Pyrrole substitutive addition

Some advances have been made in the Paal-Knorr synthesis of pyrroles by the condensation of primary amines with 1,4-dicarbonyl species. For instance, a new synthetic route to monosubstituted succinaldehydes allows for the facile preparation of 3-substituted pyrroles <96TL4099>. Additionally, a general method for the synthesis of 1-aminopyiroles has been devised by the condensation of commercially available 2,2,2-trichloroethyl- or 2-(tri-methylsilyl)ethylhydrazine with 1,4-dicarbonyl compounds <96JOCl 180>. A related route to such compounds involves the reaction of a-halohydrazones with p-dicarbonyl compounds <96H(43)1447>. Finally, hexamethyldisilazane (HMDS) can be utilized as the amine component in the Paal-Knorr synthesis in the presence of alumina, and this modification has been employed in the synthesis of tm azaprostacyclin analog <96S1336>. 

As previously described, the 3//-pyrrolium adduct 50 is obtained from the TBSOTf-promoted aldol reaction between the 1-methylpyrrole complex 21 and acetaldehyde diethylacetal (Figure 11). Deprotonation of 50 occurs at C-3 with i-Pr2EtN to give the corresponding -substituted lH-pyrrole complex. Addition of triflic acid results in the elimination of ethanol to give the azafulvenium complex 141 as a 3 2 mixture of diastereomers (Figure 25). Deprotonation of 141 results in formation of the unstable unsubstituted P-vinylpyrrole complex 142, which can be trapped in situ with N-phenyl maleimide (vide infra). 

Pyrrole-substituted [1-amino ester 394 was synthesized via aza-Michael conjugate addition (Scheme 81) [149]. 

The Birch reduction has been applied to electron-deficient pyrroles substituted with a chiral auxiliary at the C(2)-position <1999TL435>. Using either (—)-8-phenylmenthol or (- -)-/ra /-2-(ot-cumyl)cyclohexanol as auxiliaries, high levels of stereoselectivity were obtained. Pyrrole 911, prepared from the l/7-pyrrole-2-carboxylic acid 910 in 90% yield, was reduced under modified Birch conditions (Scheme 176). The best conditions involved lithium metal (3 equiv), liquid ammonia and THE at —78°C. The addition of A, A -bis(2-methoxyethyl)amine (10 equiv) helped to reduce side reactions caused by the lithium amide formed in the reaction <1998TL3075>. After 15 min, the Birch reductions were quenched with a range of electrophiles and in each case 3,4-dehydroproline derivatives 912 were formed in excellent yields and with good diastereoselectivities. 

However, with less active philodienes furan undergoes substitutive addition, and for pyrrole this entirely replaces the diene synthesis 39... 

A review on the chemistry of fused aromatic heterocyclic systems containing the furan ring fused with five- or six-membered rings and their condensed derivatives has been published <90CCC597>. The authors focus their attention on the substitution, addition, and cycloaddition reactions of condensed furo[3,2-fe]pyrroles. 

In order to overcome issues such as inductive and steric effects in polymerizing substituted monomers, less-reactive substituted monomers can be either copolymerized with unsubstituted monomers or homopolymerized under more controlled conditions. In addition, it is important for the substitution to avoid locations that will impede polymer growth. For example, in the case of aniline, the substitution should only be in the meta and/or ortho positions and in the case of aromatic heterocyclics such as thiophene and pyrrole, substitution should only occur in the p position. ... 

In recent years, synthesis of pyrroles has drawn the attention of chemists. Traditional methods used for pyrrole synthesis include the Hantzsch reaction [45] and the Paal-Knorr condensation reaction [46,47], The latter is the most widely used method, which involves the cyclocondensation reaction of 1,4-dicarbonyl compounds with primary amines to produce substituted pyrroles. In addition, there are several methods such as 1,3-dipolar cydoaddition reaction, aza-Wittig reaction, reductive coupling, and titanium-catalyzed hydroamination of diynes. Scheme 1 shows several catalysts used in this type of reaction [44]. 

The synthesis will therefore normally produce a 2,4-substituted pyrrole, with in addition an ester group or an acyl group at the 3-position, if a keto ster or a diketone respectively has been employed, and an ester group or an alkyl (aryl) group at the 5-position, according to the nature of the amino-ketone. 

Endo adducts are usually favored by iateractions between the double bonds of the diene and the carbonyl groups of the dienophile. As was mentioned ia the section on alkylation, the reaction of pyrrole compounds and maleic anhydride results ia a substitution at the 2-position of the pyrrole ring (34,44). Thiophene [110-02-1] forms a cycloaddition adduct with maleic anhydride but only under severe pressures and around 100°C (45). Addition of electron-withdrawiag substituents about the double bond of maleic anhydride increases rates of cycloaddition. Both a-(carbomethoxy)maleic anhydride [69327-00-0] and a-(phenylsulfonyl) maleic anhydride [120789-76-6] react with 1,3-dienes, styrenes, and vinyl ethers much faster than tetracyanoethylene [670-54-2] (46). 

