Riley oxidation

Last updated
Riley oxidation
Named after Harry Lister Riley
Reaction type Organic redox reaction

The Riley oxidation is a selenium dioxide-mediated oxidation of methylene groups adjacent to carbonyls. It was first reported by Harry Lister Riley and co-workers in 1932. [1] In the decade that ensued, selenium-mediated oxidation rapidly expanded in use, and in 1939, Andre Guillemonat and co-workers disclosed the selenium dioxide-mediated oxidation of olefins at the allylic position. [2] Today, selenium-dioxide-mediated oxidation of methylene groups to alpha ketones and at the allylic position of olefins is known as the Riley Oxidation. [3]

Contents

0 overview.jpg

Mechanism

The mechanism of oxidation of -CH2C(O)R group by SeO2 has been well investigated. [4] [5] [6] [7] The oxidation of carbonyl alpha methylene positions begins with attack by the enol tautomer at the electrophilic selenium center. Following rearrangement and loss of water, a second equivalent of water attacks the alpha position. Selenic acid is liberated in the final step to give the 1,2-dicarbonyl product.

8 mech1.jpg

Allylic oxidation using selenium-dioxide proceeds via an ene reaction at the electrophilic selenium center. A 2,3-sigmatropic shift, proceeding through an envelope-like transition state, gives the allylselenite ester, which upon hydrolysis gives the allylic alcohol. The (E)- orientation about the double bond, a consequence of the envelope-like transition state, is observed in the penultimate ester formation, is retained during the hydrolysis step giving the (E)-allylic alcohol product. [4] [8]

9 mech2.jpg

Scope

The Riley Oxidation is amenable to a variety of carbonyl and olefinic systems with a high degree of regiocontrol based on the substitution pattern of the given system.

Ketones with two available α-methylene positions react more quickly at the least hindered position.: [1]

1 aldehyde.jpg

Allylic oxidation can be predicted by the substitution pattern on the olefin. In the case of 1,2-disubstituted olefins, reaction rates follow CH > CH2 > CH3:

2 allylic.jpg

Geminally-substituted olefins react in the same order of reaction rates as above: [2]

6 gem sub.jpg

Trisubstituted alkenes experience reactivity at the more substituted end of the double bond. The order of reactivity follows that CH2 > CH3 > CH:

3 trisubtituted.jpg

Due to the rearrangement of the double bond, terminal olefins tend to give primary allylic alcohols:

5 terminal.jpg

Cyclic alkenes prefer to undergo allylic oxidation within the ring, rather than the allylic position at the sidechain. In bridged ring systems, Bredt’s rule is followed and bridgehead positions are not oxidized:

7 cyclic.jpg

Applications

In their strychnine total synthesis, R.B. Woodward and co-workers leveraged the Riley Oxidation to attain the trans-glyoxal. Epimerization of the alpha hydrogen led to cis-glyoxal, which spontaneously underwent cyclization with the secondary amine to yield dehydrostryninone. [9]

10 strychnine.jpg

Selenium-dioxide mediated oxidation was used in the synthesis of the diterpenoid ryanodol. [10]

11 ryanodol.jpg

Selenium dioxide mediated allylic oxidation to access ingenol. [11]

12 ingenol.jpg

Related Research Articles

<span class="mw-page-title-main">Allyl group</span> Chemical group (–CH₂–CH=CH₂)

In organic chemistry, an allyl group is a substituent with the structural formula −CH2−HC=CH2. It consists of a methylene bridge attached to a vinyl group. The name is derived from the scientific name for garlic, Allium sativum. In 1844, Theodor Wertheim isolated an allyl derivative from garlic oil and named it "Schwefelallyl". The term allyl applies to many compounds related to H2C=CH−CH2, some of which are of practical or of everyday importance, for example, allyl chloride.

The Wolff–Kishner reduction is a reaction used in organic chemistry to convert carbonyl functionalities into methylene groups. In the context of complex molecule synthesis, it is most frequently employed to remove a carbonyl group after it has served its synthetic purpose of activating an intermediate in a preceding step. As such, there is no obvious retron for this reaction. The reaction was reported by Nikolai Kischner in 1911 and Ludwig Wolff in 1912.

<span class="mw-page-title-main">Ene reaction</span> Reaction in organic chemistry

In organic chemistry, the ene reaction is a chemical reaction between an alkene with an allylic hydrogen and a compound containing a multiple bond, in order to form a new σ-bond with migration of the ene double bond and 1,5 hydrogen shift. The product is a substituted alkene with the double bond shifted to the allylic position.

