Inherent chirality

In chemistry, inherent chirality is a property of molecules and complexes whose lack of symmetry does not originate from a classic stereogenic element, but is rather the consequence of the presence of a curvature in a structure that would be devoid of symmetry axes in any bidimensional representation.^[1]^[2]

The expression "inherently chiral" was first used by Boehmer to describe calixarenes with XXYZ or WXYZ substitution patterns at the upper rim, and has been later extended to fullerenes with a chiral molecular framework, like C76, C78, and C84, non symmetric uranyl-salophen complexes and the protonated Schiff base of 11-cis-retinal, the chromophore of rhodopsin.

References

↑ Dalla Cort A, Mandolini L, Pasquini C, Schiaffino L, (2004). ""Inherent chirality" and curvature". New Journal of Chemistry. 28 (10): 1198–1199. doi:10.1039/B404388J.
↑ Inherently chiral concave molecules—from synthesis to applications Agnieszka Szumna Chem. Soc. Rev., 2010, 39, 4274-4285 doi:10.1039/B919527K

Concepts in asymmetric synthesis

Chirality types	Chirality Stereocenter Planar chirality Chiral ligand Axial chirality Supramolecular chirality Inherent chirality

Chiral molecules	Stereoisomer Enantiomer Diastereomer meso compound racemic mixture Enantiomeric excess (ee) Diastereomeric excess (de)

Analysis	Optical rotation Chiral derivatizing agents NMR spectroscopy of stereoisomers Ultraviolet-visible spectroscopy of stereoisomers

Chiral resolution	Recrystallization Kinetic resolution Chiral column chromatography Diastereomeric recrystallization

Reactions	Asymmetric induction Chiral pool synthesis Chiral auxiliaries Asymmetric catalysis Organocatalysis Biocatalysis

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Inherent chirality

See also

References