Stereoelectronic control

The high regioselectivity ( stereoelectronic control ) in the ring cleavage by chlorination of sulfur was anticipated. It had been found before that in corresponding bicyclic systems such as in the scheme below oxidation of the sulfur atom always led to the undesired cleavage of the S—Cg bond. This was rationalized through the observation on molecular models that... 

J.E. Baldwin (1976 B) also introduced a set of rules for closure reactions of 3- to 7-membered rings which are derived from similar arguments about stereoelectronic control . The specific rules are clearly explained in the original paper and need not be repeated here since their utility seems to be restricted to some specialized cases. The assumed... 

Stereoelectronic control also plays a role in mechanistic stereoselectivity. One such case is the very fundamental 8 2 process which proceeds rigorously with inversion of configuration at carbon. Because of that intrinsic and predictable stereoselectivity, the C-C disconnective Sn2 displacement transform is very important even though it does not directly reduce the number of stereocenters, e.g. 153 => 154. 

Karady et al. (72) report that the alkylation of the pyrrolidine enamine of 4-alkycyclohexanone was found to be subject to stereoelectronic control the product of hydrolysis under nonequilibrating conditions led largely to the tra i-2,4-dialkylcyclohexanone. 

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. 

With the radical 29, even though loss of an equatorial hydrogen should be sterically less hindered and is favored thermodynamically (by relief of 1,3 interactions of the axial methyl), there is an 8-fold preference for loss of the axial hydrogen (at 100 ( i. The selectivity observed in the disproportionation of this and other substituted cyclohexyl radicals led Beckwith18 to propose that disproportionation is subject to stereoelectronic control which results in preferential breaking of the C-H bond which has best overlap with the orbital bearing the unpaired spin. 

Mehta G., Uma R. Stereoelectronic Control in Diels-Alder Reaction of Dissymmetric 1,3-Dienes Acc. Chem. Res. 2000 33 278-286... 

C X bond, but not from B because only the has such an orbital. If the intermediate is in conformation B, the OR may leave (if X has a lone-pair orbital in the proper position) rather than X. This factor is called stereoelectwnic control Of course, there is free rotation in acyclic intermediates, and many conformations are possible, but some are preferred, and cleavage reactions may take place faster than rotation, so stereoelectronic control can be a factor in some situations. Much evidence has been presented for this concept. More generally, the term stereoelectronic effects refers to any case in which orbital position requirements affect the course of a reaction. The backside attack in the Sn2 mechanism is an example of a stereoelectronic effect. 

The hydrolysis of acetals and ortho esters is governed hy the stereoelectronic control factor previously discussed (see A and B on p. 427) though the effect can generally be seen only in systems where conformational mobility is limited, especially in cyclic systems. There is evidence for synplanar stereoselection in the... 

The cis product must be formed through a TS with a twistlike conformation to adhere to the requirements of stereoelectronic control. The fact that this pathway is not disfavored is consistent with other evidence that the TS in enolate alkylations occurs early and reflects primarily the structural features of the reactant, not the product. A late TS would disfavor the formation of the cis isomer because of the strain associated with the nonchair conformation of the product. 

The stereochemistry of this reaction in cyclic systems is in accord with expectations for stereoelectronic control. The allylic group approaches from a trajectory that is appropriate for interaction with the LUMO of the conjugated system.131... 

An interesting observation was made when o-aminophenol (2-411) was employed in the reaction with carbethoxypiperidone 2-410 and acrolein (Scheme 2.98). In this case, the spirocydic scaffold 2-412 was exclusively formed in 67% yield. This result can be explained by invoking a stereoelectronic control due to the presence of the aromatic ring which prevents the formation of the corresponding fused tetracyclic isomer. Moreover, both reactive sites can simultaneously be functionalized using 2-amino-1,3-propanediol (2-413) as partner in the multicomponent reaction. This leads to the formation of three new cycles... 

Nuclear motion, the principle of least, and the theory of stereoelectronic control, 24, 113 Nucleophiles, partitioning of carbocations between addition and deprotonation. 35, 67 Nucleophilic aromatic photosubstitution, 11,225 Nucleophilic catalysis of ester hydrolysis and related reactions, 5,237 Nucleophilic displacement reactions, gas-phase, 21, 197... 

Stereoelectronic control, the principle of least nuclear motion and the theory of, 24,113... 

Scheme 2-5 is one of such examples in which stereoelectronic control has to be taken into account in diastereoselective alkylation of substituted cyclohexanone enolates.12... 

Another interesting approach was developed by Ikegami and coworkers, who used an anomeric orthoester as the key intermediate (Scheme 7.14).59 Formation of orthoester 16 from lactone was effected by TMSOTf and TMSOMe. Subsequent Lewis acid mediated reduction afforded p-mannoside in high selectivity, presumably because of the stereoelectronically controlled hydride delivery from the a face. 

The first indication that this relationship can be a very simple one arose as part of an investigation of stereoelectronic effects in acetal hydrolysis. According to Deslongchamps (1983) theory of stereoelectronic control (see also Sinnott, 1988), the orientation of lone-pair electrons can control reactivity in appropriate systems. In its original form the theory suggested... 

The theory was tested in simple tetrahydropyranyl acetal systems, which exist in the axial conformation [92], but can be constrained to adopt the equatorial conformation [93] by building in appropriate structural features. It was found, for example, that the equatorial isomers of the oxadecalin acetals [94] are actually more reactive than the axial compounds [95], although only the latter have a lone pair on the donor ring oxygen antiperiplanar to the C-OAr bond (Kirby, 1984, 1987). This and other similar observations do not disprove the theory of stereoelectronic control because any stereoelectronic barrier can be got round if there is sufficient conformational flexibility. In other words, these are Curtin-Hammett systems, with free energy barriers between conformations much smaller than... 

Fig. 3.6. Stereoelectronic control of the cleavage of the tetrahedral intermediate during hydrolysis of a peptide bond by a serine hydrolase. The thin lines represent the reactive groups of the enzyme (serine, imidazole ring of histidine) the thick lines represent the tetrahedral intermediate of the transition state. The full circles are O-atoms open circles are N-atoms. The dotted lines represent H-bonds the thick double arrow indicates an unfavorable dipole-dipole interaction [21]. A (R)-configured N-center B (S)-configured N-center.

P. Deslongchamps, Stereoelectronic Control in the Cleavage of Tetrahedral Intermediates in the Hydrolysis of Esters and Amides , Tetrahedron 1977, 31, 2463 - 2490 P. Deslongchamps, Stereoelectronic Effects in Organic Chemistry , Pergamon Press, Oxford, 1983. 

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