Stereochemistry Explained

Stereochemistry, a subdiscipline of chemistry, involves the study of the relative spatial arrangement of atoms that form the structure of molecules and their manipulation.[1] The study of stereochemistry focuses on the relationships between stereoisomers, which by definition have the same molecular formula and sequence of bonded atoms (constitution), but differ in the geometric positioning of the atoms in space. For this reason, it is also known as 3D chemistry—the prefix "stereo-" means "three-dimensionality".[2]

Stereochemistry spans the entire spectrum of organic, inorganic, biological, physical and especially supramolecular chemistry. Stereochemistry includes methods for determining and describing these relationships; the effect on the physical or biological properties these relationships impart upon the molecules in question, and the manner in which these relationships influence the reactivity of the molecules in question (dynamic stereochemistry).

History

It was not until after the observations of certain molecular phenomena that stereochemical principles were developed. In 1815, Jean-Baptiste Biot's observation of optical activity marked the beginning of organic stereochemistry history. He observed that organic molecules were able to rotate the plane of polarized light in a solution or in the gaseous phase.[3] Despite Biot's discoveries, Louis Pasteur is commonly described as the first stereochemist, having observed in 1842 that salts of tartaric acid collected from wine production vessels could rotate the plane of polarized light, but that salts from other sources did not. This property, the only physical property in which the two types of tartrate salts differed, is due to optical isomerism. In 1874, Jacobus Henricus van 't Hoff and Joseph Le Bel explained optical activity in terms of the tetrahedral arrangement of the atoms bound to carbon. Kekulé used tetrahedral models earlier in 1862 but never published these; Emanuele Paternò probably knew of these but was the first to draw and discuss three dimensional structures, such as of 1,2-dibromoethane in the Giornale di Scienze Naturali ed Economiche in 1869.[4] The term "chiral" was introduced by Lord Kelvin in 1904. Arthur Robertson Cushny, Scottish Pharmacologist, in 1908, first offered a definite example of a bioactivity difference between enantiomers of a chiral molecule viz. (-)-Adrenaline is two times more potent than the (±)- form as a vasoconstrictor and in 1926 laid the foundation for chiral pharmacology/stereo-pharmacology[5] [6] (biological relations of optically isomeric substances). Later in 1966, the Cahn-Ingold-Prelog nomenclature or Sequence rule was devised to assign absolute configuration to stereogenic/chiral center (R- and S- notation) [7] and extended to be applied across olefinic bonds (E- and Z- notation).

Significance

Cahn–Ingold–Prelog priority rules are part of a system for describing a molecule's stereochemistry. They rank the atoms around a stereocenter in a standard way, allowing the relative position of these atoms in the molecule to be described unambiguously. A Fischer projection is a simplified way to depict the stereochemistry around a stereocenter.

Thalidomide example

Stereochemistry has important applications in the field of medicine, particularly pharmaceuticals. An often cited example of the importance of stereochemistry relates to the thalidomide disaster. Thalidomide is a pharmaceutical drug, first prepared in 1957 in Germany, prescribed for treating morning sickness in pregnant women. The drug was discovered to be teratogenic, causing serious genetic damage to early embryonic growth and development, leading to limb deformation in babies. Some of the several proposed mechanisms of teratogenicity involve a different biological function for the (R)- and the (S)-thalidomide enantiomers.[8] In the human body however, thalidomide undergoes racemization: even if only one of the two enantiomers is administered as a drug, the other enantiomer is produced as a result of metabolism.[9] Accordingly, it is incorrect to state that one stereoisomer is safe while the other is teratogenic.[10] Thalidomide is currently used for the treatment of other diseases, notably cancer and leprosy. Strict regulations and controls have been enabled to avoid its use by pregnant women and prevent developmental deformations. This disaster was a driving force behind requiring strict testing of drugs before making them available to the public.

Definitions

Many definitions that describe a specific conformer (IUPAC Gold Book) exist, developed by William Klyne and Vladimir Prelog, constituting their Klyne–Prelog system of nomenclature:

Torsional strain results from resistance to twisting about a bond.

