Academic literature on the topic 'Eaton's reagent'

The intramolecular cyclisation of 6-[(phenoxy/phenylthio)methyl][1,3]dioxolo[4,5-g]quinoline-7-carboxylic acids to [1]benzoxepino[3,4-b][1,3]dioxolo[4,5-g]quinolin-12(6H)-onesand[1]benzothiepino[3,4-b][1,3]dioxolo[4,5-g]quinolin-12(6H)-ones in the presence of Eaton's reagent (P2O5-MeSO3H) is described. This cyclisation protocol requires milder conditions than those traditionally employed and is characterised by relatively low reaction temperatures and ease of product isolation.

Cyclodehydration of α-phenoxy ketones promoted by Eaton’s reagent (phosphorus pentoxide–methanesulfonic acid) is used to prepare 3-substituted or 2,3-disubstituted benzofurans with moderate to excellent yields under mild conditions. The method provides a facile access to benzofurans from readily available starting materials such as phenols and α-bromo ketones. The reaction is highly efficient, which is attributed to the good reactivity and fluidity of Eaton’s reagent. The reaction can be applied to prepare naphthofurans, furanocoumarins, benzothiophenes, and benzopyrans.

The polycondensations of 3,3′-diaminobenzidine with two acids, 4,4′-oxybis(benzoic acid) and hexafluoroisopropylidene bis(benzoic acid), were conducted in Eaton’s reagent at the unusually high temperature of 180°C and under microwave irradiation at 90°C. Both protocols resulted in soluble polybenzimidazoles, OPBI and CF3PBI, of high molecular weights in very short reaction times. The synthesized polybenzimidazoles exhibited high thermostability and excellent mechanical properties. The influence of the reaction conditions on the polymer structure and molecular weights was studied. The “microwave effect” was demonstrated by comparison of the polycondensations conducted under microwave irradiation and conventional heating.

The reactions of two 3-(2-allylanilino)-3-phenylacrylate esters with acetic anhydride and with strong acids has revealed a richly diverse reactivity providing a number of unexpected products. Thus, acetylation of ethyl 3-(2-allylanilino)-3-phenylacrylate, (Ia), or ethyl 3-(2-allyl-4-methylanilino)-3-phenylacrylate, (Ib), with acetic anhydride yields not only the expected acetylated esters, (II), as the major products but also the unexpected polysubstituted quinolines 3-acetyl-8-allyl-2-phenylquinolin-4-yl acetate, (IIIa), and 3-acetyl-8-allyl-6-methyl-2-phenylquinolin-4-yl acetate, (IIIb), as minor products. Subsequent reaction of the major product ethyl 2-[(2-allyl-4-methylanilino)(phenyl)methylidene]-3-oxobutanoate, (IIb), with concentrated sulfuric acid did not provide the expected 3-acetylquinoline derivative, but instead two unexpected products, namely ethyl 4-ethyl-2-phenyl-1,4-dihydroquinoline-3-carboxylate, (IV), and ethyl 3-acetyl-4-ethyl-2-phenyl-3,4-dihydroquinoline-3-carboxylate, (V), in yields of 39 and 22%, respectively. The reaction of (Ib) with Eaton's reagent gave both the quinoline (Z)-6-methyl-2-phenyl-8-(prop-1-en-1-yl)quinolin-4(1H)-one, (VI), and the unexpected tricyclic product (2RS)-2,8-dimethyl-4-phenyl-1,2-dihydro-6H-pyrrolo[3,2,1-ij]quinolin-6-one, (VII), in yields of 71 and 12%, respectively. The products (II)–(VII) have all been fully characterized spectroscopically and the crystal structures of two of the unexpected products,i.e.(IIIb) (C23H21NO3) and (VII) (C19H17NO), are reported here. The formation of compounds (IV), (V) and (VII) all require an isomerization of the initial allyl substituent, with migration of the C=C double bond from the terminal site to the internal site. In (IIIb), the two acetyl substituents are oriented such that the intramolecular distance between the two carbonyl O atoms is only 3.243 (2) Å, and in (VII), the five-membered ring adopts a twisted half-chair conformation. The molecules of compound (IIIb) are linked by two independent hydrogen bonds to form sheets built fromR43(20) rings and the sheets are linked by a π–π stacking interaction to form a three-dimensional framework structure. The molecules of compound (VII) are linked by a single type of C—H...O hydrogen bond to form centrosymmetricR22(14) dimers. The molecules of compound (V), which crystallizes withZ′ = 2, are linked by two N—H...O and two C—H...O hydrogen bonds, forming a chain of rings.