The Simmons–Smith reaction is an organic cheletropic reaction involving an organozinc carbenoid that reacts with an alkene to form a cyclopropane. It is named after Howard Ensign Simmons, Jr. and Ronald D. Smith. It uses a methylene free radical intermediate that is delivered to both carbons of the alkene simultaneously, therefore the configuration of the double bond is preserved in the product and the reaction is stereospecific.

<span class="mw-page-title-main">Wacker process</span> Chemical reaction

The Wacker process or the Hoechst-Wacker process refers to the oxidation of ethylene to acetaldehyde in the presence of palladium(II) chloride and copper(II) chloride as the catalyst. This chemical reaction was one of the first homogeneous catalysis with organopalladium chemistry applied on an industrial scale.

An allylic rearrangement or allylic shift is an organic chemical reaction in which reaction at a center vicinal to a double bond causes the double bond to shift to an adjacent pair of atoms:

The Wittig reaction or Wittig olefination is a chemical reaction of an aldehyde or ketone with a triphenyl phosphonium ylide called a Wittig reagent. Wittig reactions are most commonly used to convert aldehydes and ketones to alkenes. Most often, the Wittig reaction is used to introduce a methylene group using methylenetriphenylphosphorane (Ph3P=CH2). Using this reagent, even a sterically hindered ketone such as camphor can be converted to its methylene derivative.

The Baeyer–Villiger oxidation is an organic reaction that forms an ester from a ketone or a lactone from a cyclic ketone, using peroxyacids or peroxides as the oxidant. The reaction is named after Adolf von Baeyer and Victor Villiger who first reported the reaction in 1899.

Organoselenium chemistry is the science exploring the properties and reactivity of organoselenium compounds, chemical compounds containing carbon-to-selenium chemical bonds. Selenium belongs with oxygen and sulfur to the group 16 elements or chalcogens, and similarities in chemistry are to be expected. Organoselenium compounds are found at trace levels in ambient waters, soils and sediments.

<span class="mw-page-title-main">Prins reaction</span> Chemical reaction involving organic compounds

The Prins reaction is an organic reaction consisting of an electrophilic addition of an aldehyde or ketone to an alkene or alkyne followed by capture of a nucleophile or elimination of an H+ ion. The outcome of the reaction depends on reaction conditions. With water and a protic acid such as sulfuric acid as the reaction medium and formaldehyde the reaction product is a 1,3-diol (3). When water is absent, the cationic intermediate loses a proton to give an allylic alcohol (4). With an excess of formaldehyde and a low reaction temperature the reaction product is a dioxane (5). When water is replaced by acetic acid the corresponding esters are formed.

<span class="mw-page-title-main">Wolff rearrangement</span> Chemical reaction

The Wolff rearrangement is a reaction in organic chemistry in which an α-diazocarbonyl compound is converted into a ketene by loss of dinitrogen with accompanying 1,2-rearrangement. The Wolff rearrangement yields a ketene as an intermediate product, which can undergo nucleophilic attack with weakly acidic nucleophiles such as water, alcohols, and amines, to generate carboxylic acid derivatives or undergo [2+2] cycloaddition reactions to form four-membered rings. The mechanism of the Wolff rearrangement has been the subject of debate since its first use. No single mechanism sufficiently describes the reaction, and there are often competing concerted and carbene-mediated pathways; for simplicity, only the textbook, concerted mechanism is shown below. The reaction was discovered by Ludwig Wolff in 1902. The Wolff rearrangement has great synthetic utility due to the accessibility of α-diazocarbonyl compounds, variety of reactions from the ketene intermediate, and stereochemical retention of the migrating group. However, the Wolff rearrangement has limitations due to the highly reactive nature of α-diazocarbonyl compounds, which can undergo a variety of competing reactions.

<span class="mw-page-title-main">Stork enamine alkylation</span> Reaction sequence in organic chemistry

The Stork enamine alkylation involves the addition of an enamine to a Michael acceptor or another electrophilic alkylation reagent to give an alkylated iminium product, which is hydrolyzed by dilute aqueous acid to give the alkylated ketone or aldehyde. Since enamines are generally produced from ketones or aldehydes, this overall process constitutes a selective monoalkylation of a ketone or aldehyde, a process that may be difficult to achieve directly.

The Kulinkovich reaction describes the organic synthesis of substituted cyclopropanols through reaction of esters with dialkyl­dialkoxy­titanium reagents, which are generated in situ from Grignard reagents containing a hydrogen in beta-position and titanium(IV) alkoxides such as titanium isopropoxide. This reaction was first reported by Oleg Kulinkovich and coworkers in 1989.

