Bromine reaction with heterocycles

From all the above calculations, one arrives at a conclusion that 1,2-dihydrodiazetes are simply constrained nonaromatic heterocycles that do not benefit from aromatic stabilization. Also, these compounds undergo facile Diels-Alder reactions or bromination reactions, with no tendency to regain the 7t-structure and are thus characteristic for typical nonaromatic compounds. 

Pyrimidine annulated heterocycles fused at positions 5 and 6 to uracil were synthesized via a three-step sequence starting from uracil 63 [20]. Firstly, the reaction with 3-bromocyclohexene gave the AT-allyl-vinyl core system 64 in 80% yield. Upon heating 64 in EtOH in the presence of HCl, aza-Claisen rearrangement gave rise to the C-cyclohexenyl uracil 65 in 38% yield. Final bromination ( 66) and dehydrogenation steps ( 67) allowed synthesis of the desired tricyclic fused uracil systems (Scheme 15). 

Notes Used for allylic and benzylic brominations (Wohl-Zieeler Reaction). With moist DMSO the reagent is useful for bromohydrin formation, providing trans addition of bromine and water. Can brominate alpha to carbonyl in carbonyl (carboxyl)-containing compounds. With DMF useful for aromatic bromination of activated aromatic rings, such as phenols, aromatic ethers, aniline derivatives and activated heterocyclic compounds. For similar chemistry, see also NBA, N-Bromoacetamide. 

Thiophene is far more reactive than benzene in electrophilic substitution reactions. Reaction with bromine in acetic acid has been calculated to be 1.76 x 109 times faster than with benzene (72IJS(C)(7)6l). This comparison should, of course, be treated with circumspection in view of the fact that the experimental conditions are not really comparable. Benzene in the absence of catalysts is scarcely attacked by bromine in acetic acid. More pertinent is the reactivity sequence for this bromination among five-membered aromatic heterocycles, the relative rates being in the order 1 (thiophene) and 120 (furan) or, for trifluoroacetylation, 1 (thiophene), 140 (furan), 5.3 xlO7 (pyrrole) (B-72MI31300, 72IJS(C)(7)6l). Among the five-membered heteroaromatics, thiophene is definitely the least reactive. 

The most efficient photosubstitution reaction, with many applications in synthesis, is the photobromination method developed by FERRIER s group [24]. The substitution of H-5 is regioselective and stereoselective for pentopyranosides [25], hexo-pyranosides [26], 1-6 anhydrosugars [27], uronic acids [24, 28] heterocyclic derivatives from deoxyinosones [29], nucleosides [30, 31], etc.. . using bromine or N-bromo-succinimide in carbon tetracloride under irradiation. 

Pashkevich and Khomutov [111] reported the synthesis of aziridines containing polyfluoroalkyl substituents on the aziridine cycle. In the case where RF is CF3, the only reaction product is bis(aziridinyl ketone) 103 (Scheme 1.28). The results also provide information about the reaction mechanism. As well as in [107], it is assumed that the reaction proceeds via the formation of a-bromo-ketones and /5-aminoketones 101 and 102 where the next step is the intramolecular bromine substitution and heterocyclization into quinoxaline 104. But in the case where RF is CF3, the formation of the aziridine cycle is followed by the interaction of the second amino group of the diamine with another molecule of the intermediate 102, leading to compound 103. 

The only known example of the tellurium by selenium exchange reaction in heterocycles 92 is a conversion of phenoxatellurine 92 (M = O) to phenoxaselenine 112 (M = O, M = Se) (28JCS511). A mixture of the product and unreacted 92 (M = O) cannot be separated by crystallization. To isolate pure phenoxaselenine, the reaction mixture was allowed to react with bromine and the resultant 10,10-dibromophenoxatellurine and 10,10-dibromophenoxaselenine were treated with acetone. Whereas the former compound is inert, the latter undergoes facile debromination, which thereby makes possible the separation of the highly acetone-soluble phenoxaselenine. Precisely this sequence of reactions was used in the first synthesis of phenoxaselenine. 

Although brominated derivatives of the five-membered heterocycles may be prepared by reactions of the co-ordinated ligands, these may then undergo further reactions with nucleophiles. As an example, the nucleophilic displacement of bromide from 8.15 by sulfide has been used to form new macrocyclic systems (Fig. 8-12). The palladium probably serves a dual function in this reaction. First, it organises the open-chain ligand such that the two reactive sites are held in proximity, so allowing the intramolecular formation of the sulfide and, second, it may activate the pyrrolic ring to nucleophilic displacement of bromide. 

The ketodiester 31 was made from 32 by bromination and elimination. Reaction with 30 gave first the heterocycle 40 that was dehydrated and aromatised in dry HC1. Oxidation of this methoxy-compound with Ce(IV) was quite easy and methoxatin was synthesised. 

The ease with which brominated heterocycles may be prepared regioselectively makes the use of these compounds as starting materials for the synthesis of regioselectively lithiated heterocycles extremely attractive. Organolithium derivatives of all the simple heterocycles at all possible positions of substitution have been made by this method.80 The scheme below illustrates some classical methods for forming 2-lithio-,81 3-lithio-,81 and 4-lithiopyridines,82 along with 4-lithioquinoline.83 rc-BuLi works well in these reactions, and indeed may be better than r-BuLi in reactions with electron deficient heterocycles, with which it tends to undergo addition reactions. 

Synthetic procedures are available for the preparation of fluoro (e.g., 2-lithio-l-methyl-5-octylpyrrole with fV-fluoro-iV-(phenylsulfonyl)benzenesulfonamide <2003JFC(124)159>), chloro, bromo, and iodo compounds from the corresponding lithio derivatives, for example, 2-iodobenzo[A]furan via lithiation of the heterocycle then reaction with iodine <2002JOC7048>. Perchloryl fluoride (FCIO3), A-chlorosuccinimide, bromine, and iodine are examples of reagents which can be used to introduce fluorine, chlorine, bromine, and iodine, respectively. 

Of lesser relevance to this discussion are halogenation methods involving the modification of the carbon skeleton (synthesis and degradation). The Hunsdiecker reaction, as applied to certain heterocyclic acids, has had limited application for the synthesis of halogen derivatives. The preparation of 3-bromo-4,6-dimethyl-2-pyridone from the silver salt of the respective 3-carboxylic acid by treatment with bromine in carbon tetrachloride is a rare example of success.13 The interaction of carbenes with heterocycles also has been employed infrequently, but recent advances in carbene generation may reactivate this approach.14 The Ciamician-Dennstedt ring expansion of pyrrole to / -halopyridines is a case in point18 [Eq. (4)] ... 

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