Highly rapid and efficient synthesis of Bis(indolyl)methanes has been developed by using a mixture of phosphorus pentoxide in methanesulphonic acid (Eaton’s reagent) at ambient temperature under solvent free condition.

An expeditious, one-pot method for the synthesis of 3,4-dihydropyrimidin-2(1H)-ones using a mixture of phosphorus pentoxide-methanesulfonic acid (Eaton’s reagent) at room temperature under solvent-free conditions is described. The salient features of this method include short reaction time, green aspects, high yields, and simple procedure.

Polypropionate marine natural products have emerged as a class of compounds that display a high degree of structural diversity. Specifically, metabolites such as that reported as tridachiahydropyrone (7), isolated from sacoglossan molluscs, display novel ring systems. The introductory chapter gives some background on tridachione marine natural products and outlines the isolation of metabolites from several species of sacoglossan mollusc. Chapter One also gives examples of the utility of the tandem conjugate addition-Dieckmann condensation approach being applied to the synthesis of these compounds. Chapter Two describes the development of the tandem conjugate addition-Dieckmann condensation and subsequent trans methylation approach to cyclohexenone rings. The synthetic strategy utilised chiral, functionalised cyclohexenone rings as synthons in the formation of bicyclic ring systems, so development of the carbocyclic ring formation was of vital importance to the overall strategy. Examples are given which confirm the viability of the proposed synthetic route to cyclohexenones such as 91, 92 and 104 from the reaction of [alpha,beta]-unsaturated carbonyl compounds 39 and 59 with dialkyl and dialkenyl Gilman cuprates. Chapter Three describes the incorporation of chiral cyclohexenone 117 into the bicyclic framework of model compound 105, analogous to the marine natural product reported as tridachiahydropyrone (7). The chapter explores the use of cyclohexenone precursor 43 that contained the total carbon framework of the bicyclic core of the desired pyrone. Once again, a tandem conjugate addition-cyclisation reaction was employed using a dialkyl Gilman cuprate, followed by trans methylation to give the requisite cyclohexenone synthon 117. A novel Eaton’s reagent-promoted intramolecular cyclisation of acid 122 to pyrone 123 was then effected. Subsequent O-methylation afforded [alpha]-methoxy-[beta]-methyl-[gamma]-pyrone 105 as a single enantiomer, which had the identical core structure to the natural product. The structure, including relative stereochemistry of 105, was confirmed by single crystal X-ray analysis. Chapter Four builds on the previous two chapters and describes the conjugate addition-cyclisation with a higher order Gilman cuprate derived from vinyl bromide 44, which would deliver the vinyl side-chain required for the synthesis of reported natural product 7. The same acyclic precursor 43 as used in Chapter Three was cyclised and methylated to yield yet another cyclohexenone synthon 41. A single crystal X-ray analysis of related alcohol 162 confirmed the relative stereochemistry and structure. Another novel P2O5-mediated intramolecular cyclisation was achieved to give pyrone 168 and O-methylation provided a compound with the reported structure of natural product 7 as a single enantiomer. The structure of synthetic 7 was established unequivocally through extensive NMR studies. Comparisons of spectral data confirmed that natural tridachiahydropyrone was not the same as synthetic compound 7, so revision of the assigned natural product structure is warranted. Several other analogues were also synthesised using this methodology, highlighting the versatility of the method under development.