Endocyclic reactions

Exocyclic reactions for aromatic carboxylic esters 174 Exocyclic reactions for aliphatic carboxylic esters 187 Endocyclic reactions for carboxylic esters 191 Carbon acid participation for carboxylic esters 195 Effective molarities 198 Ring size 199 Initiating nucleophile 200 Phosphate and sulphonate esters 200... 

Calculation of EM. The reference intramolecular reaction is nucleophilic attack by the anion of a carboxylic acid of pK, 3.15 on 2-phenoxy-l,3,2-dioxaphosphorinan-2-oxide. The rate constant for this reaction can be calculated as 7.67 x 10-10 dm3 mol 1 s-1 at 39° using the formula derived by Khan and Kirby (1970), and allows the direct calculation of the EM for the corresponding intramolecular reaction (COO-—P3—6n of A.5.5). The EM is assumed to be the same for the corresponding endocyclic reaction of the diphenyl ester anion (A.5.6), and has been shown not to differ significantly for endocyclic and exocyclic displacements (Bromilow etal., 1972)... 

If there are several nonequivalent endocyclic reaction centers in the aminoazole molecule, a question arises about regioselectivity of the condensation. Some difficulties in the determination of the isomer structures in these cases are illustrated, for example, in [165, 166] the product of the reaction of 2-aminoindole 162 with chalcone initially was assigned the structure of a pyrimidoindole 163 [165], but in a subsequent publication another arrangement of a-carboline 165 was proven (Scheme 3.48). 

This particular experimental fact allowed Kost [164] to speculate that carbon atoms were more preferable endocyclic reaction centers in reactions with unsaturated ketones than nitrogens. But applying this generalization to other ami-noazoles is not correct because of a dramatic difference of the nucleophilicity of the pyrrole-type nitrogen of indole and pyrimidine-type poly azoles. Indeed, the... 

Thus, if there are several nonequivalent endocyclic reaction centers in the aminoazole molecule (Scheme 3.50), then usually more nucleophilic ones participate in the interaction with the carbonyl compound (for example, N(2) in 3-amino-1,2,4-triazole or 5-aminopyrazole [158, 160]). 

There are several exceptions in the literature. One of them is a reaction of 3-amino-1,2,4-triazole 147 with l,4-diphenylbut-2-ene-l,4-dione (dibenzoylethy-lene) 170 [169] the first stage—alkylation of the amine with oc,(3-unsaturated ketone—is carried out with participation of all possible endocyclic reaction centers of the aminoazole (Scheme 3.51). 

The presence in the aminoazole molecule of nonequivalent endocyclic reaction centers can lead to several directions of the interaction as is observed in the case of multicomponent treatment of 5-aminopyrazoles 220-222 with dime-done 200 and aldehydes 201. In [189, 190, 191] it was shown that reactions of amines 220 and 221 with 1,3-diketone 200 and aromatic aldehydes in boiling ethanol or DMF yielded fused pyridines 225 and 226 when R is CH3 irrespective of the electronic nature of the substituent Ar (Scheme 3.61). 

There is little restriction on intramolecular exocyclic substitutions this is because N, Ca and L can readily become collinear. This does not hold, however, in the case of the endocyclic reaction. An important question is what is the smallest size of ring in the transition state for a concerted endocyclic substitution ... 

As a further application of the reaction, the conversion of an endocyclic double bond to an c.xo-methylene is possible[382]. The epoxidation of an cWo-alkene followed by diethylaluminum amide-mediated isomerization affords the allylic alcohol 583 with an exo double bond[383]. The hydroxy group is eliminated selectively by Pd-catalyzed hydrogenolysis after converting it into allylic formate, yielding the c.ro-methylene compound 584. The conversion of carvone (585) into l,3-disiloxy-4-methylenecyclohexane (586) is an example[382]. 

Imino-4-thiazolines are far more basic than their isomeric 2-aminothiazoles (see Table VI-1). They react with most electrophDic centers through the exocyclic nitrogen and are easily acylated (37, 477, 706) and sulfonated (652). The reaction of 2-imino-3-methyi-4-thiazoline (378) with a-chloracetic anhydride yields 379 (Scheme 217) (707). This exclusive reactivity of the exocyclic nitrogen precludes the direct synthesis of endocyclic quaternary salts of 2-imino-4-thiazolines. although this class of compounds was prepared recently according to Scheme 218 (493). 

The 1,4-isomer has been similarly generated from terephthalonitdle [623-26-7] (56) using a mixed Pd/Ru catalyst and ammonia plus solvent at 125 °C and 10 MPa (100 atm). It is also potentially derived (57) from terephthaUc acid [100-21-0] by amination of 1,4-cyclohexanedimethanol (30) [105-08-8], Endocyclization, however, competes favorably and results in formation of the secondary amine (31) 3-a2abicyclo[3.2.2]nonane [283-24-9] upon diol reaction with ammonia over dehydration and dehydrogenation catalysts (58) ... 