The light-induced rearrangement of 2-phenyl- to 3-phenyl-thiophene may occur by a similar mechanism an equilibrium between the bicyclic intermediate (26) and the cyclopro-penylthioaldehyde (27) has been suggested (Scheme 2). The formation of IV-substituted pyrroles on irradiation of either furans or thiophenes in the presence of a primary amine supports this suggestion (Scheme 3). Irradiation of 2-phenylselenophene yields, in addition to 3-phenylselenophene, the enyne PhC=C—CH=CH2 and selenium. Photolysis of 2-phenyltellurophene furnishes solely the enyne and tellurium (76JOM(108)183). 

The high reactivity of pyrroles to electrophiles is similar to that of arylamines and is a reflection of the mesomeric release of electrons from nitrogen to ring carbons. Reactions with electrophilic reagents may result in addition rather than substitution. Thus furan reacts with acetyl nitrate to give a 2,5-adduct (33) and in a similar fashion an adduct (34) is obtained from the reaction of ethyl vinyl ether with hydrogen bromide. 

Pyrrole, furan or thiophene do not react with nucleophilic reagents by substitution or addition but only by proton transfer. However, it should be noted that protonated pyrroles are susceptible to nucleophilic attack (see Section 3.02.2.4.5). 

Furan and thiophene undergo addition reactions with carbenes. Thus cyclopropane derivatives are obtained from these heterocycles on copper(I) bromide-catalyzed reaction with diazomethane and light-promoted reaction with diazoacetic acid ester (Scheme 41). The copper-catalyzed reaction of pyrrole with diazoacetic acid ester, however, gives a 2-substituted product (Scheme 42). 

A -Amino- and A-substituted amino-pyrroles readily undergo Diels-Alder additions and add to activated alkynes at room temperature. The resulting azanorbornadienes extrude A-aminonitrenes and this forms the basis of an unusual synthesis of benzene derivatives (81S753,81TL3347). It has been found that ethyl/3-phenylsulfonylpropiolate (135) is a superior dienophile to DMAD (Scheme 50). 

A-Substituted pyrroles, furans and dialkylthiophenes undergo photosensitized [2 + 2] cycloaddition reactions with carbonyl compounds to give oxetanes. This is illustrated by the addition of furan and benzophenone to give the oxetane (138). The photochemical reaction of pyrroles with aliphatic aldehydes and ketones results in the regiospecific formation of 3-(l-hydroxyalkyl)pyrroles (e.g. 139). The intermediate oxetane undergoes rearrangement under the reaction conditions (79JOC2949). 

There are reports of an increasing number of palladium-assisted reactions, in some of which the palladium has a catalytic function. Thus furan and thiophene undergo facile palladium-assisted alkenylation giving 2-substituted products. Benzo[6 Jfuran and TV- acetyl-indole yield cyclization products, dibenzofurans and carbazoles respectively, in addition to alkenylated products (8UOC851). The arylation of pyrroles can be effected by treatment with palladium acetate and an arene (Scheme 86) (81CC254). 

In addition to electrophilic attack on the pyrrole ring in indole, there is the possibility for additions to the fused benzene ring. First examine the highest-occupied molecular orbital (HOMO) of indole. Which atoms contribute the most What should be the favored position for electrophilic attack Next, compare the energies of the various protonated forms of indole (C protonated only). These serve as models for adducts formed upon electrophilic addition. Which carbon on the pyrrole ring (C2 or C3) is favored for protonation Is this the same as the preference in pyrrole itself (see Chapter 15, Problem 2)1 If not, try to explain why not. Which of the carbons on the benzene ring is most susceptible to protonation Rationalize your result based on what you know about the reactivity of substituted benzenes toward electrophiles. Are any of the benzene carbons as reactive as the most reactive pyrrole carbon Explain. 

Shortly thereafter, Knorr reported that combining ammonia or primary amines with 1,4-dicarbonyls furnished substituted pyrroles (see Section 2.2), and Paal produced thiophenes by addition of hydrogen sulfide with 1,4-dicarbonyls. ... 

Although pyrrole appears to be both an amine and a conjugated diene, its chemical properties are not consistent with either of these structural features. Unlike most other amines, pyrrole is not basic—the pKa of the pyrrolin-ium ion is 0.4 unlike most other conjugated dienes, pyrrole undergoes electrophilic substitution reactions rather than additions. The reason for both these properties, as noted previously in Section 15.5, is that pyrrole has six 77 electrons and is aromatic. Each of the four carbons contributes one... 

The condensation of 2,5-diunsubstituted pyrroles with formic acid20 is a viable method to produce porphyrins. However, the most common procedure21 22 involves the heating of the corresponding pyrroles 1 with aldehydes and aldehyde derivatives like imines or a Mannich reagent in the presence of acid. The reaction is initiated by electrophilic attack of the aldehyde (or aldehyde derivative) to the pyrrole 1. The formed (hydroxyalkyl)pyrrole 3 then undergoes electrophilic substitution with another pyrrole to form a dipyrrylmethane 4. Repeated addition of aldehyde and pyrrole finally forms a tetrameric (hydroxyalkyl)bilane 5. 

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