Pyrroles, 1,2,5-trisubstituted synthesis

The synthesis can be conducted both in solution and without solvents. The reaction in solvent (e.g., methanol, ethanol, dioxane, dimethylformamide) is recommended for volatile 1,3-diynes and amines in this case the pyrroles are purer and the yield is higher. With disubstituted diacetylenes, ammonia and primary alkyl- and arylamines produce 1,2,3-trisubstituted pyrroles under the same conditions (65CB98 71MI1). Since disubstituted diacetylenes are readily obtained by oxidative coupling of acetylenes (98MI2), this reaction provides a preparative route to a wide range of pyrroles. 

The second Had synthesis provided a route to 2,3,4-trisubstituted pyrroles <06CC2271>. Mixing cinnamaldehyde 27 with aminocarbene complex 28 in the presence of molecular sieves (MS) gave pyrrole 29. The authors proposed a mechanism that included a cyclopropane intermediate and subsequent fragmentation and intramolecular condensation. 

In analogy to the Paal-Knorr pyrrole synthesis described by Taddei and coworkers [342] (Scheme 6.181), similar reaction conditions were used by these authors to cyclize 1,4-dicarbonyl compounds to give furans (Scheme 6.190). Thus, heating a solution of a 1,4-dicarbonyl compound in ethanol/water in the presence of a catalytic amount of hydrochloric acid at 140 °C for 3 min provided an excellent yield of the corresponding trisubstituted furan derivative. 

In Scheme 5 under the lukianol section, the Bullington synthesis [17] of 2,3,4-trisubstituted pyrroles was presented. Bullington has used this strategy to prepare ningalin B and the resulting steps in this route are presented in Scheme 17. This route also constitutes a very efficient method for the construction of the ningalin A and B scaffold. 

Benzofuranyl)pyrroles, 2-(2-thienyl)pyrroles , 2,2 -dipyrroles, 3-(2-pyr-rolyl)indoles , 2-(2-benzimidazolyl)pyrroles and2-(2-, 3- and4-pyridyl)pyrroles were prepared using this method. Reaction of alkynes (for example, propyne) or allene with ketoximes in a superbase system (MOH/DMSO) leads to 2,5-di- or 2,3,5-trisubstituted pyrroles Pyrroles and dipyrroles were synthesized also from corresponding dioximes and acetylene in a KOH/DMSO system It has also been shown that 1,2-dichloroeth-ane can serve as a source of acetylene in pyrrole synthesis. Oxime 52 in the system acetylene/RbOH/DMSO at 70 °C afforded a mixture of three pyrroles 53-55 in low yields (equation 23). The formation of product 53 occurred through recyclization of pyrrolopy-ridine intermediate. ... 

The [3 + 2] addition of type llbd is a significant method for synthesis of both simple and complex pyrrole derivatives. One manifestation of this pattern is seen in the base-catalyzed condensation of tosylmethyl isocyanide with alkenes having strong electron-accepting substituents. The aromatization by elimination of the arenesulfinic add occurs under the reaction conditions (equation 117) (72TL5337). This reaction can be applied to the synthesis of 2,3,4-trisubstituted pyrroles by using C-alkylated tosylmethyl isocyanides or AT-tosyl-methyl-S- methylthioimidates <77H(7)77, 81JHC1127). 

Similar reaction conditions as those by Bose were used for a range of other applications, for example, the synthesis of heterocycles. A combination of a microwave-assisted Paal-Knorr reaction15 with a transfer hydrogenation takes place in the preparation of 2,5-di- and 1,2,5-trisubstituted pyrroles from -l,4-diaryl-2-butene-l,4-diones in a one-pot operation. Hydrogenation was achieved with ammonium formates and 10% Pd/C as catalyst in PEG-200. Yields of up to 92% were obtained within 0.5-2 min (Scheme 4.2)16. 

Scheme 52 Cl-Stetter addition-Paal-Knorr four-component synthesis of 1,2,3,5-tetrasubstituted and 2,3,5-trisubstituted pyrroles 97...

The bone collagen cross-link (+)-deoxypyrrololine has potential clinical utility in the diagnosis of osteoporosis and other metabolic bone diseases. Intrigued by its novel structure and its promise to allow the early discovery of various bone diseases, the research team of M. Adamczyk developed a convergent total synthesis for this 1,3,4-trisubstituted pyrrole amino acid. The key step of the synthesis was the union of the nitroalkane and aldehyde fragments to obtain a diastereomeric mixture of the expected -nitro alcohol in good yield. This new functionality served as a handle to install the pyrrole ring. 

The formal total synthesis of roseophilin was accomplished by B.M. Trost et al. who used the Paal-Knorr pyrrole synthesis to install the trisubstituted pyrrole moiety.The 1,4-diketone substrate was reacted with various primary amines to obtain A/-substituted pyrroles. The best yield was obtained when benzylamine was used as the amine component, but the A/-deprotection of the product proved to be problematic. This forced the researchers to prepare the otherwise unstable A/-unprotected pyrrole under carefully controlled conditions and protect it immediately with SEM-chloride. 

The absolute stereochemistry of natural roseophilin was determined by means of asymmetric total synthesis by M.A. Tius and co-workers. The trisubstituted pyrrole moiety of the natural product was installed using the Paai-Knorr pyrrole synthesis starting from a macrocyclic 1,4-diketone. This diketone was prepared by reacting an exocyclic a, 3-unsaturated ketone with excess 6-heptenal in the presence of 3-benzyl-5-(hydroxyethyl)-4-methylthiazolium chloride as the catalyst. The major product was the trans diastereomer and the macrocyclization was achieved via aikene metathesis. It is worth noting that when the aldehyde was tethered to the cyclopentenone, all attempts to close the macrocycle in an intramolecular Stetter reaction failed. 

Cyclocondensation of nitroalkenes with CH-acidic isocyanides in the presence of bases leads to the formation of trisubstituted pyrroles 20 (Barton-Zard synthesis) [43] ... 

This section covers cyclizations to the pyrrole nucleus catalyzed by other metals (Ti, Mn, Ru, Pd, Pt, Zn, In). Dembinski and co-workers used zinc(II) chloride as ligand-free catalyst for the microwave-assisted cyclization of homopropargyl azides 26 to afford substituted pyrroles 27 (Scheme 8) [62]. A similar methodology for the synthesis of 2,4,5-trisubstituted pyrroles was described by Driver et al. employing substituted 1-azidobuta-l,3-dienes in a cyclization reaction using catalytic amounts of zinc(ll) iodide [63]. A three-component zinc-catalyzed one-pot cyclization of aromatic and aliphatic propargylic acetates, silyl enol ethers, and primary amines to substituted pyrroles has been described by Zhan et al. The reaction sequence includes propargylation of the silyl enol ether, amination, 5-exo-(7ig-cyclization, and isomerization [64]. Hiroya and co-workers have shown... 

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