Pyrroles, intramolecular reactions with

The most useful cyclizations via intramolecular reaction with a carbonyl group involve 4-(2-oxoalkyl)isoxazoles, leading to pyrroles (Scheme 25) and 4-(3-oxoalkyl)isoxazoles, leading to pyridine derivatives (Scheme 26). 

An intramolecular reaction with primary amine as the nucleophile that was prepared in situ by the reduction of the nitro group in pyrrole 1319 resulted in the pyrrolo[2,Tf]benzo[/ ]diazepine 1320, which indicates that the amino group reacts via condensation with the aldehyde group rather than via substitution of the chloro group (Equation 287) <2005T5831>. 

Transition-metal-mediated C—X bond formation by intramolecular reactions with alkynes is a powerful strategy for the construction of heteroarene rings such as pyridines, pyrroles, and furans. Because of the wide availability of Sonogashira coupling of various haloarenes with terminal alkynes, these transformations provide efficient routes to synthesize fused heteroarenes, including isoquinolines, indoles, and benzofurans. In this chapter the construction of aromatic rings by transition-metal-catalyzed or transition-metal-mediated intramolecular C—X bond formation between C—X or X—H and alkynes is described. As shown in Scheme 19.1, Section... 

The use of a vinylphosphonium salt as the source of the QQ fragment instead of the more commonly employed 1,2-dicarbonyl substrate is illustrated by the pyrrole synthesis in Scheme 79b (8UOC2570). A particularly interesting feature is the intramolecular Wittig reaction with an amide carbonyl group. A very useful synthesis of pyrroles depends upon the addition of the anion of p-toluenesulfonylmethyl isocyanide (TOSMIC) to a,/3-unsatur-... 

The last method for the preparation of 2-quinolones described in this chapter relies on a intramolecular Heck cyclization starting from heteroaryl-amides (Table 2) [57]. These are synthesized either from commercially available pyrrole- and thiophene-2-carboxylic acids (a, Table 2) or thiophene-and furan-3-carboxylic acids (b, Table 2) in three steps. The Heck cyclization is conventionally performed with W,Ar-dimethylacetamide (DMA) as solvent, KOAc as base and Pd(PPh3)4 as catalyst for 24 h at 120 °C resulting in the coupled products in 56-89% yields. As discussed in Sect. 3.4, transition metal-catalyzed reactions often benefit from microwave irradiation [58-61], and so is the case also for this intramolecular reaction. In fact, derivatives with an aryl iodide were successfully coupled by conventional methods, whereas the heteroarylbromides 18 and 19, shown in Table 2, could only be coupled in satisfying yields by using MAOS (Table 2). 

The preparation of 3-vinylpyrroles was investigated utilizing the Horner-Wads worth-Emmons reaction with 3-formyl-lV-tosylpyrrole <06S1494>. The intramolecular acylation of pyrrole-2-Weinreb amides provided access to novel indolizinone derivatives <06T6182>. The amidation of pyrrole-2-carbonyl chloride was utilized as a key step in the preparation of pyrrole-oxazole analogue 90 of the insecticide Pirate <06S1975>. 

Among early reported Pd-catalyzed reactions, the Mori-Ban indole synthesis has proven to be very useful for pyrrole annulation. In 1977, based on their success of nickel-catalyzed indole synthesis from 2-chloro-fV-allylaniline, the group led by Mori and Ban disclosed Pd-catalyzed intramolecular reactions of aryl halides with pendant olefins [122]. Compound 102, easily prepared from 2-bromo-lV-acetylaniline and methyl bromocrotonate, was adopted as the cyclization precursor. Treatment of 102 with Pd(OAc)2 (2 mol%), Ph3P (4 mol%) and NaHCQ3... 

The amino pyrrole 29 derived from the reaction with phenylhydrazine <1998JOC9131> was found to undergo an acid-catalyzed intramolecular condensation with the carbonyl present to give the 3//-pyrrolo[l,2-A pyrazole 30 ring system in a good yield (75%) (Equation 2). 

If secondary AAs are heated in the presence of aldehydes containing a proximate terminal double or triple bond and then condensed, decarboxylation and intramolecular cycloaddition tri-, tetra-, penta-, or hexa-cyclic cycloadducts with a condensed pyrrole ring are formed. An example is the reaction with sarcosine (Scheme 55) (88T4953). 

Pyrroles, indoles and benzo[ft]thiophene act as good dienophiles in inverse electron demand Diels-Alder reactions with 1,2-diazines, 1,2,4-triazines and sy/n/n-tetrazines. This is examplified by the formation of compounds (189) in excellent yields on interaction of indoles and benzo[c]thiophene with dimethyl l,2,4,5-tetrazine-3,6-dicarboxylate (87JOC4610 90JOC3257). There are also many examples of such intramolecular reactions, e.g. (190 — 191). 

Palladium-catalyzed coupling reactions of the Heck type have in many instances involved indole and pyrrole derivatives. Although the mechanisms are complex, organopalladium species are implicated (84H(22)1493). Vinylation of A-substituted-3 -iodoindoles with amidoacrylate groups provides a useful functionalization of indoles (Scheme 81) (90JOM(39l)C23). Yields are improved in intramolecular reactions, e.g. (406 — 407) and (408 — 409) <92H(34)219,91CPB2830). 

The intramolecular reaction of carbenoids with pyrroles is extremely effective and leads to the formation of heterobicyclic systems in high yield, as can be seen in the simple systems shown in equation (44).163 The reaction is so favorable that even an alkylcarbenoid capable of hydride migration could be utilized to generate a bicyclic system (218), but formation of (219) was a competing reaction in this case (equation 45).166... 

Treatment of 340 with paraformaldehyde 341 in EtOH gave 342 through an intramolecular cyclization, whereas the reaction with triethyl orthoformate resulted in the formation of343 and the thiadiazepine 344 (Scheme 71). The pyrrole 343 was converted into 344 under acidic conditions <1997FES375>. 

Although brominated derivatives of the five-membered heterocycles may be prepared by reactions of the co-ordinated ligands, these may then undergo further reactions with nucleophiles. As an example, the nucleophilic displacement of bromide from 8.15 by sulfide has been used to form new macrocyclic systems (Fig. 8-12). The palladium probably serves a dual function in this reaction. First, it organises the open-chain ligand such that the two reactive sites are held in proximity, so allowing the intramolecular formation of the sulfide and, second, it may activate the pyrrolic ring to nucleophilic displacement of bromide. 

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