Aldehydes synthesis from toluene

A standard method for enamine synthesis from aldehydes or ketones is to heat the carbonyl compound and the secondary amine in benzene or toluene and remove the water formed by azeotropic distillation. This method cannot, however, be used the preparation of enamines from methyl ketones which undergo self-condensation under these conditions. A procedure which overcomes these difficulties has been given by White and Weingarten [31]. The method employs anhydrous titanium tetrachloride as water scavenger. In the original procedure by White and Weingarten, titanium tetrachloride is added dropwise to a cooled... 

Aldehyde synthesis. The synthesis of n-pentadecanal from s-trithiane and I -bromo-tctradccane (3, 329) has been published. Purification is accomplished by extraction of 30 g. of commercial s-trithiane with 300 ml. of toluene. 

The synthesis of methanofullerenes 955 was achieved starting from / -tosylhydrazones 954 and Cso under basic conditions (toluene, 70 °C). Tosylhydrazones 954 were prepared from the respective aldehydes 953 and />-toluene sulfonylhydrazide (Scheme 146) <2000CC113>. 

REACTION ALDEHYDE SYNTHESIS — GATTERMANN-KOCH Example p-Tolylaldehyde from Toluene and Carbon Monoxide1... 

A standard method for enamines synthesis from carbonyl compounds is to heat the parent aldehyde or ketone and a secondary amine in benzene or toluene and to remove the eliminated water by azeotropic distillation. However, this method fails with methyl ketone substrates which are prone to self-condensation imder these conditions. These difficulties could be overcome by a procedure using anhydrous titanium tetrachloride as water scavenger.[6] In the original procedure, titanium tetrachloride was added dropwise to a cold solution of the ketone and the amine, followed by prolonged stirring at room temperature. It was later found that the reaction time could be considerably shortened by a modified procedure, in which the... 

This zinc-promoted reaction has been used with a variety of carbonyl compounds. Thus, the Luche conditions were applied in a synthesis of (-1-)-muscarine using an aldehyde derived from ethyl lactate [109]. Allyl halide condensation onto a-ketoamides of proline benzyl ester gave good diastereoselec-tivity when performed in the presence of zinc dust and pyridinium p-toluene-sulfonate in a water/THF mixture. In this way, a-hydroxy ketones were obtained with good enantioselectivity after removal of the chiral auxiliary [110]. Reactions of allyl bromide under the Luche conditions with y-aldo esters afforded y-hydroxy esters, which were converted in a one-pot reaction to y-allyl-y-butyro-lactones (Scheme 22) [111]. 

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). 

Microwave irradiation has been used to accelerate the Gewald reaction for the one-pot synthesis of N-acyl aminothiophenes on solid support [67]. A suspension of cyanoacetic acid Wang resin 35, elemental sulfur, DBU and an aldehyde or ketone 36 in toluene was irradiated for 20 min at 120 °C in a single-mode microwave synthesizer (Scheme 13). Acyl chloride 37 was added, followed by DIPEA, and the mixture was irradiated for 10 min at 100 °C. After cooling to room temperature, the washed resin was treated with a TEA solution to give M-acylated thiophenes 38 in 81-99% yield and purities ranging from 46-99%. 

The Strecker reaction has been performed on the aldehyde 182 prepared from L-cysteine [86] (Scheme 28). The imine was formed in situ by treatment with benzylamine, then TMS cyanide was added to afford prevalently in almost quantitative yield the syn-diamine 183, which is the precursor of (-l-)-biotin 184. The syn selectivity was largely affected by the solvent, toluene being the solvent of choice. Since the aldehyde 182 is chemically and configurationally unstable, a preferred protocol for the synthesis of 183 involved the prehminary formation of the water-soluble bisulfite adduct 185 and the subsequent treatment with sodium cyanide. Although in this case the syn selectivity was lower, both diastereomers could be transformed to (-l-)-biotin. 

Treatment of 122 with (R,R)-tartrate crotyl-boronate (E.R.R)-W 1 provides the alcohol corresponding to 123 with 96% stereoselectivity. Benzylation of this alcohol yields 123 with 64% overall yield. The crude aldehyde intermediate obtained by ozonolysis of 123 is again treated with (Z,R,R)-111 (the second Roush reaction), and a 94 5 1 mixture of three diastereoisomers is produced, from which 124 can be isolated with 73% yield. A routine procedure completes the synthesis of compound 120, as shown in Scheme 3-44. Heating a toluene solution of 120 in a sealed tube at 145°C under argon for 7 hours provides the cyclization product 127. Subsequent debromination, deacylation, and Barton deoxygenation accomplishes the stereoselective synthesis of 121 (Scheme 3-44). 

Diarylethenes, 1,1-diarylallylalcohols and aryl vinyl ethers were succesfully hydroformylated in water/toluene or water/cyclohexane biphasic mixtures with a catalyst prepared in situ from[ RhCl(COD) 2] and TPPTS (Scheme 4.15). Yields of the desired linear aldehyde product were around 80%. This method was applied for the synthesis of the neuroleptics Fluspirilen and Penfluridol (Scheme 4.16) and for other pharmaceutically active compounds containing the 4,4-bis(p-fluorophenyl)butyl group [153]. 

In 2007, Tron and Zhu reported the multicomponent synthesis of 5-iminoox-azolines (42) starting from a,a-disubstituted secondary isocyano amides (41), amines, and carbonyl components (see Fig. 15) [155]. The reaction presumably follows a similar mechanism as in the 2,4,5-trisubstituted oxazole MCR (described in Fig. 11) however, because of the absence of a-protons at the isocyano amide 41, the nonaromatized product is obtained. As in the 2,4,5-trisubstituted oxazole MCR, toluene was found to be the optimal solvent in combination with a weak Brpnsted acid. The reaction was studied for a range of aldehydes and secondary amines. In addition, a variety of functionalities such as acetate, free hydroxyl group, carbamate, and esters are tolerated. Clean conversions were observed for this MCR as indicated by NMR analysis of the crude products (isolated yield 50-68%). The... 

A total synthesis of ( )-dihydrospiniferin-l (149), an unstable furanosesquiterpene from the Mediterranean sponge Pleraplysilla spinifera, has been reported. It is of interest because (149) is the first reported natural product incorporating the novel l,6-methano[10]annulene carbon framework (80JA4274). The key step in the synthesis is the condensation of the aldehyde (150) with methoxymethylenetriphenylphosphorane in toluene to give the bis-enol ether (151). Treatment of (151) with aqueous hydrochloric acid in diethyl ether affords the furan (149). 

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