotonylphosphonates 406. The procedure was not only applicable to enol silanes derived from aryl methyl and alkyl methyl ketones (a-unsubstituted silicon enolates) but also to several cycfic a-disubstituted silyl enol ethers, as illustrated for the derivatives of a-methyl tetralone and indanone 405 in Scheme 5.105. Despite the steric demand of that substitution pattern, the reaction occurred in relatively high chemical yield with varying diastereoselectivity and excellent enantiomeric excess of the major diastereomer. The phosphonate residue was replaced in the course of the workup procedure to give the methyl esters 408. The protocol was extended inter alia to the silyl enol ether of 2,6,6-tetramethylcyclohexanone. The relative and absolute configuration of the products 408 was not elucidated [200]. 

The most recent, and probably most elegant, process for the asymmetric synthesis of (+)-estrone appHes a tandem Claisen rearrangement and intramolecular ene-reaction (Eig. 23). StereochemicaHy pure (185) is synthesized from (2R)-l,2-0-isopropyhdene-3-butanone in an overall yield of 86% in four chemical steps. Heating a toluene solution of (185), enol ether (187), and 2,6-dimethylphenol to 180°C in a sealed tube for 60 h produces (190) in 76% yield after purification. Ozonolysis of (190) followed by base-catalyzed epimerization of the C8a-hydrogen to a C8P-hydrogen (again similar to conversion of (175) to (176)) produces (184) in 46% yield from (190). Aldehyde (184) was converted to 9,11-dehydroestrone methyl ether (177) as discussed above. The overall yield of 9,11-dehydroestrone methyl ether (177) was 17% in five steps from 6-methoxy-l-tetralone (186) and (185) (201). 

Bruce et al. carried out the cyclization of 4-phenylbutyric acid to tetralone in NaCl/AlCl3 (X(A1C13) = 0.68) at 180-200 °C [92]. The reaction between valerolactone and hydroquinone to give 3-methyl-4,7-dihydroxyindanone was also performed by Bruce, using the same ionic liquid and reaction conditions. These are shown in Scheme 5.1-60. 

The combination of CsF with Si(OMe)4 58 is an efficient catalyst for Michael additions, e.g. of tetralone 130 to methacrylamide, followed hy cyclization of the addition product to the cyclic enamide 131 in 94% yield [67]. Likewise, addition of the lactone 132 to methyl cinnamate affords, after subsequent cyclization with tri-fluoroacetic acid, the lactam 133 in 58% yield [68] whereas < -valerolactam 134, with ethyl acrylate in the presence of Si(OEt)4 59/CsF, gives 135 in 98% yield [69]. Whereas 10mol% of CsF are often sufficient, equivalent amounts of Si(OEt)4 59 seem to be necessary for preparation of 135 [69] (Scheme 3.11). 

Reaction of 1-tetralone with aryl cyanides or methyl thiocyanate, followed by aromatisation with DDQ gave good yields of benzoquinazolines. The further transformation of the methylthio product 31, via oxidation and selective sequential nucleophilic substitution of the resulting sulfones, illustrates the utility of this substituent. 2-Tetralone reacted similarly but substantial amounts of by-products were formed <06T2799>. 

N-Cyanoguanidine, 35, 69 Cyanohydrin formation, 33, 7 3-Cyano-6-isobutyl-2(l)-pyridone, 32, 34 3-Cyano-6-methyl-2(1)-pyridone, 32, 32 l-Cyano-3-a-naphthylurea, 36, 11 1-Cyano-3-phenylurea, 36, 8 Cyclic acyloins, 36, 82 Cyclization, (3-aminoethylsulfuric acid to ethylenimine, 30, 38 1,2-benzo-3,4-dihydrocarbazole from phenylhydrazine and a-tetralone,... 

The first promising asymmetric aldol reactions through phase transfer mode will be the coupling of silyl enol ethers with aldehydes utilizing chiral non-racemic quaternary ammonium fluorides,1371 a chiral version of tetra-n-butylammonium fluoride (TBAF). Various ammonium and phosphonium catalysts were tried138391 in the reaction of the silyl enol ether 41 of 2-methyl-l-tetralone with benzaldehyde, and the best result was obtained by use of the ammonium fluoride 7 (R=H, X=F) derived from cinchonine,1371 as shown in Scheme 14. 

Tetralone is readily mono- or di-alkylated at the 1-position to the exclusion of O-alky lation with a range of alkylating agents under liquiddiquid two-phase conditions without an added solvent [24], Similarly, it has been reported that anthrone undergoes mono- and di-C-alky lation at the 10-position with propargyl and allyl halides to the almost complete exclusion of O-alkylation [25]. It has been claimed that methyl-ation yields 9-methoxyanthracene [26],... 

The stereospecific C-alkylation of a range of benzylic ketones, such as tetralones, 2-phenylcyclohexanones and cycloheptanones, and 2-phenyl-y-lactones, has also been described [8]. For example, Af-(4-trifiuoromethylbenzyl)cinchonidinium bromide catalyses the reaction of 1,5-dibromopentane with 7-methoxy-l-methyl-2-tetralone to yield the (R)-l-(5-bromopentyl) derivative (75% yield with 60% ee). 

The Robinson annulation reaction of 7-methoxy-l-methyl-2-tetralone with methyl vinyl ketone in the presence of A,-(4-trifluoromethylbenzyl)cinchonidinium bromide produces the S-isomer of the tricyclic compound (Scheme 12.10) with an 81% conversion (81% ee) [8]. 

Reaction of 299 with benzaldehyde was found to give an equimolar mixture of diastereomeric j3-hydroxysulfoxides (314). Addition of 299 to a-tetralone 300 was more satisfactory, since the corresponding diastereomeric/3-hydroxysulfoxides 301 were formed in a 1.8 1 ratio. Their subsequent desulfuration with Raney nickel yielded levorota-tory 1-hydroxy-1-methyl-1,2,3,4-tetrahydronaphthalene 302 of unknown absolute configuration and optical purity. Similarly, addition of 299 to cyclohexene oxide leads to the formation of diastereomeric /3-hydroxysulfoxides 303 in a 2 1 ratio which, after separation, may be desulfurized to give (R,R)- and (S,S)- trans-2-methylcyclo-hexanols 304, respectively. Analysis of NMR spectra of the... 

Streptomyces griseus NRRL 8090 catalyzes a series of biotransformations of naphthalene and 2-methyl-1,4-naphthaquinone to their corresponding racemic and diastereomeric 4-hydroxy-1-tetralones (Figure 12.1). The yields of 4-hydroxy-l-tetralone obtained with S. griseus are much higher than those produced by various fungi that oxidize naphthalene. ... 

For gas chromatography analysis, samples were spiked with 2-methyl-naphthalene as an internal standard. Samples were analyzed using a Shimadzu GC-17A series gas chromatograph equipped with RTX-5 column, 15 m (length) 0.25 mm (i.d.) and 0.25 pm (film thickness). The initial column temperature was 70 °C and temperature was increased at 20 °C min 300 °C, and column temperature was held for 13 min. Retention times R naphthalene, 3.2 min 2-methyl-naphthalene, internal standard, 4.09 min 1-tetralone, 4.7 min menadione, 5.68 min 1-naphthol, 5.7 min 4-hydroxy-1-tetralone, 6.1 min and 2-methy 1-4-hydroxy-1-tetralone, 6.18,6.27,6.3 and 6.4 min. 

Tetralone from tetralone, alpha-naphthol, tetralin NaY Methyl acetate [241]... 

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