A systematic effort to correlate ease of ring closure with the stereoelectronic requirements of the transition state has been developed by Baldwin and co-workers. They classify ring closures with respect to three factors (a) ring size, (b) the hybridization of the carbon at the reaction site, and (c) the relationship (endocyclic or exocyclic) of the reacting bond to the forming ring. Certain types of ring closures are found to be favorable whereas others are unfavorable for stereoelectronic reasons. The relationships are summarized in Table 3.12. 

The dehydrobromination and dequaternization of l,l,3-trimethyl-2-bromomethylpyrrolidinium bromide (158) has been accomplished by dry distillation from potassium acetate (123). Since the product was isolated as the perchlorate salt, no conclusion can be drawn as to whether the original reaction mixture contained the exocyclic enamine (159) or the endocyclic enamine (160) ora mixture of both. 

Intramolecular cycloadditions of substrates with a cleavable tether have also been realized. Thus esters (37a-37d) provided the structurally interesting tricyclic lactones (38-43). It is interesting to note that the cyclododecenyl system (w = 7) proceeded at room temperature whereas all others required refluxing dioxane. In each case, the stereoselectivity with respect to the tether was excellent. As expected, the cyclohexenyl (n=l) and cycloheptenyl (n = 2) gave the syn adducts (38) and (39) almost exclusively. On the other hand, the cyclooctenyl (n = 3) and cyclododecenyl (n = 7) systems favored the anti adducts (41) and (42) instead. The formation of the endocyclic isomer (39, n=l) in the cyclohexenyl case can be explained by the isomerization of the initial adduct (44), which can not cyclize due to ring-strain, to the other 7t-allyl-Pd intermediate (45) which then ring-closes to (39) (Scheme 2.13) [20]. While the yields may not be spectacular, it is still remarkable that these reactions proceeded as well as they did since the substrates do contain another allylic ester moiety which is known to undergo ionization in the presence of the same palladium catalyst. 

Allylic bromination of pregnenolone acetate with dibromodi-methylhydantoin affords the 7-bromo compound (155) of undefined stereochemistry. Dehydrobromination by means of collidine followed by saponification affords the 5,7 endocyclic cis,cis-diene, 156. This compound contains the same chromophore as ergosterol, a steroid used as a vitamin D precursor. The latter displays a complex series of photochemical reactions among the known products is lumisterol, in which the stereochemistry at both C9 and Cio is inverted. Indeed, irradiation of 156 proceeds to give just such a product (158). This reaction can be rationalized by... 

Details of the hydrolytic process are somewhat more complicated because the acid-catalyzed hydrolysis proceeds via the initial protonation of an alkoxy oxygen followed by bond cleavage. Because the protonation can involve the exocyclic or endocyclic alkoxy group, two different sets of initial products are possible. However, in both cases the ultimate degradation products remain the same. These two possible reaction paths are shown on page 130. 

The IH of exocyclic alkenes allows the construction of bicyclic amines bearing one methyl group at the ring junction. Although long reaction times (2-7 days) are necessary (Eq. 4.22), amines are obtained in good yield. In contrast, endocyclic aminoalkenes are resistant to cyclization [134]. 

For a number of reactions of cyclic di- and triesters of phosphoric acid, there are exchange data which can be rationalized on the assumption of trigonal bipyrami-dal intermediates which readily interconvert by pseudorotation. This constitutes a strong argument that at least these cyclic esters react by an associative mechanism and is suggestive evidence that simple trialkyl phosphates also react by this mechanism. The pH dependence of exocyclic versus endocyclic cleavage of methyl ethylene phosphate is readily interpreted in terms of the effect of ionization of the intermediate on the pseudorotation of these pentacoordinate intermediates. ... 

There are numerous examples of intramolecular Heck reactions,151 such as in Entries 10 to 14. Entry 11 is part of a synthesis of the antitumor agent camptothecin. The Heck reaction gives an 11 1 endocyclic-exocyclic mixture. Entries 12-14 are also steps in syntheses of biologically active substances. Entry 12 is part of a synthesis of maritidine, an alkaloid with cytotoxic properties the reaction in Entry 13 is on a route to galanthamine, a potential candidate for treatment of Alzheimer s disease and Entry 14 is a key step in the synthesis of a potent antitumor agent isolated from a marine organism. 

The colored form of spironaphthopyran 32 absorbs at A,max of ca. 450 m,70 and the closed spiro form is colorless, which has no absorption band above 400nm. Bulky substituent group is especially important for photochromic sunglass. Introduction of the spiroadamantane or spirobi-cyclo[3.3.1]heptane into the 2-position of naphthopyran increases the resistance to photo-fatigue reaction, since endocyclic double bond induced by 1,7-hydrogen shift in the colored form cannot be formed in 2-adamantyl or 2-bicycloheptanyl group. 

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