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Five-membered ring heterocyclic compounds
3rd Lecture Year 2 2nd Semester 2024

Dr Hasanain Ali Abbas
Pharmaceutical Chemistry Department, Faculty of Pharmacy
Jabir Ibn Hayyan University for Medical & Pharmaceutical Sciences
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 Structure of pyrrole, furan and thiophene

The simplest of the five-membered heterocyclic compounds are pyrrole, furan,
and thiophene, each of which contains a single hetero atom.

The saturated derivatives are called pyrrolidine, tetrahydrofuran (THF), and
thiophane, respectively.

The bicyclic compounds made of a pyrrole, furan, or thiophene ring fused to a
benzene ring are called indole (or isoindole), benzofuran, and benzothiophene,
respectively.

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Pyrrole, furan and thiophene are considered as aromatic compounds since they
follow the Huckel’s aromaticity rules (4n+2 electron rule). The aromatic nature
and extra-stability of these compounds can also be supported by the formation of
different resonating structures as shown in below figures.

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 Bioactive Furans, Pyrroles and Thiophenes
Ranitidine was the world's biggest-selling prescription drug. It is an H2-receptor
antagonist and lowers stomach acid levels – used to treat stomach ulcers.

Ketorolac is an analgesic and anti-inflammatory drug.

Pyrantel is an anthelmintic agent and is used to treat worms in livestock.

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 Source of pyrrole, furan, and thiophene
Pyrrole and thiophene are found in small amounts in coal tar. During the
fractional distillation of coal tar, thiophene (b.p. 84) is collected along with the
benzene (b.p, 80); as a result ordinary benzene contains about 0.5% of
thiophene.
Thiophene can be synthesized on an industrial scale by the high-temperature
reaction between n-butane and sulfur.

Pyrrole can be synthesized in a number of ways. For example:

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The pyrrole ring is the basic unit of the porphyrin system, which occurs, for
example, in haemoglobin and in chlorophyll.

Furan is most readily prepared by decarbonylation (elimination of carbon
monoxide) of furfural (furfuraldehyde), which in turn is made from pentosans.

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Certain substituted pyrroles, furans, and thiophenes can be prepared from
the parent heterocycles by substitution; most, however, are prepared from
open-chain compounds by ring closure. For example:

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 Electrophilic substitution in pyrrole, furan and thiophene

Like other aromatic compounds, these five-membered heterocycles are
reactivate with electrophilic reagents to undergo electrophilic substitution
reactions such as: nitration, halogenation, sulfonation, and Friedel-Crafts
acylation. Whereas heterocyclic aromatic compounds tend to react by
substitution, simple cycloalkenes generally give addition reactions. The
aromatic five-membered heterocycles all undergo electrophilic substitution,
with a general reactivity order:

pyrrole >> furan > thiophene > benzene

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Some examples are given in the below diagram. The exceptional reactivity of
pyrrole is evidenced by its reaction with iodine, and formation of 2-acetylpyrrole
by simply warming it with acetic anhydride (no catalyst).

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 Orientation of pyrrole, furan and thiophene

There is a clear preference for substitution at the 2-position (α) of the ring,
especially for furan and thiophene. Reactions of pyrrole require careful
evaluation, since N-protonation destroys its aromatic character. Indeed, N-
substitution of this 2º-amine is often carried out prior to subsequent
reactions. For example, pyrrole reacts with acetic anhydride or acetyl
chloride and triethyl amine to give N-acetylpyrrole. Consequently, the
regioselectivity of pyrrole substitution is variable, as noted in the above
diagram.

An explanation for the general α-selectivity of these substitution reactions is
apparent from the mechanism outlined below.

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The intermediate formed by electrophile attack at C-2 is stabilized by charge
delocalization to a greater degree than the intermediate from C-3 attack.

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Functional substituents influence the substitution reactions of these
heterocycles in much the same fashion as they do for benzene. Indeed, once
one understands the ortho-para and meta-directing character of these
substituents, their directing influence on heterocyclic ring substitution is not
difficult to predict. Reactions 1 & 2 are 3-substituted thiophenes, the first by an
electron donating substituent and the second by an electron withdrawing
group. The third reaction has two substituents of different types in the 2 and 5-
positions.

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