Cycloaddition and Cycloisomerization Reactions

Rh(III)-metallocydes derived from 1,6-enynes are postulated as reactive intermediates in catalytic [4+2] and [5+2] cycloadditions, Pauson-Khand reactions and cycloisomerizations P. Cao, B. Wang, X. Zhang, J. Am. Chem. Soc. 2000, 122, 64901 and references cited therein. 

Double cyclization of iodoenynes is proposed to occur through a Rh(I)-acetylide intermediate 106, which is in equilibrium with vinylidene lOS (Scheme 9.18). Organic base deprotonates the metal center in the course of nucleophilic displacement and removes HI from the reaction medium. Once alkenylidene complex 107 is generated, it undergoes [2 + 2]-cycloaddition and subsequent breakdown to release cycloisomerized product 110 in the same fashion as that discussed previously (Scheme 9.4). Deuterium labeling studies support this mechanism. 

The photocycloaddition of (cyclic) a,(B-unsaturated ketones to alkenes affording cyclobutanes as products comprises the four reaction types shown in Sch. 1, i.e., (a) intermolecular enone + alkene cycloaddition (b) cycloisomerization of alkenylsubstituted enones (c) photocyclodimerization of enones, one ground state enone molecule acting as alkene and (d) cycloisomerization of fe-enones. 

Silver salts or reagents have received much attention in preparative organic chemistry because they are useful catalysts for various transformations involving C-G and C-heteroatom bond formation.309 Especially, the silver(i)/ BINAP (2,2 -bis(diphenylphosphino)-l,T-binaphthalene) system is a very effective catalyst for a variety of enantio-selective reactions, including aldol, nitroso aldol, allylation, Mannich, and ene reactions. Moreover, silver salts are known to efficiently catalyze cycloisomerization and cycloaddition reactions of various unsaturated substrates. Recently, new directions in silver catalysis were opened by the development of unique silver complexes that catalyze aza-Diels-Alder reactions, as well as carbene insertions into C-H bonds. 

For completeness. Appendix A.12 contains the 100% atom economical reactions cited in Trost s landmark publication. All were ring-forming reactions such as cycloadditions and prototropic cycloisomerizations, which satisfy the research interests of leading synthetic organic chemists. 

Rhodium is a rare white-silvery metal classified as a member of the platinum group metals. As a result, rhodium is commonly used as a catalyst in chemical reactions. It is also used in several chemical feedstock processes, including hydroformylation. Furthermore, rhodium has been used to catalyze more complex processes, such as higher order cycloaddition reactions. In addition, rhodium has been used in simpler reaction types such as hydrogenation and cycloisomerization. The fact that rhodium is effective for a wide range of chemical processes makes it an attractive metal for catalysis. 

Recent advances in the cyclizations catalyzed by transition metals and their complexes are reviewed. The catalytic cyclizations discussed here include various carbocyclizations, for example, cycloisomerization, cycloaddition, reductive cyclization, and so on cascade carbocyclizations, for example, cyclotrimerization, silylcarbocyclization, and Heck reaction carbonylative carbocyclizations cyclohy-drocarbonylations intramolecular hydrosilylations intramolecular silylformyla-tions and aldol cyclizations. These reactions serve as efficient and useful methods for the syntheses of a variety of heterocycles and carbocycles that are important... 

Carboni and coworkers developed the appUcation of a one-pot palladium-catalyzed cycloisomerization reaction between enynes 6/Diels-Alder cycloaddition/allylboration sequence to efficiently generate tricyclic structures 7 with complete control of the four new stereogenic centers formed in this process (Scheme 4.5) [6]. 

Computational studies have been reported for the PtCl2- and (PPh3)AuSbF6-catalysed cycloisomerization reactions of propargylic 3-indoleacetate which result in [3 -l- 2]- and [2 -I- 2]-cycloaddition products, respectively (Scheme 149). ... 

A rhodium-catalyzed cycloisomerization reaction of triyne 137 to 141 involves cleavage of the C=C triple bond (Scheme 7.49) [68]. The following reaction pathway is proposed initially, oxidative cyclization produces the rhodacycle 138, which then undergoes reductive elimination. The rhodium cyclobutadiene complex 139 is thus generated, and then undergoes oxidative addition to produce the rhodacycle 140. This isomerization from 138 to 140 would reduce the steric congestion of the heUcal structure. Subsequently, a cycloaddition reaction between the rhodacycle and the pendant alkyne moiety takes place to afford 141. 

All these results seemed to indicate that this reaction was ideal for the con-stmction of the (—)-berkelic acid skeleton. However, a serious problem was still unresolved at this point how to constmct the additional pyran ring contained in the natural product. Nevertheless, our experience on cycloisomerization reactions led us to speculate on the possibility that a unique metal complex could promote the cycloisomerization of alkynol 15 to give the exo-cyclic enol ether 19 and also that the cycloisomerization of an alkynyl-substituted salicylaldehyde 23 would give 25. Thus, activation of the alkyne of 15 should promote a hydroalkoxylation reaction to give the exocyclic enol ether 19. On the other hand, activation of the alkyne in 23 should promote a cascade cyclization process to finally give the 8//-isochromen-8-one derivative 25. The formal [4-F 2]-cycloaddition reaction between intermediates 19 and 25 would result in the formation of the core structure of (—)-berkehc acid 24 in a very simple way (Scheme 7). 

