Li, Han, and coworkers of the Dalian Institute of Chemical Physics have reported an isocoumarin synthesis that proceeds through a nucleopalladative-oxidation olefination pathway (1).
Li, Han, and coworkers report the oxidative coupling of olefins and t-butyl 2-alkynylbenzoates to produce isocoumarins (1)
The isocoumarin products formed can possess some degree of complexity, based on the initial functionalization of the starting materials:
- the pendant olefin in the product may be functionalized with aryl or ether groups, based on the choice of olefin ( i.e. methyl acrylate, p-chlorophenyl styrene, etc.)
- The aromatic ring of the arylalkyn-ester substrate seems to tolerate methyl- and chloro-substituents well, and -OMe to a lesser extent.
‘numbering’ the atoms in author’s paper: 3- (3-cyclopropyl-1-oxo-1H-isochromen-4-yl)- acrylic tert-butyl ester.
Some background information. This author admits his weak knowledge of this compound class. To appreciate this paper a little review was required. Isocoumarins are somewhat obscure materials, and a first step was a to understand their numbering system.
Once you know the trick, it’s not hard. Carbon ’1′ is the carbonyl carbon, and then you count your way around the ring with the ring oxygen as atom ’2′. One item that was a little puzzling is the use of ’1H’ nomenclature in this compound class. The rule I am familiar with goes this way:
‘In a heterocyclic ring with maximum unsaturation, if the double bonds can be arranged in more than one way, then their positions are specified by nuumbering those nitrogen or carbon atoms which are not multiply-bonded. i.e. bear an ‘extra’ hydrogen atom, by italic capital ‘1H’ ’2H’ ’3H’ etc. The numerals indicate the position of these atoms having the extra hydrogen atom. ’ (2)
Apparently this rule can be adapted to coumarin compounds to denote a point of ‘saturation’ in what would have otherwise been a fully aromatic system. Not wanting to sink further into the morass of heterocyclic nomenclature, I was willing to accept this explanation. These compounds may also be named as 1H-2-benzopyran-1-ones and 3,4-benzo-2-pyrones, to further confuse the issue.
You may not have worked with isocoumarins previously; I certainly hadn’t. The authors cited some papers that represented examples in natural products and pharmaceuticals (3). A specific example includes thunberginol A (found in Japanese Hydrangea) (4).
You may be more familiar with coumarin compounds, (the anticoagulant and rodenticide warfarin / coumadin, and ‘coumarin’ itself – a fragrance compound once used to enhance the fragrance of pipe tobacco) (5). The synthesis of these compounds is unrelated to isocoumarin preparation. The final isomeric isocoumarin cousins are the chromones (1,4 benzopyrones).
Things that sound like isocoumarin – but which are different.
There appear to be a number of isocoumarin syntheses available to choose from, but the feature of the Lee & Han isocoumarin paper is the ‘one step’ synthesis of an olefinated isocoumarin. They cite the work of others toward this goal, including a two step sequence reported by Larock in 2003, which depends on a Heck coupling (performed in DMSO!) to contribute the olefin functionality (6).
As previously mentioned, the underlying mechanism of their reaction is nucleopalladation, one of three basic ways that Pd-C bonds are formed. Arguable the other two are more familiar to most organic chemists, if only by their associated ‘Name’ reactions:
- Pd-C bond forming method 1: Transmetallation (Stille, Suzuki, Hayama coupling reactions)
- C-H activation reactions via Pd- catalysis.
The authors contend that nucleopalladation provides a benefit in the synthesis of heterocycles in that both C-heteroatom and C-C bonds can be formed in tandem fashion. They spell out the key steps in this process and suggest that palladium plays two important functions in the reaction:
- initial activation of a C-C π bond (that of the 2-alkynyl group) toward intramolecular nucleophilic attack (by the ester carbonyl oxygen)
- final carbopalladation and β-hydride elimination step to produce the olefin group in the 4 position of the molecule.
A capsule summary of the isocoumarin synthesis of Li, Han et Al. follows:
Alkynylester (0.25 mmol), PdCl2 (0.025 mmol), acrylate (0.50 mmol) and DMSO (2.0 mL) were placed in a dry Schlenk tube. The mixture was heated for 16 hours at 85 °C under oxygen (balloon).
Workup involved brine washing, DCM extraction (2 x 20 mL), drying over sodium sulfate, and the crude product was purified by silica gel chromatography (pet ether / EtOAc).
In closing, a few points about the generality of the reaction:
- The alkynl ester is preferably a t-butyl ester; isopropyl esters seemingly provided lower reaction yields and screening work was performed exclusively using the t-butyl ester compounds.
- 2-alkynlbenzoic acid starting materials failed to provide olefinated products and were not explored.
- DMSO was chosen as reaction solvent due to the recognition by the authors that it is a good solbent in related cyclization-olefination work reported previously by Loh (olefinated isoquinoline synthesis) and Larock (olefinated napthalene synthesis). (6)
(1) Li, X.; Han, K.; Peng, Z.; Chen, D.; Song;G. J. Org. Chem. 77 (2012), 1579-1584.
(2) Sainsbury, M. Heterocyclic Chemistry (2001), 6.
(3) Subramanian, V.; Rso Batchu, V.; Barange, D.; Pal, M.J. J. Org. Chem. 70 (2005), 4778 b) Mail, R.S.; Babu, K.N. J. Org Chem. 63 (1998), 2488.
(4) Wikipedia.org, “Thunberginol A”. Accessed 26 February 2012.
(5) Wikipedia.org, “Coumarin”. Accessed 26 February 2012.
(6) Larock, R.C.; Doty, M.J.; Han, X.J. J. Org. Chem. 68 (2003) 5936 b) Loh, T.-P.; Feng, C. J. Am. Chem. Soc. 132 (2010), 17710.