Types

See also

Notes and References

  1. Ernest Eliel Basic Organic Stereochemistry,2001 ; Bernard Testa and John Caldwell Organic Stereochemistry: Guiding Principles and Biomedicinal Relevance 2014 ; Hua-Jie Zhu Organic Stereochemistry: Experimental and Computational Methods 2015 ; László Poppe, Mihály Nógrádi, József Nagy, Gábor Hornyánszky, Zoltán Boros Stereochemistry and Stereoselective Synthesis: An Introduction 2016
  2. Web site: the definition of stereo-. Dictionary.com. live. https://web.archive.org/web/20100609162256/http://dictionary.reference.com/browse/stereo-. 2010-06-09.
  3. Book: Nasipuri, D . Stereochemistry of Organic Compounds Principles and Applications . New Delhi: New Age International . 2021 . 978-93-89802-47-4 . 4th . 1.
  4. Paternò. Emanuele. 1869 . Intorno all'azione del percloruro di fosforo sul clorale. Giorn. Sci. Nat. Econ.. 5 . 117–122.
  5. Smith. Silas W.. 2009-05-04. Chiral Toxicology: It's the Same Thing…Only Different. Toxicological Sciences. 110. 1. 4–30. 10.1093/toxsci/kfp097 . 19414517. 1096-6080. free.
  6. Patočka. Jiří . Dvořák . Aleš. 2004-07-31. Biomedical aspects of chiral molecules. Journal of Applied Biomedicine. 2. 2. 95–100. 10.32725/jab.2004.011. free.
  7. Cahn. R. S.. Ingold. Christopher . Prelog. V.. April 1966. Specification of Molecular Chirality. Angewandte Chemie International Edition in English. 5. 4 . 385–415. 10.1002/anie.196603851 . 0570-0833.
  8. Stephens TD, Bunde CJ, Fillmore BJ . Mechanism of action in thalidomide teratogenesis. Biochemical Pharmacology. 59. 12. 1489–99. June 2000. 10799645. 10.1016/S0006-2952(99)00388-3.
  9. Clin. Pharmacokinet. . 2004 . 43 . 5 . 311–327 . Clinical pharmacokinetics of thalidomide . 15080764 . Teo SK, Colburn WA, Tracewell WG, Kook KA, Stirling DI, Jaworsky MS, Scheffler MA, Thomas SD, Laskin OL . 10.2165/00003088-200443050-00004 . 37728304 .
  10. Urban legends of chemistry . Francl, Michelle . Nature Chemistry . 2010 . 2 . 8 . 600–601 . 10.1038/nchem.750 . 20651711 . 2010NatCh...2..600F .
  11. Anslyn, Eric V. and Dougherty, Dennis A. Modern Physical Organic Chemistry. University Science (2005), 1083 pp.
  12. Toenjes . Sean T . Gustafson . Jeffrey L . February 2018 . Atropisomerism in medicinal chemistry: challenges and opportunities . Future Medicinal Chemistry . 10 . 4 . 409–422 . 10.4155/fmc-2017-0152 . 1756-8919 . 5967358 . 29380622.
  13. Web site: 2014-07-17 . 13.2: Cis-Trans Isomers (Geometric Isomers) . Chemistry LibreTexts . 2022-11-27.
  14. Book: Garrett . Reginald H. . Grisham . Charles M. . Biochemistry . 2005 . Thomson Brooks/Cole . 0-534-49033-6 . 3rd . Belmont, CA . 56058171.
  15. Caillet . Céline . Chauvelot-Moachon . Laurence . Montastruc . Jean-Louis . Bagheri . Haleh . French Association of Regional Pharmacovigilance Centers . November 2012 . Safety profile of enantiomers vs . racemic mixtures: it's the same?: Short report . British Journal of Clinical Pharmacology . en . 74 . 5 . 886–889 . 10.1111/j.1365-2125.2012.04262.x . 3495153 . 22404187.