Ag-catalyzed in situ generation of azomethine ylides from alkynyl A-benzylidene glycinates 35 and their reaction with electron-deficient alkynes 36 were demonstrated by Su and Porco (Scheme 16.17) [26]. This reaction is supposed to be initiated by cycloisomerization of alkynyl imines 35 to isoquinolinium species A with the assistance of AgOTf. Subsequent proton transfer would afford azomethine ylides B with regeneration of Ag(I). 1,3-Dipolar cycloaddition with alkynes 36 followed by aerobic oxidation may furnish pyrroloisoquinoline products 37. It is worth noting that various types of electron-deficient alkynes, irrespective of internal and terminal alkynes, are applicable to this reaction. 

Next to cycloisomerizations, catalysts like 11 are also useful for [4 + 2] and even more interesting for [5 + 2] cycloaddition reactions (Fig. 11), which are very... 

Fiirstner A, Majima K, Martin R, Krause H, Kattnig E, Goddard R, Lehmann CW (2008) A cheap metal for a Noble task preparative and mechanistic aspects of cycloisomerization and cycloaddition reactions catalyzed by low-valent iron complexes. J Am Chem Soc 130 1992-2004... 

Another focus of this chapter is the alkynol cycloisomerization mediated by Group 6 metal complexes. Experimental and theoretical studies showed that both exo- and endo- cycloisomerization are feasible. The cycloisomerization involves not only alkyne-to-vinylidene tautomerization but alo proton transfer steps. Therefore, the theoretical studies demonstrated that the solvent effect played a crucial role in determining the regioselectivity of cycloisomerization products. [2 + 2] cycloaddition of the metal vinylidene C=C bond in a ruthenium complex with the C=C bond of a vinyl group, together with the implication in metathesis reactions, was discussed. In addition, [2 + 2] cycloaddition of titanocene vinylidene with different unsaturated molecules was also briefly discussed. 

Under optimized conditions, cycloisomerizations of a number of functionalized hept-l-en-6-ynes took place in good-to-excellent yields (Table 9.3). Heteroatom substitution was tolerated both within the tether and on its periphery. Alkynyl silanes and selenides underwent rearrangement to provide cyclized products in moderate yield (entries 6 and 7). One example of seven-membered ring formation was reported (entry 5). Surprisingly, though, substitution was not tolerated on the alkene moiety of the reacting enyne. The authors surmize that steric congestion retards the desired [2 + 2]-cycloaddition reaction to the point that side reactions, such as alkyne dimerization, become dominant. 

The chemical reactions possible with silver catalysis are multiple and cover cycloadditions, cycloisomerizations, allylations, aldol reactions, and even C-H bond activation. Also, asymmetric versions are known, even though they still need to be improved.3-10... 

Copper(I) catalysis is very well established to promote intramolecular [2+2] photocycloaddition reactions of l,n-dienes (review [351]). The methodology recently enjoyed a number of applications [352-354], It is assumed that CuOTf, which is commonly applied as the catalyst, coordinates the diene and in this way mediates a preorganization. The Ghosh group recently reported a number of CuOTf-catalyzed photochemical [2+2] cycloaddition reactions, in which an organocopper radical complex was proposed as a cyclization intermediate (which should, however, have a formal Cu(II) oxidation state) (selected references [355-357]). A radical complex must, however, not be invoked, since the process may either proceed by a [2+2] photocycloaddition in the coordination sphere of copper without changing the oxidation state or according to a cycloisomerization/reductive elimination process. 

The first such reaction published in 1908 by Ciamician and Silber was the light induced carvone —> carvonecamphor isomerization, corresponding to type b [1]. Between 1930 and 1960 some examples of photodimerizations (type c) of steroidal cyclohexenones and 3-alkylcyclohexenones were reported [2-5]. In 1964, Eaton and Cole accomplished the synthesis of cubane, wherein the key step is again a type b) photocycloisomerization [6]. The first examples of type a) reactions were the cyclopent-2-enone + cyclopentene photocycloaddition (Eaton, 1962) and then the photoaddition of cyclohex-2-enone to a variety of alkenes (Corey, 1964) [7,8]. Very soon thereafter the first reviews on photocycloaddition of a,(3-unsaturated ketones to alkenes appeared [9,10]. Finally, one early example of a type d) isomerization was communicated in 1981 [11]. This chapter will focus mainly on intermolecular enone + alkene cycloadditions, i.e., type a), reactions and also comprise some recent developments in the intramolecular, i.e., type b) cycloisomerizations. 

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