Azetidine fused

The most informative feature of the IR spectra of azetidin-2-ones is generally the /3-lactam carbonyl absorption, the frequency of which is affected by substitution and by fusion of the ring (c/. Table 3). Thus, IR spectra of simple monocyclic /3-lactams generally have absorption maxima in the region 1730-1760 cm while the fused 2- and 3-cephem systems (60) and (61) show IR maxima in the regions 1772-1784 and 1782-1792 cm S respectively (b-72MI50900 p. 318). 

It is often necessary to prepare /3-lactams with particular substituents at N-1, C-3 and C-4, e.g. in the preparation of fused /3-lactams from monocyclic precursors. For reasons of space it is not possible to give an exhaustive list of the variously substituted /3-lactams available however, Table 4 summarizes the most general routes to /3-lactams bearing particular substituents at C-3 and C-4. -Substitution of azetidin-2-ones has already been dealt with cf. Section 5.09.3.2.3). N-Unsubstituted /3-lactams and protected 3-amino-/3-lactams are particularly important synthetic intermediates and methods of preparing these are discussed below. 

Azete, trisdimethylamino-isolation, 7, 278 Azetes, 7, 237-284, 278-284 benzo fused, 7, 278 benzodiazepine fused applications, 7, 284 fused ring, 7, 341-362 structure, 7, 360 2,3-naphtho fusion, 7, 278 reactivity, 7, 279 structure, 7, 278 synthesis, 7, 282-283 Azetidine, acylring expansion, 7, 241 synthesis, 7, 246 Azetidine, 3-acyl-irradiation, 7, 239 synthesis, 7, 246 Azetidine, N-acyl-synthesis, 7, 245 Azetidine, alkyl-synthesis, 7, 246 Azetidine, 3-alkylthio-synthesis, 7, 246 Azetidine, 3-amino-synthesis, 7, 246 Azetidine, N-amino-oxidation, 7, 241 synthesis, 7, 246 Azetidine, aryl-synthesis, 7, 246... 

Azetidin-2-one, l-benzyl-3,3,4-triphenyl-, 7, 249 Azetidin-2-one, l-(2-bromophenyl)-X-ray crystallography, 7, 247 Azetidin-2-one, 3-carboxy-synthesis, 7, 262 Azetidin-2-one, 3-halo-synthesis, 7, 77 ring contraction, 7, 81-82 Azetidin-2-one, 4-imino-IR spectroscopy, 7, 248 Azetidin-2-one, 1-phenyl-irradiation, 7, 255 Azetidin-2-one, 4-phenyl-reductive ring cleavage, 7, 252 Azetidin-2-one, 4-thio-IR spectroscopy, 7, 248 Azetidinones bicyclic, 7, 348-356 C NMR, 7, 348 H NMR, 7, 348 reactivity, 7, 356-358 spectroscopy, 7, 357 structure, 7, 349 synthesis, 7, 358-359 fused ring... 

The stereoselective synthesis of classical trinems (fused tricyclic systems having the azetidin-2-one nucleus fused through the N-C4 bond) <98MI347> and the chemistry of non-classical polycyclic P-lactams have been reviewed <00T5743>. 

Other Fused-ring Azetidines, Azetines and Azetes... 

The literature on fused-ring azetidines and azetidinones has virtually exploded in the last 15 years. A major factor in the expansion of research in this area has been the discovery... 

One report of the photochemical decomposition of a fused-ring azetidine (19) utilized photoaromatization to produce 2-azetines (20) (77CC806) (see Section 5.09.4.3.3). 

The primary mode of electrophilic attack on the azetidine of fused-ring derivatives is acid-catalyzed opening of the bridging bond. For example, l-azabicyclo[2.2.0]hexane (4) gives 4-chloropiperidine (21) on treatment with hydrogen chloride (64HCA2145). 

Fused-ring azetidines also are susceptible to nucleophilic attack, primarily at the bridging bond. Attack on bicyclohexane (4) by hydroxide or ethoxide gives the corresponding 4-substituted piperidine (64HCA2145). 

Examples of the synthesis of fused-ring azetidines by ring closure onto a preformed azetidine are uncommon, in contrast to approaches used for the preparation of fused ring azetidinones (see Sections 5.12.3, 5.11.4.4 and 5.10.4.3). The l,3-diazabicyclo[3.2.0]hep-tane derivative (48) was prepared (72JOC516) by cyclization with DCC of the carbamoyl-azetidine followed by thermal rearrangement of the intermediate thiazolidinone (Scheme 6). 

Table 1 Bicyclic Azetidines having a Carbon-containing Fused Ring Ring system Systematic name Substituents Yield (%) Ref.

Table 2 Bicyclic Azetidines containing One Heteroatom in the Fused Ring...

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