N-Chlorosuccinimide (NCS)

Biographical Sketches

Introduction

N-Chlorosuccinimide (NCS) is a very powerful chlorinating reagent, which also finds applications as mild oxidizing agent. This colourless, commercially available, inexpensive solid is thermally stable to some extent. It is least toxic as well as highly selective compared to chlorinating agents, such as 1,3-dichloro-5,5-dimethylhydan­toin (NDDH) and trichloroisocyanuric acid (TCCA). In the last two decades, it has emerged as a useful mediator or catalyst for many chemical reactions, such as functional groups replacement, halocyclization, formation of ­heterocyclic systems, carbon-carbon bond formation, rearrangement, deprotections, and functional group transformations. [¹] NCS also possess some bactereostatic and anti-bactericidal activity as it forms hypochlorous acid upon slow hydrolysis with water. [²] NCS is soluble in carbon tetrachloride at room temperature while its conjugate product succinimide is not, which leads to easy separation from the reaction mixture.

Preparation

NCS was firstly prepared by Bender in 1886 by chlorination of succinimide with chlorinated lime. [³] It can also be prepared by the chlorination of succinimide with potassium hypochlorite or tert-butylhypochlorite or chlorine in aqueous sodium hydroxide. [4]

Abstracts

(A) Håkansson and co-workers have discovered the absolute asymmetric synthesis of 1-chloroindene in 87-89% ee and 78-97% yield utilizing NCS and a single crystal of novel diindenylzinc reagent [Zn(ind)2(pic)2]. [5]
(B) The application of NCS and an organophosphine reagent for the synthesis of polychlorinated hydrocarbon motifs with multiple sp [³] C-Cl bonds arranged in a regularly spaced pattern with proper ­stereochemical configuration has been developed by Tanaka and ­co-workers. [6]
(C) Nasim and Crooks have utilized the oxidative power of NCS for the convenient synthesis of pharmacologically important 1,2,4-thiadiazolidine-3,5-diones (TDZD) via an oxidative condensation of isothiocyanate and isocyanate. [7] This method provides a safe and easy alternate method for the synthesis of thiadiazolidinones to the classical reagents like chlorine gas or SO2Cl2.
(D) De Kimpe and co-workers have developed the chlorination of 1-alkyl-3,4-dihydroisoquinolines with NCS to yield 1-chloroalkyl-, 1-(2,2-dichloroalkyl)-, and 1-(trichloromethyl)-3,4-dihydroisoquinolines which serves as suitable precursors for the synthesis of functionalized isoquinolines by aromatization with alkoxide involving sequential 1-4,dehydrochlorination, tautomerization, and nucleophilic substitution. 1-Vinylisoquinoline and 1-methylisoquinolines could be synthesized selectively depending on the substitution pattern on position 1. [8]
(E) Yadav et al. have developed a simple, environmentally benign, and practical protocol for the selective synthesis of α-keto thioethers in excellent yields via α-sulfenylation of ketones with thiophenols mediated by NCS. [9]
(F) The thiourea-catalyzed regioselective synthesis of the chlorohydrins has been developed by Bentley et al. with NCS chlorination of olefins in the presence of water. Different olefins, such as styrenes, aliphatic olefins, stilbenes, chalcones, and indenes were found tolerable under the optimized reaction conditions. [¹0]
(G) α-Thio-β-chloroacrylamide analogues have been synthesized by treatment of α-thioamides with NCS. [¹¹] Different substituents, such as aryl and alkylthio as well as primary, secondary and tertiary amides have been employed. In most cases, the chloroacrylamides were formed exclusively as Z-stereoisomers; however, with tertiary propanamides or with amides derived from butanoic or pentanoic acid a mixture of E- and Z- isomers were formed.
(H) Michael et al. have explored the application of NCS for the functional group tolerant, exo-selective synthesis of a variety of five-and six-membered ring systems via a mild and facile palladium-catalyzed intramolecular chloramination of unactivated alkenes under mild conditions. [¹²] Various valuable acid sensitive groups were tolerated under the reaction conditions.
(I) A mild approach for the synthesis of benzonitriles from corresponding benzaldehyde oximes substituted with electron-donating groups using NCS and pyridine has been developed by Gucma and Goebiewski. [¹³] However, benzaldehyde oxime and oximes of aliphatic aldehydes are deprotected to the parent aldehydes.

