Labile bicyclic

Again, the bicyclic valence isomer coexists in sufficient concentration, that the bicyclic peroxide 19 was readily accessible in ca. 20% yield. Alternatively, the thermally labile bicyclic valence isomer of cyclooctatetraene, namely bicyclo[4.2.0]-octa-2,4,7-triene, was converted into the corresponding endoperoxide on low temperature singlet oxygenation and reduced with diimide to yield 19. 

A review of the synthesis and polymerization of bicyclic acetals and orthoesters Is presented, and the relationship between ring structure and the ability to polymerize Is discussed. The highly labile bicyclic acetals and orthoesters were synthesized at high tenr-perature In dloctyl phthalate under vacuum In order to remove the monomers as soon as they form. The ability of the bicyclic monomers to polymerize falls In the same sequence as the ring strain [2.2.1] > [2.2.2] >... 

The often inaccessible and labile isoindoles can be accessed by the BZ reaction, as can be heteroisoindoles, such as 32. " Novel pyrroles fused to rigid bicyclic skeleta are readily crafted via a BZ reaction. Certain nitroheterocycles undergo the BZ... 

The bicyclic nature of the labile adduct (79) from 3-methyl-pyridine was established by Acheson and Taylor who found that hydrogenation, yielding (80), followed by oxidation gave pyridine-3,4,5-tricarboxylic acid. This conclusion is consistent with Diels and Alder s observations that acid hydrolysis of the labile pyridine adduct gave pyridine and some crotonaldehyde, whereas alkaline hy-... 

The cycloaddition reaction of compound 6 with N-aryl- and N-aralkylazides 23 was also investigated (967(52)7183). Thiadiazabicyclo[3.1.0]hexene derivatives 25 were obtained from the labile triazoline intermediate 24 through nitrogen elimination. This bicyclic system underwent thermal transformation, producing thiadiazine dioxides 26 as the main product together with thiazete dioxides 27 and pyrazoles 28. 

Dioxabicyclo[2.2.1]heptane naturally assumed the role of the principal target molecule. It represented a considerable synthetic challenge, for not only is it a strained bicyclic molecule containing the weak and labile 0—0 bond, but it is also a di(secondary-alkyl) peroxide which is the most difficult type to make by classical procedures 12). New synthetic methods of exceptional mildness were clearly needed to solve this problem. In the course of the development of such techniques and from a desire to establish their scope, a variety of saturated bicyclic peroxides have been obtained in addition to 2,3-dioxabicyclo[2.2.1]heptane. The question of how substitution patterns and ring sizes affect the reactivity of bicyclic peroxides has further served to broaden interest in the subject. 

Of the substrates that have worked well, let us first illustrate the 7-alkylidene-2,3-dioxabicyclo[2.2.1]heptane system 10. It was known that fulvenes react with singlet oxygen at low temperatures to afford the corresponding endoperoxides however, attempts to isolate these labile compounds led to decomposition, although NMR identification was possible at —70 °C 19>. When reduction of the singlet oxygenates with diimide was performed at —50 °C, the bicyclic peroxides 10 were obtained in high yield (Eq. 7) 20). 

The bicyclic peroxide 11 was prepared via diimide reduction of the endoperoxide derived from spirocyclopentadiene (Eq. 8)21>. As before, at elevated temperature the labile endoperoxide rearranges into diepoxide and ketoepoxide,22) but diimide reduction at —78 °C allows trapping leading to the highly strained bicyclic peroxide 11. 

As the first isolable intermediate in the bioconversion of arachidonic acid into prostaglandins and thromboxanes (Eq. 3), PGG2 is a bicyclic peroxide of immense biological importance. It is difficult to obtain pure from natural sources and the presence of the 15-hydroperoxide group adds a further dimension of chemical lability to that associated with the 9,11-peroxide bridge. The chemical synthesis of PGG2 is thus a landmark in prostaglandin chemistry. It also represents a pinnacle of success for the silver-salt route to bicyclic peroxides. 

Similarly, the very labile keto-peroxide 15 also affords succinaldehyde with chemiluminescence on decarbonylation 20). Sufficient chemical energy is stored in these bicyclic peroxides to generate electronically excited products 68). 

The equilibrium interconversion between an ethylene phosphite and a bicyclic spirophosphorane is shown to proceed by the insertion of the phosphite into the labile O-H bond of the hydroxyethyl ester. The mechanism is similar to the insertion of carbenes or nitrenes. Energy relationships of reaction intermediates were studied by MO RHF, MP2(full), MP4SDTQ, and DFT calculations. In most cases, they predicted that hydroxyethyl ethylene phosphates were more stable than the strained spirophosphoranes, which is not supported by the experimental evidence. The best correspondence to experimental data was obtained by DFT calculations with Perdew-Wang correlation functions <2003JST35>. 

The 1,3-dipolar cycloaddition of diazoalkanes 276 and nitrile oxides 279 to isothiazole dioxides 275 provides an easy entry into fused bicyclic isothiazole systems 277 and 280, respectively <06JHC1045>. The adducts from 4-bromoisothiazole (R1 = Br) are labile and undergo spontaneous debromination to form the aromatic bicyclic pyrazolo-isothiazoles 278... 

The double )5-scission pathway becomes dominant in bicyclic systems (Equations (7)-(9) and Scheme 13). Thus, cyclopentene ozonide (69) gives cyclopropane (Equation (7)) <68TL329l>. Photolysis of the ozonide derived from 1,4-benzodioxins (70) provides a method for the preparation of labile o-benzoquinones (71) (Scheme 13) <87JOC56l6>. Photolysis can also provide a route to unstable compounds and transient species such as the aziridine-2,3-dione (72) (Equation (8)), identified at 77 K using infrared spectroscopy <80JA6902>. Relatively unstable azacarbapenems (73) have been prepared by photolysis of tricyclic compounds containing a cyclobutene ozonide (Equation (9)). On silica, the 1,2,4-trithiolane (74) underwent photo-equilibration (Equation (10)) with the 1,3-dithetane (75) and sulfur. 

Regitz and co-workers (143) found that 2,3,4-tri-tert-butylazete reacts with isomiinchnones to give relatively labile cycloadducts. This group (153) has employed the cycloaddition of isomiinchnones 256 with phosphaalkynes 257 to prepare 1,3-oxaphospholes 258 (Scheme 10.35). This sequence is clearly the method of choice for the synthesis of the relatively little investigated 1,3-oxaphosp-holes. The presumed bicyclic intermediates could not be detected by NMR. 

Valence tautomerism of azepines and azabicyclo[3.2.0]heptadienes has been discussed in Section 5.16.3.2.1. In most cases the process is reversible and the azepine can be regenerated by gentle thermolysis of the bicycle. Sano and coworkers have capitalized on this thermal lability of azabicycloheptadienes to synthesize several azatropone and azatropolone derivatives (see Section 5.16.3.1.2), by ring expanding the 2,3-dioxopyrrole [2 + 2] cycloadducts, e.g. (251), as illustrated in Scheme 31 (81H(16)363). 

Most of the highly unsaturated monocyclic eight-membered heterocycles contain one or two nitrogen atoms and have been obtained by bond reorganization processes from strained bicyclic or polycyclic precursors. Although several of the less substituted compounds without stabilizing substituents are highly labile substances, 1,4-dihydro-1,4-diazocines qualify as dihetera[8]annulenes and display distinct aromatic properties. 

Halogen atoms at position 3 in tetrahydrothiins are labilized toward nucleophiles by the sulfur atom, by the formation of a bicyclic episulfonium salt as observed in the chemistry... 

---