Isomerism detection

In the course of investigating conformational alterations in bovine serum albumin, Leonard and Foster (1961a) have closely analyzed changes in rotatory dispersion that are not paralleled by the specific rotation. As the pH is lowered, bovine serum albumin undergoes an isomerization detectable by two different electrophoretic components before it expands at low pH. 

Equilibration of aziridines via azomethine ylides has been reported for a variety of structures (67JA1753). Most aziridines equilibrated by this method show greater cis stability. An energy barrier has been detected between the two isomeric azomethine ylides (69AG(E)602>. 

BFO reacted readily with 1,3-diketones to give 2,3-disubstituted quinoxaline 1,4-dioxides. In the case of unsymmetrical 1,3-diketones, mixtures of isomeric quinoxaline dioxides were obtained, and the ratio of isomers was influenced by the steric bulk of the carbonyl substituent. When BFO 1 was combined with 1,3-diketone compounds 18 in the presence of triethylamine, the isomeric quinoxaline 1,4-dioxides 19 and 20 were obtained. When R = Me, 19 was the only product observed. As the steric bulk of R increased, increasing amounts of isomer 20 were observed. When R = tBu, 20 was the only product detected in the reaction. 

Whereas only one dehydrobenzene, benzyne, has been detected, two pyridynes are possible. Thus, the scheme we can write ab initio for the action of a nucleophile on the isomeric monosubstituted derivatives of pyridine involving 2,3- (26) and/or 3,4-pyridyne (31) is more complicated than that for the analogous reaction of the corresponding benzene derivative. The validity of this scheme can be checked using data available in the hterature on reactions of halogenopyridines with potassium amide and hthium piperidide involving pyridynes. 

Prinzbach and Limbach have studied the valence isomerism between N-substituted azepines 14b and benzeneimines 14c (76CB3505) although 14b is much more stable (actually it is the only form detected by NMR), the compound could react, depending on R, as 14c with diazomethane. Later, Prinzbach et al. reported the study of the equilibrium 14b (90% )/14c (10%) in the case of R = p-tosyl [the compound has the following C-substituents 3,6-dichloro-4,5-di(methoxycarbonyl)] in the solid state (X-ray) only 14b is present [86CB616],... 

When N,A/ -dimethyl-Af,N -diphenyl-p-phenylenediamine (231) underwent irradiation in die presence of oxygen, a remarkably regioselective reaction was observed, from which the /V,A/ -dimediylindolo[2,3-f ]carbazole (190) was obtained, without coformation of die other possible isomeric product, indolo[3,2-/)]carbazole (4). The expected intermediate 232, where only one ring closure had taken place, could not be detected. The authors attributed this fact to a two-photon autosensitization mechanism in which die conversion of 231 into 190 is sensitized by 232, permitting accumulation of 232 only in extremely small concentrations (83JA6268). 

Katritzky and co-workers studied the mechanism of this reaction in detail. His work involved a NMR study of 16 reactions of methyl-, phenyl-, 1,2-dimethyl-, and l-methyl-2-phenylhydrazine with /3-keto esters. In many cases starting materials, intermediates, and products were detected simultaneously. Most reactions proceed by nucleophilic addition of the less hindered hydrazine nitrogen atom to the keto carbon of the keto ester. For example, the pathway given in Scheme 3 for the reaction of methyl 3-oxobutanoate 9 with methyl- or phenyUiydrazine 2 (R = Me or Ph) was found to be dominant. The initially formed addition product 10 dehydrates to hydrazone 11, which then isomerizes to hydrazone 12. Intermediate 12 then cyclizes to pyrazol-3-one 13, which tautomerizes to the kinetically more stable pyrazol-3-otie 14 [87JCS(P2)969]. 

Arylsulfenyl azides in this reaction mainly give the product of the triazole ring opening 380, which is isomeric to the expected triazole 381 detected only in negligible quantities (72S571). 

In 1956 it was found that when pyridine is refluxed with a modified Raney-nickel catalyst, 2,2 -bipyridine (1) is formed in satisfactory yield. The isomeric bipyridines could not be detected, and the product was readily purified. Similar heterocyclic biaryls have been formed in the same way from substituted pyridines and from some related compounds, the yield being dependent on the nature of the compound. The reaction has become the method of choice for the preparation of 2,2 -bipyridine, and it is now used on an industrial scale. Bipyridyls are of particular importance as chelating agents. 

