Synthesis cyclocondensation

Wipf P, Fletcher JM, Scarone L (2005) Microwave promoted oxazole synthesis cyclocondensation cascade of oximes and acyl chlorides. Tetrahedron Lett 46 5463-5466... 

Several oxo compounds are derived from pyrazolidine, a cyclic iy,iV-disubstituted hydrazine. Pyra-zolidin-3-ones, as well as pyrazolidin-4-ones are known [141]. The anti-inflammatory phenylbutazone 1 is a substituted pyrazolidine-3,5-dione. It is made by C-alkylation of l,2-diphenylpyrazolidin-3,5-dione. For the industrial synthesis, cyclocondensation of 1,2-diphenylhydrazine with diethyl 2-butyl-malonate is preferred ... 

The cyclocondensation route is also effective for the synthesis of planar C2N4S2 rings from benzamidines and sulfur dichloride in the presence of a strong base (Eq. 2.11). ... 

The cyclocondensation of trimethylsilyl azide with a bis(sulfenyl chloride) is an efficient synthesis of dithiazolium cations (Section 11.3.5) (Eq. 2.15). ... 

A more versatile synthesis of 11.1 (and the selenium analogue) involves the cyclocondensation of trisilylated amidines with sulfur dichloride or SeCl2 generated in situ (Eq. 11.3). This route can be used to prepare the prototypal systems [HCNEEN]" (E = S, Se). It is also readily extended to the synthesis of multi-dichalcogenadiazolium cations such as 1,3- or 1,4-C6H4(CNEEN)2] (H-2, E = S, Se), °... 

The primary route to 1,3,2-dithiazolium salts involves the cyclocondensation of l,2-bis(sulfenyl chlorides) with trimethylsilyl azide, which is illustrated for benzo-fused derivatives in Eq. 11.11. ° This method can be extended to the synthesis of bis( 1,3,2-dithiazolylium) salts. 

Available information on the mechanism of cyclocondensation is rather contradictory. According to one hypothesis, both the condensation of aryl halides with copper acetylides and the cyclization occur in the same copper complex (63JOC2163 63JOC3313). An alternative two-stage reaction route has also been considered condensation followed by cyclization (66JOC4071 69JA6464). However, there is no clear evidence for this assumption in the literature and information on the reaction of acetylenyl-substituted acids in conditions of acetylide synthesis is absent. 

This is by far the most used type of primary synthesis for quinoxalines. It usually involves the cyclocondensation of an o-phenylenediamine (or closely related substrate) with a synthon containing an oxalyl [—C(=0)—C(=0)—] or equivalent [e.g., HC(=0)—C=N] grouping. For convenience, discussion of this synthesis is subdivided according to the type of synthon used to produce formally aromatic quinoxalines the formation of similar ring-reduced quinoxalines (mostly from related synthons at a lower oxidation state) is included in each such category. 

Scheme 31 Microwave-assisted cyclocondensation-cycloaddition-N2 expulsion for the synthesis of the canthine skeleton...

Abstract Controlled microwave heating has foimd many important applications in the synthesis of heterocycles. Almost all kinds of heterocycles have been prepared (or their preparation attempted) with the aid of microwaves. Many examples of cyclocondensations, reactions where two or more fimctional groups combine with the loss of another small molecule (usually water), have been described. Moreover, microwave irradiation successfully induces cycloaddition reactions, especially in the cases where high temperatures are required. This review collects the most representative examples of the application of microwaves to these two kinds of transformations. Except for a few examples, all the reactions selected have been carried out imder controlled microwave irradiation using dedicated instruments. 

Oxazol-4-ones 132 have been prepared by Trost and co-workers via a microwave-assisted cyclocondensation of bromo imides in the presence of NaF [86]. These products where then employed for a Mo-catalyzed asymmetric synthesis of Q -hydroxycarboxylic acid derivatives 134 (Scheme 47). 

For the synthesis of coumarins, the Pechmann reaction [145] is one of the most popular synthetic routes. As the reaction is conventionally carried out at high temperature, two microwave-assisted versions have been recently described. Besson and co-workers described the cyclocondensation of different m-amino phenols 226 with /1-ketoesters 227 on graphite/montmorillonite KIO support (Scheme 83). The use of graphite was crucial in the development of the reaction conditions. In fact, microwave irradiation of the reagents using different conditions gave poor results in terms of yields and purity. The optimized conditions, using a monomode microwave system, employed... 

The Pictet-Spengler reaction has mainly been investigated as a potential source of polycyclic heterocycles for combinatorial apphcations or in natural product synthesis [149]. Tryptophan or differently substituted tryptamines are the preferred substrates in a cyclocondensation that involves also aldehydes or activated ketones in the presence of an acid catalyst. Several versions of microwave-assisted Pictet-Spengler reactions have been reported in the hter-ature. Microwave irradiation allowed the use of mild Lewis acid catalysts such as Sc(OTf)3 in the reaction of tryptophan methyl esters 234 with different substituted aldehydes (aliphatic or aromatic) [150]. Under these conditions the reaction was carried out in a one-pot process without initial formation of the imine (Scheme 86). 

