2-Chloropyridine

2-Chloropyridine is an organohalide with the formula C₅H₄ClN. It is a colorless liquid that is mainly used to generate fungicides and insecticides in industry. It also serves to generate antihistamines and antiarrythymics for pharmaceutical purposes.^[2]

Preparation

2-Choropyridine was originally described in 1898 by the chlorination of 2-hydroxypyridine.^[3] A typical chlorinating agent is phosphoryl chloride. It can also be generated by halogenating pyridine. This reaction affords a mixture of 2-chloro and 2,6-dichloropyridine.^[2]

Alternatively, 2-chloropyridines can be conveniently synthesized in high yields from pyridine-N-oxides.^[4]

Structure and properties

2-Chloropyridine reacts with nucleophiles to generate pyridine derivatives substituted at the second and fourth carbons on the heterocycle. Therefore, many reactions using 2-chloropyridine generate mixtures of products which require further workup to isolate the desired isomer.^[2]

Main reactions and applications

2-chloropyridine is primarily used to generate other pyridine derivatives. Some commercial products include pyrithione, pyripropoxyfen, chlorphenamine, and disopyramide. These reactions rely on chloride’s nature as a good leaving group to facilitate the transfer of a substrate onto the pyridine ring.^[2] Pyrithione, the conjugate base of 2-mercaptopyridine-N-oxide, is a fungicide found in some shampoos. It is generated from 2-chloropyridine by reacting the N-oxide of 2-chloropyridine with Na₂S in a basic solution, before adding aqueous HCl.^[5] Used as an antihistamine, pheniramine may be generated via several different pathways. One synthesis is to hydroformylate functionalized olefins. This reaction proceeds by reacting phenylacetonitrile with 2-chloropyridine in the presence of a base. The resulting intermediate is then alkylated by 2-(dimethylamino)ethyl chloride and the cyano group removed.^[6]

Environmental Properties

Though pyridine is an excellent source of carbon, nitrogen, and energy for certain microorganisms, introduction of a halogen moiety significantly retards degradation of the pyridine ring. With the exception of 4-chloropyridine, each of the mono- and di-substituted chloropyridines were found to be relatively resistant to microbiological degradation in soil or liquid media.^[7] Estimated time for complete degradation was > 30 days. 2-Chloropyridine exhibits extensive volatilization losses from water, less so when present in soil.^[8]

References

↑ Linnell, R. H., J. Org. Chem., 1960, 25, 290.
1 2 3 4 Shimizu, Shinkichi et al. Pyridine and Pyridine Derivatives. Ullmann’s Encyclopedia of Industrial Chemistry. 2000. doi:10.1002/14356007.a22_399
↑ Sell, William J.; Dootson, Frederick W. The chlorine derivatives of pyridine. Part I. Journal of the Chemical Society, Transactions 1898, 73, pp. 432-441. http://www.rsc.org/ejarchive/CT/1898/CT8987300432.pdf
↑ P. Naender, B. Gangadasu, Chilukuri Ramesh, B.C. Raju and V.J. Rao. Facile and Selective Synthesis of Chloromethypyridines and Chloropyridines using Diphosgene/Triphosgene. Synthetic Communications. 34, 6, 1097, 2004
↑ Cheng, Hefeng; She, Ji. 14. Improved preparation of 2-mercaptopyridine-N-oxide. Zhongguo Yiyao Gongye Zazhi. 1990, 21, (2), pp. 55-56. ISSN 1001-8255
↑ Botteghi, Carlo et al. New Synthetic Route to Pheniramines via Hydroformylation of Functionalyzed Olefins. 1994, 59, pp. 7125-7127. doi:10.1021/jo00102a044
↑ Sims, G. K. and L.E. Sommers. 1986. Biodegradation of pyridine derivatives in soil suspensions. Environmental Toxicology and Chemistry. 5:503-509.
↑ Sims, G. K. and L.E. Sommers. 1985. Degradation of pyridine derivatives in soil. Journal of Environmental Quality. 14:580-584.

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