In the biphasic batch reaction the best reaction conditions were found for the system [EMIM][(CF3S02)2N]/compressed CO2. It was found that increasing the partial pressure of ethylene and decreasing the temperature helped to suppress the concurrent side reactions (isomerization and oligomerization), 58 % conversion of styrene (styrene/Ni = 1000/1) being achieved after 1 h under 40 bar of ethylene at 0 °C with 3-phenyl-1-butene being detected as the only product and with a 71 % ee of the R isomer. 

The X-ray crystal structure of rapamycin reveals the constitution of the major isomer, compound 1, although in solution at least four isomers are detectable. The most abundant isomers are 1 (major) and the isomeric seven-membered hemiketal (mixture of stereoisomers). For the purposes of this chapter, we will restrict ourselves to structure 1. 

Subsequently, it was shown that ring expansion of these bicyclic systems is followed by a series of proton shifts involving the isomeric 2- and 5-methyleneazepines. The former were detected spectroscopically ( H NMR) whereas, in some cases, the latter were isolated.127 For example, 4,6-dimethyl-2-methylene-3-phenyl-3-azabicyclo[4.1,0]hept-4-ene-l, 5-dicarbonitrile (28), on treatment with hydrochloric acid in chloroform, yields the 4-methyleneazepine 29, which on prolonged heating with acid is converted into the 1//-azepine 30. 

Depending upon the substitution pattern, a thermal valence isomerization of 1,4-dioxocins 4 to the tricyclic jyn-benzene dioxides (xyn-3,8-dioxatricyclo[5.1,0.02-4]oct-5-enes) 3 can be detected. On the other hand, the valence isomerization of sin-benzene dioxides (anti-benzene dioxides do not undergo such rearrangements) provides a general approach to 1,4-dioxocins 4. 

In an attempt to prepare the parent system via the valence isomerization of the. ryn-benzene-bisepisulfide 2, which in turn was generated from the syw-benzenebisepoxide 3 via diol 4, no valence isomerization to 1,4-dithiocin (1) was detected.3 The bisepisulfide 2 is a thermally rather unstable compound and decomposes in solution even at 20 C, leading to benzene and sulfur as the only isolated products. 

Most of the subsequent work on this reagent was concerned with the formation of aryl radicals (see review by Cadogan, 1971). However, 2-terf-butyl-A-nitrosoacet-anilide was found to decompose in benzene to give, instead of 2-tert-butylbiphenyl, as expected for a substitution of benzene by a 2-tert-butylphenyl radical, a mixture of isomeric tert-butylphenyl acetates. A careful reexamination (Cadogan and Hib-bert, 1964) suggested that the ratio of 2- and 3-tert-butylphenyl acetates was consistent with the involvement of 2-tert-butylbenzyne, i.e., the product of an ionic dediazoniation, as an intermediate. This was later confirmed by trapping experiments designed to detect aryne intermediates. 

The structure of the intermediate obtained from 3-phenyl-5-amino-l,2,4-thiadi-azole (Goerdeler and Deselaers, 1958) was elucidated by UV- and IR-spectroscopy. The results are consistent with the nitrosoamine structure 3.18. Its UV spectrum (Fig. 3.4) is very similar to that of the A-methyl-TV-nitroso compound 3.19, but different from that of the isomeric compound 3.20 with a methyl group in the 4-position (Goerdeler and Deselaers, 1958). The spectrum of this 4-methyl derivative is expected to be similar to that of the nitrosoamine structure 3.21, which is obviously not present, at least not in detectable tautomeric equilibrium concentration. 

Parallel and reversible reactions. The isomerization of allyl phenyl sulfide is a degenerate rearrangement made detectable by isotopic labeling of one end of the allyl group, permitting kinetic monitoring by NMR techniques.12... 

In contrast to the allylic sulfenates mentioned so far, cinnamyl trichloromethanesulfenate (9), prepared by the usual method, can be isolated and is relatively stable. Furthermore, its rearrangement to cinnamyl trichloromethyl sulfoxide (i.e., without allylic isomerization, equation 7), proceeds at a relatively slow rate (in CC14 at 80.0 °C, k = 3.90 x 10 5s 1). This result also contrasts with the observation mentioned earlier that cinnamyl arenesulfinate rearranges to a-phenylallyl aryl sulfone33,34. Similar behavior has been detected for y, y-dimethylallyl ester 11 which undergoes thermal isomerization to sulfoxide 12 (equation 8)36-38. 

Recently, the detection of UV-transparent alkanemonosulfonates without ion pairing is made feasible by a light-scattering detector (LSD) [32]. The optimized selectivity for the separation of alkanemonosulfonates by chain length using LSD is shown in Fig. 15. The separation of the isomeric tetradecanemonosulfonates is exemplified in Fig. 16. 

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