Photocycloaddition synthesis

Photocycloaddition. Synthesis of the highly carcinogenic polycycHc hydrocarbons, eg (51) [72735-91-2] may be affected by photocycloaddition of 2-bromo-3-methoxy naphthoquinone [26037-61-6] with 1,1-diarylethylenes such as l,l-bis(p-methoxyphenyl)ethene (41). 

Mizuno, K., Kagano, H., and Otsuji, Y. (1983) Regio- and stereoselective intramolecular photocycloaddition synthesis of macrocyclic 2,co-dioxabicyclo [n. 2.0] ring system. Tetrahedron Letters, 24, 3849-3850. 

Sarkar N, Nayek A, Ghosh S (2004) Copper(l)-catalyzed intramolecular asymmetric [2+2] photocycloaddition. Synthesis of both enantiomers of cyclobutane derivatives. Org Lett 6 1903-1905... 

The photocycloaddition of arylazirines with a variety of multiple bonds proceeds in high yield and provides a convenient route for the synthesis of five-membered heterocyclic rings. Some of the dipolarophiles include azodicarboxylates, acid chlorides, vinylphosphonium salts and p-quinones. 

Photochemical [2 + 2] cycloaddition is a powerful way to produce cyclobutanes, which, in turn, are reactive synthesis intermediates. N-Methylpyrrole adds aldehydes via [2 -I- 2] photocycloaddition to give transient oxetanes with high regioselectivity Ring-opening produces 3-(oi-hydroxyalkyl)pyrroles which are oxidized easily to 3-arylpyrroles, such as 3-BUTYROYL-l-METHYL-PYRROLE. With a special apparatus, ethylene is conveniently added to 3-methyl-... 

In recent years the application of photocycloaddition reactions to organic synthesis has been growing in importance. - The procedure described is illustrative of a general method based on a photocycloaddition reaction for the introduction of an activated alkyl group specifically to the a-carhon atom of an a,/3-unsaturated cyclohexenone. Especially significant is the fact that the method is also applicable to... 

In this synthesis, we have witnessed the dramatic productivity of the intramolecular enone-olefin [2+2] photocycloaddition reaction. This single reaction creates three contiguous and fully substituted stereocenters and a strained four-membered ring that eventually provides the driving force for a skeletal rearrangement to give isocomene. 

Photocycloaddition of Alkenes and Dienes. Photochemical cycloadditions provide a method that is often complementary to thermal cycloadditions with regard to the types of compounds that can be prepared. The theoretical basis for this complementary relationship between thermal and photochemical modes of reaction lies in orbital symmetry relationships, as discussed in Chapter 10 of Part A. The reaction types permitted by photochemical excitation that are particularly useful for synthesis are [2 + 2] additions between two carbon-carbon double bonds and [2+2] additions of alkenes and carbonyl groups to form oxetanes. Photochemical cycloadditions are often not concerted processes because in many cases the reactive excited state is a triplet. The initial adduct is a triplet 1,4-diradical that must undergo spin inversion before product formation is complete. Stereospecificity is lost if the intermediate 1,4-diradical undergoes bond rotation faster than ring closure. 

Scheme 54 summarizes Font s synthesis of (+)-grandisol (36), the male pheromone of the cotton boll weevil (Anthonomus grandis) [80]. The key-step is the double [2+2] photocycloaddition of ethylene to bis(a,(3-butenohde) A to give B, which yielded C after glycol cleavage. The recently identified pheromone of the oleander scale (Aspidiotus nerii) possesses a structure similar to that of grandisol (Scheme 54), and its synthesis was reported by Ducrot [81 ] and also by Guerrero [82,83]. 

Although Wender s synthesis was completed prior to Hudlicky s, it was published later [65]. It utilized the technique of mefa-photocycloaddition of arenes that Wender developed into a general method of synthesis for both angular and linear triquinanes. The overall strategy was centered around an intramolecular Diels-Alder cycloaddition for construction of the internal six-membered ring of the target. 

The synthesis of nitrogen containing heterocyclic systems by photocylo-addition processes is virtually limited to examples involving [ 2 + 2] cycloaddition of imines, nitriles, and azo compounds. Successful additions are few in number and the requirements for success uncertain. The reactions do not proceed with the facility with which carbonyl containing compounds undergo photocycloaddition to alkenes to give oxetans, and various explanations have been advanced to account for this observed lack of reactivity.226... 

Photo-induced conversions are also important synthetically. The photocycloaddition of 5-substituted uracils 69 with ethylene has been used for the synthesis of 2-aminocyclobutanecarboxylic acids. The addition reaction worked well with carbon and fluorine substituents and also with a Cbz-protected amino. However, uracils with other 5-nitrogen substituents (NH2, NHBn and NO2) failed, only starting material being recovered. The sequence also worked for the 6-isomers but somewhat less consistently <06SL1394>. 

