Trisubstituted isomers

The value of many chemical products, from pesticides to pharmaceuticals to high performance polymers, is based on unique properties of a particular isomer from which the product is ultimately derived. Eor example, trisubstituted aromatics may have as many as 10 possible geometric isomers whose ratio ia the mixture is determined by equiHbrium. Often the purity requirement for the desired product iacludes an upper limit on the content of one or more of the other isomers. This separation problem is a compHcated one, but one ia which adsorptive separation processes offer the greatest chances for success. 

The number of naphthalene derivatives is very large, since the number of positional isomers is large 2 for monosubstitution, 10 for disubstitution—same substituent, 14 for disubstitition—different substituents, 14 for trisubstitution—same substituent, 42 for trisubstitution—two different substituents, 84 for trisubstitution—three different substituents, and so on with multiplying complexity. 

The pyrrolidine enamine of 2-methylcyclohexanone (7) was in fact found to be quite inert toward further alkylation and was shown to consist only of the trisubstituted isomer (4) on the basis of the NMR spectral data. The... 

Amine Per cent trisubstituted isomer Per cent tetrasubstituted isomer Ref. 

The tetrasubstituted isomer of the morpholine enamine of 2-methyl-cyclohexanone (20) because cf the diminished electronic overlap should be expected to exhibit lower degree of enamine-type reactivity toward electrophilic agents than the trisubstituted isomer. This was demonstrated to be the case when the treatment of the enamine with dilute acetic acid at room temperature resulted in the completely selective hydrolysis of the trisubstituted isomer within 5 min. The tetrasubstituted isomer was rather slow to react and was 96% hydrolyzed after 22 hr (77). The slowness might also be due to the intermediacy of quaternary iminium ion 23, which suffers from a severe. 4< strain 7,7a) between the equatorial C-2 methyl group and the methylene group adjacent to the nitrogen atom, 23 being formed by the stereoelectronically controlled axial protonation of 20. 

That the methyl group in the less substituted isomer of the enamine (20) is axial was borne out by the work of Johnson et al. (18) in the total synthesis of the glutarimide antibiotic //-dehydrocycloheximide (24). The acylation of the morpholine enamine of 2,4-dimethylcyclohexanone (25) with 3-glutarimidylacetylchloride (26), followed by the hydrolysis of the intermediate product (27) with an acid buffer, led to the desired product in 35 % yield. The formation of the product in a rather low yield could most probably be ascribed to the relatively low enamine-type aetivity exhibited by the tetrasubstituted isomer, which fails to undergo the acylation reaction, and also because in trisubstituted isomer one of the CHj groups is axial. Since the methyl groups in the product are trans to each other, the allylic methyl group in the less substituted isomer of the enamine should then be in the axial orientation. 

Danishafsky and Feldman (21) have shown that the cyclization of the aminoketone (28) led to the internal enamine (29), which lacks the steric interaction of the type existent in the enamines of 2-alkycyclohexanones. In this case, the tetrasubstituted isomer was favored over the trisubstituted one by a factor of 4 1, which may be ascribed to the double bond being in the exo position in the latter case. 

Risaliti et al. (22), have shown that in the addition of the electrophilic olefins to the enamines of cyclohexanone, the formation of the less substituted enamine is favored when a bulky group is present at the electrophilic carbon atom. For instance, the reaction of (8-nitrostyrene with the morpholine enamine of cyclohexanone gave only the trisubstituted isomer (30) with the substituent in the axial orientation (23). The product on hydrolysis led to the ketone (31) to which erythro configuration was assigned on the grounds illustrated in Scheme 3 (24). 

It would be pertinent to point out (25,27) that the trisubstituted isomer of the enamine of 2-aIkylcyclohexanone reacts in a quantitative manner with ethyl azodicarboxylate to give the addition product (35). This reaction in Conjunction with NMR spectroscopy can thus be employed for the determination of the amount of the trisubstituted isomer. According to the authors, hydrolysis of 35 furnishes the corresponding cw-2,6-disubstituted cyclohexanone (36) this seems unlikely since it would involve the stereo-electronically unfavored equatorial protonation of the enamine. 

