Intramolecular cyclizations heterocycles from

Large ring heterocyclic radicals are not particularly well known as a class. Their behavior often resembles that of their alicyclic counterparts, except for transannular reactions, such as the intramolecular cyclization of 1-azacyclononan-l-yl (Scheme 1) (72CJCH67). As is the case with alicyclic ethers, oxepane in the reaction with r-butoxy radical suffers abstraction of a hydrogen atom from the 2-position in the first reaction step (Scheme 2) (76TL439). 

Cyclization arising from the intramolecular photoelimination of HC1, HBr, and HI has been extensively used in the synthesis of heterocycles and alkaloids. The mechanisms of these transformations have not in many cases been thoroughly investigated. Some undoubtedly are initiated by simple homolysis of the carbon-halogen bond whereas others involve photocycliza-tion and subsequent elimination of HX. 

In this approach, the SENA skeleton is assembled from nitroalkene (42) and nucleophile 56.With the exception of two examples (entries 1 and 2 in Table 3.2), the reaction does not stop at SENA 51, which either undergoes intramolecular cyclization through [3 + 2]-cycloaddition to give fused heterocycles (as a rule after elimination of trimethylsilanol) (198-200) or is involved in [3+ 2]-cycloaddition with specially added methyl vinyl ketone or methyl acrylate to form (after elimination of silanol) substituted isoxazolines in rather high yields (201). 

Another tetracyclic carbon skeleton, named cumbiane, has been isolated from Pseudopterogorgia elisahethae. Its representatives are the diterpenoids cumbiasin A (33) and B (34) [20] their structures and relative configurations were elucidated by interpretation of a combination of spectral data. The six-membered ring D was formed by connecting CIO and C16 of an elisabethane carbon skeleton. The carbocyclic skeleton of the cumbiasins is unprecedented and represents a new class of C20 rearranged diterpenes. The tricyclic seco-cumbiane skeleton is derived from the cumbiasins by cleavage of the C15-C16 bond. Due to intramolecular cyclizations two additional oxo-heterocycles are present in cumbiasin C (35) [20] (Fig. 7). 

The reaction of iminium ions with dihydropyridines is a method, suggested from biosynthetic studies, for the formation of carbon-carbon bonds to these six-membered heterocycles. The 1,4-dihydropyridine (8), a presumed intermediate from the reaction of ammonia with glutaraldehyde, reacts with the cyclic iminium ion (159) to give, after oxidation, nicotine (160) (72CC1091). Another example of this reaction has provided a total synthesis of olivacine (163). The 1,2-dihydropyridine ring system in (161), generated from its chromium tricarbonyl complex, was observed to undergo an intramolecular cyclization... 

The hexahydropyrimidine (58), formed from l-phenylpropane-l,2-dione and propane-1,3-diamine, is an excellent precursor for the a-diimine macrocyclic complexes (60), presumably via the amino ketone (59) (Scheme 36).126 In this case, intramolecular cyclization of (59) to (58) is reversible, so that the metal ion can exert a thermodynamic template effect in formation of the complex (60). This represents a further example of a long-known phenomenon in which a metal ion can stabilize an a-diimine structure by virtue of the formation of stable five-membered chelate rings. Many 2-hydroxy- or 2-mercapto-amines undergo reaction with a-dicarbonyl compounds to yield heterocyclic compounds rather than a-diimines. However, in the presence of suitable metal... 

Elimination of the fluoride ion from the CF3 group of carbanion B leads to the formation of olefin 54 with a terminal multiple bond. Intramolecular cyclization of olefin 54 gives a minor amount (5%) of seven-membered heterocycles 5-pentafluoroethyl-6-trifluoromethyl-5,7-difluoro-l,4-dioxacy-cloheptene-6 52 and 5-pentafhioroethyl-6-trifluoromethyl-7,7-difluoro-l,4-dioxacycloheptene-5 53. 

Metal complexes of heterocyclic compounds display reactivities changed greatly from those of the uncomplexed parent systems. All of the -electron system(s) of the parent heterocycle can be tied up in the complex formation, or part can be left to take part in alkenic reactions. The system may be greatly stabilized in the complex, so that reactions, on a heteroatom, for example, can be performed which the parent compound itself would not survive. Orbital energy levels may be split and symmetries changed, allowing hitherto forbidden reactions to occur. In short, a multitude of new reaction modes can be made possible by using complexes dimerization of azirines with a palladium catalyst serves as a typical example (Scheme 81). A variety of other insertion reactions, dimerizations, intramolecular cyclizations, and intermolecular addition reactions of azirines are promoted by transition metals. 

Until recently, the intramolecular cyclization procedure had been used only to synthesize fused heterocyclic structures. The first report of a bridged product, in 1978, involved only a minor amount (9%) of an azabicyclo[3.3.1]nonane derivative obtained from the reaction of ds-carveol with acetonitrile and BFj-EtiO. However, several effective examples are now known. These all involve reaction of the nitri-lium intermediate with an internal alkenic nucleophile to yield a 1-azacyclohexene ring and a new carbe-nium ion which undergoes conventional, but stereospecific, Ritter reaction fiom the least hindered face. Such reactions are typified by formation of the multicyclic structures (64 equation 38) 5<) and (65 equation 39), 5i considerable potential in the synthesis of complex nitrogen heterocyclic systems... 

Other examples from this study indicate that the reaction path followed by the nitrilium ion depends very much on the nature of the nucleophiles present. Thus, the allylindole (106) produced the imidate (107) through reaction of the nitrilium ion wiA methanol in preference to the electron-rich heterocyclic system (equation 45). In contrast, alcohol (108) underwent effective intramolecular cyclization (equation 46). 

This heterocyclic skeleton is accessible by four methods The first involves an intramolecular cyclization of the enolform of 8-bromo- or 8-chloro-7-(acylalkyl)-purinedione derivatives 39, which were prepared from the potassium salt of 8-bromopurinediones and a-bromodialkyl- or a-bromoalkyl aryl ketones 41 under reflux in dimethylformamide giving derivatives of oxazolo[2,3-/]-purine-2,4-dione 40 (86KGS1133) (Scheme 10). 

---