Anomeric effect orientations

Anomeric effect (Section 25 8) The preference for an elec tronegative substituent especially a hydroxyl group to oc cupy an axial orientation when bonded to the anomeric carbon m the pyranose form of a carbohydrate Anti (Section 3 1) Term describing relative position of two substituents on adjacent atoms when the angle between their bonds is on the order of 180° Atoms X and Y m the structure shown are anti to each other... 

An electronegative substituent adjacent to a ring oxygen atom also shows a preference for an axial orientation. This is known as the anomeric effect , and is particularly significant to the conformations of carbohydrates (B-71MI20100, B-83MI20100). 

The magnitude of the anomeric effect depends on the nature of the substituent and decreases with increasing dielectric constant of the medium. The effect of the substituent can be seen by comparing the related 2-chloro- and 2-methoxy-substituted tetrahydropy-rans in entries 2 apd 3. The 2-chloro compound exhibits a significantly greater preference for the axial orientation than the 2-methoxy compound. Entry 3 also provides data relative to the effect of solvent polarity it is observed that the equilibrium constant is larger in carbon tetrachloride (e = 2.2) than in acetonitrile (e = 37.5). 

Compounds in which conformational, rather than configurational, equilibria are influenced by the anomeric effect are depicted in entries 4—6. Single-crystal X-ray dilfiaction studies have unambiguously established that all the chlorine atoms of trans, cis, ira j-2,3,5,6-tetrachloro-l,4-dioxane occupy axial sites in the crystal. Each chlorine in die molecule is bonded to an anomeric carbon and is subject to the anomeric effect. Equally striking is the observation that all the substituents of the tri-0-acetyl-/ -D-xylopyranosyl chloride shown in entry 5 are in the axial orientation in solution. Here, no special crystal packing forces can be invoked to rationalize the preferred conformation. The anomeric effect of a single chlorine is sufficient to drive the equilibrium in favor of the conformation that puts the three acetoxy groups in axial positions. 

Anomeric effect (Section 25.8) The preference for an electronegative substituent, especially a hydroxyl group, to occupy an axial orientation when bonded to the anomeric carbon in the pyranose form of a carbohydrate. 

Polymerization of 4-bromo-6,8-dioxabicyclo[3.2.1 ]octane 2 7 in dichloromethane solution at —78 °C with phosphorus pentafluoride as initiator gave a 60% yield of polymer having an inherent viscosity of 0.10 dl/g1. Although it is not described explicitly, the monomer used seems to be a mixture of the stereoisomers, 7 7a and 17b, in which the bromine atom is oriented trans and cis, respectively, to the five-membered ring of the bicyclic structure. Recently, the present authors found that pure 17b was very reluctant to polymerize under similar conditions. This is understandable in terms of a smaller enthalpy change from 17b to its polymer compared with that for 17a. In the monomeric states, 17b is less strained than 17a on account of the equatorial orientation of the bromine atom in the former, whereas in the polymeric states, the polymer from 17b is energetically less stable than that from 17a, because the former takes a conformation in which the bromine atom occupies the axial positioa Its flipped conformation would be even more unstable, because the stabilization by the anomeric effect is lost, in addition to the axial orientation of the methylene group. 

Second-row heteroatoms are known to show a substantial anomeric effect. There appears to be evidence for a reverse anomeric effect in 2-aminotetrahydro-pyrans. ° It has been called into question whether a reverse anomeric effect exists at all. ° In 94, the lone-pair electrons assume an axial conformation and there is an anomeric effect. In 95, however, the lone-pair electron orbitals are oriented gauche to both the axial and equatorial oc-CH bond and there is no anomeric effect. ... 

The conformational energies of monosubstituted oxanes studied to date are collected in Table I. In position 2, polar substituents (except NR2) prefer the axial position other substituents prefer the equatorial orientation, which is generally the case for groups in positions 3 and 4. Destabilizing 1,3-diaxial interactions cause the equatorial geometry to be usually favored in the 2-position, the anomeric effect stabilizes the axial conformation. A large purine moiety in position 2 of oxane, for example, prefers the equatorial position because the 1,3-diaxial interactions overcome the anomeric effect (75TL1553). 

Anomeric effects are cumulative, and can cause a potentially flexible ring to adjust to a more rigid conformation in order to maximize the overlap of suitable lone pair and a orbitals. It has been particularly instructive in explaining anomalous preferences for substituent orientations in tetrahydropyrans and related compounds. In the case of 2-methoxytetrahydropyran, for example, the axial conformer is three times more populated than the equatorial form (Scheme 1.2). 

The conformational equilibria of 3-hydroxytetrahydro-l,3-oxazines and their 3-acetyloxy derivatives were found to be shifted toward conformers in which the lone pair on the nitrogen displayed an equatorial orientation. The preferred conformation was stabilized by a strong anomeric effect. The H NMR spectrum of 82 indicated the presence of the major and minor conformers 82a and 82b in a ratio of ca. 4 1 in CDCI3 at 243 K <1999SAA1445,... 

In the corresponding nonfluorinated 4,5-dialkylsultines, the sultine ring adopts a half-chair conformation with the S=0 bond in a pseudoaxial orientation 50 (cf. Scheme 12) <20030EJ4911>. Again, hyperconjugative interactions within the sulfinyl moiety (the anomeric effect ) were found to be responsible for the conformational preference. 

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