Acyloin
{{Short description|Organic compounds of the form –C(O)CH(OH)–}}
{{Use dmy dates|date=June 2023}}
In organic chemistry, acyloins or α-hydroxy ketones{{GoldBookRef|title=acyloins|file=A00126}} are a class of organic compounds of the general form {{chem2|R\sC(O)CH(OH)\sR'}}, composed of a hydroxy group ({{chem2|\sOH}}) adjacent to a ketone group ({{chem2|>C\dO}}). The name acyloin is derived from the fact that they are formally derived from reductive coupling of carboxylic acyl groups ({{chem2|\sC(\dO)OH}}). They are one of the two main classes of hydroxy ketones, distinguished by the position of the hydroxy group relative to the ketone; in this form, the hydroxy is on the alpha carbon, explaining the secondary name of α-hydroxy ketone.
== Synthesis ==
Classic organic reactions exist for the synthesis of acyloins.
- The acyloin condensation is a reductive coupling of esters
- The benzoin condensation is condensation reaction between aldehydes catalyzed by a nucleophile
- Oxidation of carbonyls is possible with molecular oxygen but not selective
- Better alternative is oxidation of corresponding silyl enol ethers with mCPBA in the Rubottom oxidation
- MoOPH oxidation of carbonyls is a system with molybdenum peroxide, pyridine and hexamethylphosphoramide.
- A family of stereoselective syntheses oxidizes in situ enols with nitroso equivalents. In the simplest version, nitrosobenzene oxidizes a carbonyl to an α{{nbh}}hydroxylamine, with a proline organocatalyst for enantioselection.{{cite web|date=26 Jan 2004|first=Douglass F.|last=Taber|author-link=Taber's reagent|title=Catalytic Enantioselective Synthesis|series=Organic Chemistry Highlights|website=Organic Chemistry Portal|url=https://www.organic-chemistry.org/Highlights/2004/26January.shtm|access-date=7 June 2024}} In a more elaborate version, enolates can be oxidized by sulfonyloxaziridines.{{cite journal|title=Synthesis of α-hydroxycarbonyl compounds (acyloins): direct oxidation of enolates using 2-sulfonyloxaziridines|first1 =Franklin A. |last1=Davis|first2= Lal C. |last2=Vishwakarma |first3=Joanne G. |last3=Billmers |first4=John|last4= Finn |journal=J. Org. Chem.|year=1984|volume=49|issue=17|pages=3241–3243|doi=10.1021/jo00191a048}}{{cite journal|title=Asymmetric oxidation of ester and amide enolates using new (camphorylsulfonyl)oxaziridines|last1= Davis|first1= F. A.|last2= Haque|first2= M. S.|last3= Ulatowski|first3= T. G.|last4= Towson|first4= J. C. |journal=J. Org. Chem. |year=1986|volume=51|issue= 12|page=2402|doi=10.1021/jo00362a053}}
=Oxidation with Sulfonyloxaridines=
When sulfonyloxaziridines oxidize enol(ate)s, the latter reacts by nucleophilic displacement at the electron deficient oxygen of the oxaziridine ring.
:File:Enolate oxidation sulfonyloxazirines.png
This reaction type is extended to asymmetric synthesis by the use of chiral oxaziridines derived from camphor (camphorsulfonyl oxaziridine). Each isomer gives exclusive access to one of the two possible enantiomers. This modification is applied in the Holton taxol total synthesis.
:File:Camphorsulfonyl oxaziridine.png
In the enolate oxidation of the cyclopentadienone below{{cite journal|title=An Electrochemical Approach to the Guanacastepenes |first1=Chambers C. |last1=Hughes |first2=Aubry K. |last2=Miller | first3=Dirk |last3=Trauner | authorlink3 = Dirk Trauner| journal=Org. Lett. |year=2005 |volume=7 |issue=16 |pages=3425–3428 |url=http://www.cchem.berkeley.edu/trngrp/traunerweb/Publications/electrochemical.pdf |doi=10.1021/ol047387l |pmid=16048308 |url-status=dead |archive-url=https://web.archive.org/web/20060904162144/http://www.cchem.berkeley.edu/trngrp/traunerweb/Publications/electrochemical.pdf |archive-date=4 September 2006}} with either camphor enantiomer, the trans isomer is obtained because access for the hydroxyl group in the cis position is limited. The use of the standard oxaziridine did not result in an acyloin.
:File:Acyloin example Hughes.png
== Reactions ==
- Reduction of acyloins give diols.
- Oxidation of acyloins give diones.
- α-hydroxy ketones give positive Tollens' and Fehling's test.
- Some acyloins rearrange with positions swapped under the influence of base in the Lobry–de Bruyn–van Ekenstein transformation
- A similar reaction is the so-called Voigt amination{{cite journal| first1= E.|last1= von Meyer|first2= Karl|last2= Voigt | journal = J. Prakt. Chem. | title = Ueber die Einwirkung von primären aromatischen Aminen auf Benzoïn | trans-title = On the effect of primary aromatic amines on benzoin| language = German| doi = 10.1002/prac.18860340101| volume = 34| issue = 1| year = 1886| pages =1–27|url= https://zenodo.org/record/1427912}} where an acyloin reacts with a primary amine and phosphorus pentoxide to an α-keto amine:{{cite book|title=Amines: Synthesis, Properties and Applications|first= Stephen A.|last= Lawrence|year= 2004|publisher= Cambridge University Press |isbn=978-0-521-78284-5}}
- Indole synthesis,{{cite journal|last=Roth|first= Lepke |year=1972|title=Synthese von Indol- und Carbazol-Derivaten aus α-Hydroxyketonen und aromatischen Aminen|trans-title=Synthesis of indole and carbazole derivatives from α-hydroxyketones and aromatic amines|journal= Archiv der Pharmazie|volume=305 |pages=159–171|issue=3|doi=10.1002/ardp.19723050302|pmid= 5048240 |s2cid= 84990819 |language=German}} compare Bischler–Möhlau
See also
- Glycolaldehyde, a related molecule equivalent to an acyloin with both R groups as hydrogen (and thus an aldehyde not a ketone)