References

• 1-1a Goebiewski WM. Gucma M. Synthesis  2007,  3599 
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• 1-1b Virgil SC. N- Chlorosuccinimide, In Encyclopedia of Reagents for Organic Synthesis   Paquette LA. John Wiley & Sons; New York: 1995.  Vol. 1:  p.768-773   and references cited therein
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• 1-2 Kohl HH. Wheatley WB. Worley SD. Bodor N. J. Pharm. Sci.  1980,  69:  1292 
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• 1-3 Bender G. Chem. Ber.  1886,  19:  2268 
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• 1-4a Tscherniac J. Chem. Ber  1901,  34:  4213 
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• 1-4b Zimmer H. Auddeth LF. J. Am. Chem. Soc.  1954,  76:  3856 
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• 1-4c Hirst M. J. Chem. Soc.  1922,  121:  2175 
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• 1-5 Lennartson A. Olsson S. Sundberg J. Håkansson M. Angew. Chem. Int. Ed.  2009,  48:  3137 
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• 1-6 Yoshimitsu T. Fukumoto N. Tanaka T. J. Org. Chem.  2009,  74:  696 
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• 1-7 Nasim S. Crooks PA. Tetrahedron Lett.  2009,  50:  257 
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• 1-8 Jacobs J. Van TN. Stevens CV. Markusse P. De Cooman P. Maat L. De Kimpe N. Tetrahedron Lett.  2009,  50:  3698 
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• 1-9 Yadav JS. Reddy BVS. Jain R. Baishya G. Tetrahedron Lett.  2008,  49:  3015 
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• 1-10 Bentley PA. Mei Y. Du J. Tetrahedron Lett.  2008,  49:  1425 
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• 1-11 Murphy M. Lynch D. Schaeffer M. Kissane M. Chopra J. O’Brien E. Ford A. Ferguson G. Maguire AR. Org. Biomol. Chem.  2007,  5:  1228 
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• 1-12 Michael FE. Sibbald PA. Cochran BM. Org. Lett.  2008,  10:  793 
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• 1-13 Gucma M. Go ebiewski WM. Synthesis  2008,  1997 
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References

• 1-1a Goebiewski WM. Gucma M. Synthesis  2007,  3599 
  Google Scholar
• 1-1b Virgil SC. N- Chlorosuccinimide, In Encyclopedia of Reagents for Organic Synthesis   Paquette LA. John Wiley & Sons; New York: 1995.  Vol. 1:  p.768-773   and references cited therein
  Google Scholar
• 1-2 Kohl HH. Wheatley WB. Worley SD. Bodor N. J. Pharm. Sci.  1980,  69:  1292 
  Google Scholar
• 1-3 Bender G. Chem. Ber.  1886,  19:  2268 
  Google Scholar
• 1-4a Tscherniac J. Chem. Ber  1901,  34:  4213 
  Google Scholar
• 1-4b Zimmer H. Auddeth LF. J. Am. Chem. Soc.  1954,  76:  3856 
  Google Scholar
• 1-4c Hirst M. J. Chem. Soc.  1922,  121:  2175 
  Google Scholar
• 1-5 Lennartson A. Olsson S. Sundberg J. Håkansson M. Angew. Chem. Int. Ed.  2009,  48:  3137 
  Google Scholar
• 1-6 Yoshimitsu T. Fukumoto N. Tanaka T. J. Org. Chem.  2009,  74:  696 
  Google Scholar
• 1-7 Nasim S. Crooks PA. Tetrahedron Lett.  2009,  50:  257 
  Google Scholar
• 1-8 Jacobs J. Van TN. Stevens CV. Markusse P. De Cooman P. Maat L. De Kimpe N. Tetrahedron Lett.  2009,  50:  3698 
  Google Scholar
• 1-9 Yadav JS. Reddy BVS. Jain R. Baishya G. Tetrahedron Lett.  2008,  49:  3015 
  Google Scholar
• 1-10 Bentley PA. Mei Y. Du J. Tetrahedron Lett.  2008,  49:  1425 
  Google Scholar
• 1-11 Murphy M. Lynch D. Schaeffer M. Kissane M. Chopra J. O’Brien E. Ford A. Ferguson G. Maguire AR. Org. Biomol. Chem.  2007,  5:  1228 
  Google Scholar
• 1-12 Michael FE. Sibbald PA. Cochran BM. Org. Lett.  2008,  10:  793 
  Google Scholar
• 1-13 Gucma M. Go ebiewski WM. Synthesis  2008,  1997 
  Google Scholar