This chapter deals with [2 + 2]cycloadditions of various chromophors to an olefinic double bond with formation of a four-membered ring, with reactions proceeding as well in an intermolecular as in an intramolecular pattern. Due to the variety of the starting materials available (ketones, enones, olefins, imines, thioketones, etc.. . .), due to the diversity of products obtained, and last but not least, due to the fact that cyclobutanes and oxetanes are not accessible by such a simple one-step transformation in a non-photo-chemical reaction, the [2+2]photocycloaddition has become equivalent to the (thermal) Diels-Alder reaction in importance as for ring construction in organic synthesis. 

The uniqueness of the intramolecular 1,3-photocycloaddition of arenes to olefins with the developement of three new rings and up to six stereocentres has been efficiently demonstrated in the synthesis of (+)-a-cedrene from the... 

Mechanistic evidence indicates 450,451> that the triplet enone first approaches the olefinic partner to form an exciplex. The next step consists in the formation of one of the new C—C bonds to give a 1,4-diradical, which is now the immediate precursor of the cyclobutane. Both exciplex and 1,4-diradical can decay resp. disproportionate to afford ground state enone and alkene. Eventually oxetane formation, i.e. addition of the carbonyl group of the enone to an olefin is also observed452. Although at first view the photocycloaddition of an enone to an alkene would be expected to afford a variety of structurally related products, the knowledge of the influence of substituents on the stereochemical outcome of the reaction allows the selective synthesis of the desired annelation product in inter-molecular reactions 453,454a b). As for intramolecular reactions, the substituent effects are made up by structural limitations 449). 

Allenes behave as somehow special olefins in such photocycloadditions 476a,b,477) Additions of enones to allene have been used as key step in the synthesis of the alkaloids annotinine 478a) (4.65) and chasmanine (4.66) 478b). 

The literature of diene and polyene photochemistry provides many cases of synthetically useful reactions. As a result, certain arbitrary decisions have been made regarding what is covered in this chapter. For example, intramolecular [2 + 2]-photocycloaddition reactions of a, >-dienes can be formally included under the general rubric of diene photochemistry. However, we have chosen to restrict our discussion to dienes and polyenes which constitute a self-contained chromophore, viz. conjugated, cross-conjugated and 1,4-diene systems. Likewise, arene-olefin photocycloadditions will not be considered. These two broad classes of photoreactions have been applied extensively in synthesis, and have been the subject of recent reviews3,4. 

The [2+2]-photocycloaddition of carbonyl groups with olefins (Paterno-Buchi reaction) is one of the oldest known photochemical reactions and has become increasingly important for the synthesis of complex molecules. Existing reviews have summarized the mechanistic considerations and defined the scope and limitations of this photocycloaddition73. Although this reaction likely proceeds via initial excitation of the carbonyl compound and not the excited state of the diene, the many examples of this reaction in natural product synthesis justify inclusion in this chapter. 

These cycloadducts, at their most elementary level, are excellent intermediates for the synthesis of 3-substituted furan derivatives. For example, Kawanisi and coworkers reported a synthesis of perillaketone 174 in which the critical step was a Paterno-BUchi photocycloaddition between furan and 4-methylpentanal in the presence of methanesul-fonic acid (Scheme 39)82. This reaction furnished two initial photoadducts, 172 and 173. The unexpected product 173 presumably arises from a Norrish Type II cleavage of 4-methylpentanal to give acetaldehyde, and subsequent cycloaddition with furan. The desired cycloadduct 172 was then converted uneventfully to 174 via acid-catalyzed aromatization and oxidation. 

Schreiber and his coworkers have published extensively over the past decade on the use of this photocycloaddition for the synthesis of complex molecules730 81. Schreiber was the first to recognize that the bicyclic adducts formed in these reactions could be unmasked under acidic conditions to afford threo aldol products of 1,4-dicarbonyl compounds (175 to 176) (Scheme 40). The c -bicyclic system also offers excellent stereocontrol in the addition of various electrophilic reagents (E—X) to the enol ether of these photoadducts on its convex face (175 to 177). This strategy has been exploited in the synthesis of a variety of architecturally novel natural products. 

Hoveyda has also studied the intramolecular variant of the furan-carbonyl photocycloaddition87. Several examples of this reaction, each of which proceeds in modest yield, are shown in Scheme 44. However, given the ease of synthesis of the starting materials and the complexity of the adducts produced in these photocycloadditions, these... 

Zamojski and coworkers have explored the use of the furan-carbonyl photocycloaddition in asymmetric synthesis, with somewhat limited success88. Irradiation of chiral glyoxylate derivative 196 [R = (R)(—)-menthyl and (R)(—)-8-phenylmenthyl] afforded... 

---