A completely different kind of macro cycle, a calix-salen type macrocycle, was obtained in good yield by microwave irradiation of various dialdehydes and diamines [165]. This was the first example of a calix-type synthesis under microwave conditions and without the presence of a metal template. An example of a [3 -1- 3] cyclocondensed macrocycle 265, obtained from a bis aldehyde and a chiral diamine is reported in Scheme 97. 

Rodriquez M, Taddei M (2006) Synthesis of Heterocycles via Microwave-Assisted Cycloadditions and Cyclocondensations. T. 213-266... 

Ojima, 1., Habus, 1., Zhao, M. (1991) Efficient and Practical Asymmetric Synthesis ofthe Taxol C-13 Side Chain, N-Benzoyl-(2R,3S)-3-phenylisoserine, and its Analogues via Chiral 3-Hydroxy-4-aryl-b-lactams Through Chiral Ester Enolate-Imine Cyclocondensation. Journal of Organic Chemistry, 56, 1681-1683. 

Samuel Danishefsky s group at the Sloan Kettering Institute for Cancer Research in New York has also been active in the synthesis of the natural epothilones and biologically active analogs. One of their syntheses also used the olefin metathesis reaction (not shown). The synthesis in Scheme 13.62 used an alternative approach to create the macrocycle, as indicated in the retrosynthetic scheme. The stereochemistry at C(6), C(7), and C(8) was established by a TiCl4-mediated cyclocondensation (Step A). The thiazole-containing side chain was created by reaction sequences F and G. The... 

Monocyclic 2H-[ 1,2,3 Idiazaphospholes (B) are easily accessible from the condensation of the four-membered chain incorporated in hydrazones or azoalkanes with phosphorus trichloride making available a large number of representatives that have been intensively studied [2, 4, 7], In contrast, their 1//-isomers (A) are less known and are obtained only as second minor product during the synthesis of 2//-[l,2,3]diazaphospholes in some cases. A facile synthesis for pyrido-anellated azaphospholes has been developed in our group by making use of 1,2-disubstituted pyridinium salts for condensation with phosphorus trichloride [8, 13-15], Accordingly, cyclocondensation of 2-alkyl-1-aminopyridinium iodides (1) with phosphorus trichloride in the presence of triethylamine affords pyrido-anellated l//-[l,2,3]diazaphospholes, i.e. l,2,3]diazaphospholo 1,5-a] pyridines (2) (Scheme 1) [16],... 

Scheme 19 Synthesis of monocyclic [l,4,2]diazaphospholes from [3+2] cyclocondensation...

Cyclocondensation of the iminoethers 157 with anthranilic acid was utilized in the synthesis of compounds 158a, 158b <2004TA3045> and 158 (R2 = indol-3-ylmethyl R1 = (A )-Me, (R)-Me (A)-Pr R4 = H, (A)-Me) resulting in moderate yields with retention of configuration at all stereocenters (Equation 16) <1998T969>. 

The only publication on the angularly condensed benzologues, pyrimido[2,l-tf]quinoxalines, describes the synthesis of 161 by formation of both the pyrimido and the pyrazino ring from [6+0] atom fragments. Compound 160, the targeted cyclocondensation product of the propanediamine derivative 159, spontaneously cyclized to the pyri-mido[2,l- ]quinoxaline A-oxide 161 (Equation 17) <2002S2687>. 

The synthesis of (6 5 6) fused heterocycles may involve one-pot double intramolecular cyclocondensations. A typical example of this reaction is the formation of amide intermediate 247 from 246, which further cyclizes to give pyridopurine derivative 248 (Scheme 13) <1995TL4249>. 

The Clauson-Kaas pyrrole synthesis was adapted to a soluble polyglycerol (PG) support <060L403>. Electrochemical oxidation of furan 33 in the presence of methanol followed by hydrogenation gave 2,5-dimethoxytetrahydrofuran 34. Cyclocondensation with primary arylamines gave A-arylpyrroles 35. Removal from the PG support was then accomplished by treatment of 35 with LiOH which gave 2-pyrrolepropanoic acids 36. 

A mixture of metals was utilized to promote a type Ilae synthesis of penta-substituted pyrroles <06OL2151>. Treatment of enyne 37 with a Ag(I) catalyst followed by BnNH2 and a Au(I) catalyst gave pyrrole 38 via a Claisen-type rearrangement and cyclocondensation. 

A type Ilbc approach to pyrroles was employed in the synthesis of pyrrolo[2,l-fc]thiazoles <06S1433>. The key step involved a formylation with the Vilsmeier-Haack reagent followed by a cyclocondensation of the putative iminium intermediate. 

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