Cadogan–Sundberg indole synthesis
Cadogan–Sundberg indole synthesis | |
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Named after | John Cadogan Richard J. Sundberg |
Reaction type | Ring forming reaction |
Identifiers | |
RSC ontology ID | RXNO:0000509 |
The Cadogan–Sundberg indole synthesis, or simply Cadogan indole synthesis, is a name reaction in organic chemistry that allows for the generation of indoles from o-nitrostyrenes with the use of trialkyl phosphites, such as triethyl phosphite.[1][2][3][4][5][6][7]
Mechanism
o-nitrostyrene first reacts with triethyl phosphite, and the nitro group is converted to a nitroso group. The nitroso group then reacts with the alkene, and N-hydroxylindole is formed, which reacts again with triethyl phosphite to form the indole.[1][2][3][4]
Application
The Cadogan–Sundberg indole synthesis has been used as an intermediate step in the total synthesis of Tjipanazole E,[8] transforming 2-[trans-2-[5-Chloro-2-nitrophenyl)vinyl]-5-chloro-1H-indole to 5,5’-Dichloro-2,2’-biindole.
References
- ^ a b Cadogan, John Ivan George; Mackie, R. K. (1974). "Tervalent phosphorus compounds in organic synthesis". Chemical Society Reviews. 3 (1): 87–137. doi:10.1039/CS9740300087.
- ^ a b Wang, Zerong (15 September 2010). Comprehensive Organic Name Reactions and Reagents. doi:10.1002/9780470638859.conrr128. ISBN 9780470638859.
- ^ a b Sundberg, Richard J.; Yamazaki, Toshio (1 February 1967). "Rearrangements and ring expansions during the deoxygenation of β,β-disubstituted o-nitrostyrenes". The Journal of Organic Chemistry. 32 (2): 290–294. doi:10.1021/jo01288a009.
- ^ a b Sundberg, Richard J. (1 November 1965). "Deoxygenation of Nitro Groups by Trivalent Phosphorus. Indoles from o-Nitrostyrenes". The Journal of Organic Chemistry. 30 (11): 3604–3610. doi:10.1021/jo01022a006.
- ^ Gribble, Gordon W. (17 June 2016). "Cadogan–Sundberg Indole Synthesis". Indole Ring Synthesis: From Natural Products to Drug Discovery. pp. 266–277. doi:10.1002/9781118695692.ch26. ISBN 9781118695692.
- ^ Majgier-Baranowska, Helena; Williams, John D.; Li, Bing; Peet, Norton P. (1 February 1967). "Studies on the mechanism of the Cadogan–Sundberg indole synthesis". Tetrahedron Letters. 53 (35): 4785–4788. doi:10.1016/j.tetlet.2012.06.146.
- ^ Li, Jie Jack (4 January 2014). "Cadogan–Sundberg indole synthesis". Indole Ring Synthesis: From Natural Products to Drug Discovery. Springer. p. 102-103. doi:10.1007/978-3-319-03979-4_49. ISBN 978-3-319-03979-4.
- ^ Kuethe, Jeffrey T.; Wong, Audrey; Davies, Iaan W. (3 September 2003). "Effective Strategy for the Preparation of Indolocarbazole Aglycons and Glycosides: Total Synthesis of Tjipanazoles B, D, E, and I". Organic Letters. 5 (20): 3721–3723. doi:10.1021/ol035418r. PMID 14507214.
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- Addition reaction
- Elimination reaction
- Polymerization
- Reagents
- Rearrangement reaction
- Redox reaction
- Regioselectivity
- Stereoselectivity
- Stereospecificity
- Substitution reaction
- A value
- Alpha effect
- Annulene
- Anomeric effect
- Antiaromaticity
- Aromatic ring current
- Aromaticity
- Baird's rule
- Baker–Nathan effect
- Baldwin's rules
- Bema Hapothle
- Beta-silicon effect
- Bicycloaromaticity
- Bredt's rule
- Bürgi–Dunitz angle
- Catalytic resonance theory
- Charge remote fragmentation
- Charge-transfer complex
- Clar's rule
- Conformational isomerism
- Conjugated system
- Conrotatory and disrotatory
- Curtin–Hammett principle
- Dynamic binding (chemistry)
- Edwards equation
- Effective molarity
- Electromeric effect
- Electron-rich
- Electron-withdrawing group
- Electronic effect
- Electrophile
- Evelyn effect
- Flippin–Lodge angle
- Free-energy relationship
- Grunwald–Winstein equation
- Hammett acidity function
- Hammett equation
- George S. Hammond
- Hammond's postulate
- Homoaromaticity
- Hückel's rule
- Hyperconjugation
- Inductive effect
- Kinetic isotope effect
- LFER solvent coefficients (data page)
- Marcus theory
- Markovnikov's rule
- Möbius aromaticity
- Möbius–Hückel concept
- More O'Ferrall–Jencks plot
- Negative hyperconjugation
- Neighbouring group participation
- 2-Norbornyl cation
- Nucleophile
- Kennedy J. P. Orton
- Passive binding
- Phosphaethynolate
- Polar effect
- Polyfluorene
- Ring strain
- Σ-aromaticity
- Spherical aromaticity
- Spiroaromaticity
- Steric effects
- Superaromaticity
- Swain–Lupton equation
- Taft equation
- Thorpe–Ingold effect
- Vinylogy
- Walsh diagram
- Woodward–Hoffmann rules
- Woodward's rules
- Y-aromaticity
- Yukawa–Tsuno equation
- Zaitsev's rule
- Σ-bishomoaromaticity
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