The formation of the less favored trisubstituted isomer (37) occurs by the usual intramolecular axial proton transfer from the 6 position, whereas that of the tetrasubstituted isomer (38) involves the intramolecular proton transfer of the stereoelectronically less favored equatorial proton either via a four-membered transition state (39) or a six-membered transition state (40). 

Reaction of the pyrrolidine enamine of cyclohexanone with phenyl vinyl sulfone afforded a 9 1 mixture of the tri- and tetrasubstituted isomers (2(5). The preference of the less substituted isomer in this case is in keeping with the greater overlap requirement between the n electrons of the double bond and the electron pair on the nitrogen atom, since the double bond exo to the five-membered ring is much more favored than the double bond exo to the six-membered ring. It is, however, hard to explain the formation of largely the trisubstituted isomer with the piperidine enamine of cyclohexanone, where both of the rings involved are six-membered. 

The reaction of morpholine enamine of cyclohexanone with 1 mole of phenyl isocyanate has been reported (30,31) to give the monoadduet (49), consisting largely of the trisubstituted isomer, and with 2 moles of phenyl isocyanate, the bis adduct (50). That the bis adduct is a dicarboxyanilide rather than a urea derivative (32) such as 51 was shown by its mild hydrolysis to the ketone (52). Reaction of the morpholine enamine of 2-methylcyclo-... 

A less obvious method for the preparation of 2,4-disubstituted furans involves th< treatment of epoxyketones like 81 with eatalytie p-toluenesulfonie aeid and their rearrangemen to furans (for example 82). Cormier developed this method, whieh presumably involves a 1,4 diketone intermediate, and works for a variety of epoxyketone derivatives to yield othe disubstituted furan isomers as well as 2,3,5-trisubstituted furans. ... 

Application of the Knorr pyrazole synthesis has also been demonstrated on solid support. ° To prepare trisubstituted pyrazoles, the diketone was linked to the solid support to make 57 using a linker with an amide bond. Alkylation of the diketone followed by condensation of the hydrazine with the resulting diketone gave the desired pyrazoles as mixtures of isomers. Subsequent cleavage of the amide bond linker then provided the pyrazole amides 59. ... 

Conversely, when A-alkyl tryptophan methyl esters were condensed with aldehydes, the trans diastereomers were observed as the major products." X-ray-crystal structures of 1,2,3-trisubstituted tetrahydro-P-carbolines revealed that the Cl substituent preferentially adopted a pseudo-axial position, forcing the C3 substituent into a pseudo-equatorial orientation to give the kinetically and thermodynamically preferred trans isomer." As the steric size of the Cl and N2 substituents increased, the selectivity for the trans isomer became greater. A-alkyl-L-tryptophan methyl ester 42 was condensed with various aliphatic aldehydes in the presence of trifluoroacetic acid to give predominantly the trans isomers. ... 

In an effort to make productive use of the undesired C-13 epimer, 100-/ , a process was developed to convert it into the desired isomer 100. To this end, reaction of the lactone enolate derived from 100-) with phenylselenenyl bromide produces an a-selenated lactone which can subsequently be converted to a,) -unsaturated lactone 148 through oxidative syn elimination (91 % overall yield). Interestingly, when 148 is treated sequentially with lithium bis(trimethylsilyl)amide and methanol, the double bond of the unsaturated lactone is shifted, the lactone ring is cleaved, and ) ,y-unsaturated methyl ester alcohol 149 is formed in 94% yield. In light of the constitution of compound 149, we were hopeful that a hydroxyl-directed hydrogenation52 of the trisubstituted double bond might proceed diastereoselectively in the desired direction In the event, however, hydrogenation of 149 in the presence of [Ir(COD)(py)P(Cy)3](PF6)53 produces an equimolar mixture of C-13 epimers in 80 % yield. Sequential methyl ester saponification and lactonization reactions then furnish a separable 1 1 mixture of lactones 100 and 100-) (72% overall yield from 149). 

