Transannular

Transaminases Transamination Transannular peroxide Transcat process Transcobalamin II Transcortin... 

A number of chemiluminescent reactions may proceed through unstable dioxetane intermediates (12,43). For example, the classical chemiluminescent reactions of lophine [484-47-9] (18), lucigenin [2315-97-7] (20), and transannular peroxide decomposition. Classical chemiluminescence from lophine (18), where R = CgH, is derived from its reaction with oxygen in aqueous alkaline dimethyl sulfoxide or by reaction with hydrogen peroxide and a cooxidant such as sodium hypochlorite or potassium ferricyanide (44). The hydroperoxide (19) has been isolated and independentiy emits light in basic ethanol (45). 

Onium ions of small and large heterocyclics are usually produced by electrophilic attack on a heteroatom. In three- and four-membered rings nucleophilic attack on an adjacent carbon follows immediately, in most cases, and ring opening stabilizes the molecule. In large rings the onium ion behaves as would its acyclic analog, except where aromaticity or transannular reactions come into play (each with its electronic and steric pre-conditions). A wide diversity of reactions is observed. 

Anions of small heterocyclics are little known. They seem to be involved in some elimination reactions of oxetan-2-ones (80JA3620). Anions of large heterocycles often resemble their acyclic counterparts. However, anion formation can adjust the number of electrons in suitable systems so as to make a system conform to the Hiickel rule, and render it aromatic if flat geometry can be attained. Examples are found in Chapter 5.20. Anion formation in selected large heterocycles can also initiate transannular reactions (see also Section 5.02.7 below). 

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). 

Nucleophilic attack on ring atoms of large heterocycles is largely confined to saturated systems, saturated parts of partially unsaturated systems, and to carbonyl functions and the like. These reactions are not fundamentally different from those of corresponding acyclic systems, except for transannular reactions. 

S-Substituted thiiranium ions react with water and alcohols to give trans ring opening (Scheme 72). A report that oxygen nucleophiles attack sulfur as well as carbon has been shown to be incorrect (79ACR282). The intermediate thiiranium ion (57) in the presence of lithium perchlorate readily yields the carbenium ion which undergoes a transannular hydride... 

Azetidine, 7V-bromo-, 7, 240 Azetidine, AT-r-butyl- N NMR, 7, 11 Azetidine, AT-t-butyl-3-chloro-transannular nucleophilic attack, 7, 25 Azetidine, 3-chloro-isomerization, 7, 42 Azetidine, AT-chloro-, 7, 240 dehydrohalogenation, 7, 275 Azetidine, 7V-chloro-2-methyl-inversion, 7, 7 Azetidine, 3-halo-synthesis, 7, 246 Azetidine, AT-halo-synthesis, 7, 246 Azetidine, AT-hydroxy-synthesis, 7, 271 Azetidine, 2-imino-stability, 7, 256 Azetidine, 2-methoxy-synthesis, 7, 246 Azetidine, 2-methyl-circular dichroism, 7, 239 optical rotatory dispersion, 7, 239 Azetidine, AT-nitroso-deoxygenation, 7, 241 oxidation, 7, 240 synthesis, 7, 246 Azetidine, thioacyl-ring expansion, 7, 241 Azetidine-4-carboxylic acid, 2-oxo-oxidative decarboxylation, 7, 251 Azetidine-2-carboxylic acids absolute configuration, 7, 239 azetidin-2-ones from, 7, 263 synthesis, 7, 246... 

Azocin-2( 1H )-one, hexahydro- 1-phenyl-photochemical rearrangement, 7, 656 Azodn-2( 1H )-one, 1,2,7,8-tetrahydro-synthesis, 7, 662 Azocin-5-one IR spectra, 7, 16 transannular interactions, 7, 14 Azocin-5-one, l-(2,4-dimethylphenyl)-IR spectrum, 7, 657 Azocin-5-one, methoxycarbonyl-synthesis, 7, 657 Azocin-5-one, 1-methyl-IR spectrum, 7, 657 synthesis, 7, 657 Azodn-5-one, 1-p-tolyl-IR spectrum, 7, 657 Azocinones... 

Dibenzazepin-2-one, 5-aminomethyl-transannular nucleophilic attack, 7, 25 Dibenzazepin-2-ones tautomerism, 7, 503 Dibenz[6,dJazepinones phenanthridinones from, 2, 507 synthesis, 7, 530 Dibenz[6,d]azepinones, hydrosynthesis, 7, 536 Dibenz[6,eJazepinones synthesis, 7, 529, 530 5H-Dibenz[c,eJazepin-7-ones synthesis, 7, 529... 

No product derived from the transannular hydrogen abstraction is observed in the addition of bromotrichloromethane because bromine-atom abstraction is sufficiently rapid to prevent effective competition by the intramolecular hydrogen abstraction. 

By using various trapping reagents, it has been deduced that the transannular fragmentation is rapidly reversible. The cyclization of the fragmented radical C is less favorable, and it is trapped at rates which exceed that for recyclization under most circumstances. " Radicals derived from ethers and acetals by hydrogen abstraction are subject to fragmentation, with formation of a ketone or ester, respectively. 

The homolysis of tertiary hypochlorites for the production of oxy radicals is well known." The ease with which secondary hypohalites decompose to ketones has hampered the application of hypohalites for transannular reactions. However the tendency for the base-catalyzed heterolytic decomposition decreases as one passes from hypochlorites to hypobromites tohypoidites. Therefore the suitability of hypohalites for functionalization at the angular positions in steroids should increase in the same order. Since hypoidites (or iodine) do not react readily with ketones or carbon-carbon double bonds under neutral conditions hypoiodite reactions are more generally applicable than hypochlorite or hypobromite decompositions. 

Reaction of dibromocyclopropane (39) with hot quinoline gives 1-ethoxy-cyclohepta-l,3,5-triene (37) in 32% yield. Dihalocyclopropanes prepai ed from larger ring enol ethers do not react with hot pyridine but afford products with hot quinoline formed by transannular reactions. 

The bicyclic compound 8.17 also serves as a source of the five-membered ring 8.20 upon reduction with SbPhs. In contrast to the related S or Se systems, 8.11a and 8.11b, both Cl substituents are attached covalently to Te in 8.20. Reaction of 8.20 with an excess of AsFs in SO2 produces the eight-membered cyclic [Tc2S2N4] dication, which exhibits a Te-Te bond length of 2.88 A (cf. 2.70 A for a Te-Te single bond) and no transannular S S bonding J... 

The eight-membered rings 13.14 normally adopt boat conformations in the solid state with short S=N bond distances (1.51-1.52 A) that are typical of sulfur diimides. There are no transannular S S contacts. The sole exception is the antimony derivative BuSb(NSN)2Sb Bu, which is a planar eight-membered ring. 

Transannular Te N interactions have also been employed to stabilize compounds of the type 15.24 with terminal Te=E (E = S, Se) bonds.The Te=Se bond length in 15.24b is 2.44 A (cf. 2.54 A for a Te-S single bond) and d(Te N) = 2.62 A. Intramolecular coordination was also employed in the isolation of the first aryl-selenenium and -tellurenium cations 15.25a,b as [PEg] salts. 

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