In contrast to the spontaneous reaction, the catalyzed process seldom gives the 1,2,3-trisubstituted benzene isomer from an acetylene RC=CH. The chief product is usually the 1,2,4-isomer, with lesser amounts of the 1,3,15-isomer also generally obtained, but little if any of the 1,2,3-isomer. The mechanism of the catalyzed... 

Mixtures of the cis and irons isomers of 2,3,4-trisubstituted azetine 2, together with the... 

With trisubstitution by the same or different substituents, the three positional isomers shown above are possible. When the substituent groups are the same, the positional numbers are given followed by the suffix tri-. For example, if the three groups are chlorine, the first isomer above is named 1,2,3-trichlorobenzene. The compound above with different substituents is named as a derivative of the parent compound toluene (methylbenzene) where it is understood that the methyl group is in the 1-position. 

The jS-oxido-ylides synthesis of trisubstituted olefins has also been applied to the synthesis of farnesol (127). The phosphonium salt (123) with the aldehyde (124) and formaldehyde gave the hydroxy farnesol derivative (125) which was transformed into farnesol (127) and into (126), a position isomer of Cj juvenile hormone. 

It also explains the /Z selectivity of products at low conversions (kinetic ratio. Scheme 19). In the case of propene, a terminal olefin, E 2-butene is usually favoured (E/Z - 2.5 Scheme 19), while Z 3-heptene is transformed into 3-hexene and 4-octene with EjZ ratios of 0.75 and 0.6, respectively, which shows that in this case Z-olefins are favoured (Scheme 20). At full conversion, the thermodynamic equilibriums are reached to give the -olefins as the major isomers in both cases. For terminal olefins, the E olefin is the kinetic product because the favoured pathway involved intermediates in which the [ 1,2]-interactions are minimized, that is when both substituents (methyls) are least interacting. In the metathesis of Z-olefins, the metallacyclobutanes are trisubstituted, and Z-olefins are the kinetic products because they invoke reaction intermediates in which [1,2] and especially [1,3] interactions are minimized. 

Z-isomers of 2-pentenyloxy ethers show modest stereoselectivity, but the fi-ethers show no stereoselectivity.26 Trisubstituted allylic TBDPS ethers show good stereoselectivity.27... 

Vogtle et al. reported the first example of a photoswitching dendrimer [94] with six azobenzene moieties attached to a derivative of 1,3,5-trisubstituted benzene as the central core. Irradiation of the all (F)-isomer at 313 nm led to a photostationary equilibrium where most of the azobenzene units were switched to the (Z)-configuration. Conversely, irradiation of this species again at a lower energy frequency (436 nm) led to a second photostationary equilibrium where the (F)-form was dominant however, it was not proven as to how many azobenzene units isomerized after irradiation. 

Only a few results are available concerning competitive cyclopropanation of non-conjugated dienes. The case of 1,4-hexadiene72 (mixture of Z and E isomers) illustrates the reactivity difference between a monosubstituted and a 1,2-disubstituted double bond, whereas in limonene (24)47, a 1,1-disubstituted and a trisubstituted double bond compete for the carbenoid derived from ethyl diazoacetate. In both cases, the less substituted double bond reacts preferentially (Scheme 8). 

An interesting feature of the cyclization of y, -unsaturated alcohols is the marked effect on product isomer distribution by the nature of substituents remote from the double bond (cf. 42 and Scheme 59).98 Complete stereospecificity is observed for the phenyl derivative 42a in contrast to 42b and c, and the isomer ratio is reversed for 42d. The suggested mechanism98 is shown in Scheme 60 the trisubstituted alkene (45) is mainly converted into a pyran (46) rather than a tetrahydrofuran derivative (Scheme 61). 

Thermal isomerization of certain cis-l,3,4-trisubstituted azetidin-2-ones 76 provided the trans isomer in good yield . Bases caused the isomerization of cis-3-substituted-4-formylazetidin-2-ones and of sulfonic acid derivatives of 3-aminoazetidin-2-ones during the formation of a Schiff base <00T3985>. 4-Acyloxy-iV-o-azidobenzoyl-P-lactams underwent ring expansion to produce l,3-oxazin-6-ones 77 . 

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