The Lemieux–Johnson or Malaprade–Lemieux–Johnson oxidation is a chemical reaction in which an olefin undergoes oxidative cleavage to form two aldehyde or ketone units. The reaction is named after its inventors, Raymond Urgel Lemieux and William Summer Johnson, who published it in 1956. The reaction proceeds in a two step manner, beginning with dihydroxylation of the alkene by osmium tetroxide, followed by a Malaprade reaction to cleave the diol using periodate. Periodate also serves to regenerate the osmium tetroxide. This means a only catalytic amount of the osmium reagent is needed and also that the two consecutive reactions can be performed as a single tandem reaction process. The Lemieux–Johnson reaction ceases at the aldehyde stage of oxidation and therefore produces the same results as ozonolysis.

Selenoxide elimination is a method for the chemical synthesis of alkenes from selenoxides. It is most commonly used to synthesize α,β-unsaturated carbonyl compounds from the corresponding saturated analogues. It is mechanistically related to the Cope reaction.

Oxidation with chromium(VI) complexes involves the conversion of alcohols to carbonyl compounds or more highly oxidized products through the action of molecular chromium(VI) oxides and salts. The principal reagents are Collins reagent, PDC, and PCC. These reagents represent improvements over inorganic chromium(VI) reagents such as Jones reagent.

An insertion reaction is a chemical reaction where one chemical entity interposes itself into an existing bond of typically a second chemical entity e.g.:

The Saegusa–Ito oxidation is a chemical reaction used in organic chemistry. It was discovered in 1978 by Takeo Saegusa and Yoshihiko Ito as a method to introduce α-β unsaturation in carbonyl compounds. The reaction as originally reported involved formation of a silyl enol ether followed by treatment with palladium(II) acetate and benzoquinone to yield the corresponding enone. The original publication noted its utility for regeneration of unsaturation following 1,4-addition with nucleophiles such as organocuprates.

<span class="mw-page-title-main">Trifluoroperacetic acid</span> Chemical compound

Trifluoroperacetic acid is an organofluorine compound, the peroxy acid analog of trifluoroacetic acid, with the condensed structural formula CF
3
COOOH
. It is a strong oxidizing agent for organic oxidation reactions, such as in Baeyer–Villiger oxidations of ketones. It is the most reactive of the organic peroxy acids, allowing it to successfully oxidise relatively unreactive alkenes to epoxides where other peroxy acids are ineffective. It can also oxidise the chalcogens in some functional groups, such as by transforming selenoethers to selones. It is a potentially explosive material and is not commercially available, but it can be quickly prepared as needed. Its use as a laboratory reagent was pioneered and developed by William D. Emmons.

References

  1. 1 2 Riley, Harry Lister; Morley, John Frederick; Friend, Norman Alfred Child (1932-01-01). "255. Selenium dioxide, a new oxidising agent. Part I. Its reaction with aldehydes and ketones". Journal of the Chemical Society (Resumed): 1875–1883. doi:10.1039/jr9320001875. ISSN   0368-1769.
  2. 1 2 Guillemonat (1939). "Oxidation of ethylenic hydrocarbons using selenium dioxide".
  3. Kurti, Laszlo (29 September 2005). Strategic Applications of Named Reactions in Organic Synthesis. Elsevier Science. pp. 380–381. ISBN   978-0-12-429785-2.
  4. 1 2 Trachtenberg, Edward N.; Nelson, Charles H.; Carver, Jane R. (1970-05-01). "Mechanism of selenium dioxide oxidation of olefins". The Journal of Organic Chemistry. 35 (5): 1653–1658. doi:10.1021/jo00830a083. ISSN   0022-3263.
  5. Sharpless, Karl Barry; Gordon, Kenneth M. (1976-01-01). "Selenium dioxide oxidation of ketones and aldehydes. Evidence for the intermediacy of .beta.-ketoseleninic". Journal of the American Chemical Society. 98 (1): 300–301. doi:10.1021/ja00417a083. ISSN   0002-7863.
  6. Warpehoski, M. A.; Chabaud, B.; Sharpless, Karl Barry (1982-07-01). "Selenium dioxide oxidation of endocyclic olefins. Evidence for a dissociation-recombination pathway". The Journal of Organic Chemistry. 47 (15): 2897–2900. doi:10.1021/jo00136a017. ISSN   0022-3263.
  7. Shafer, Cynthia M.; Morse, Daniel I.; Molinski, Tadeusz F. (1996). "Mechanism of SeO2 promoted oxidative rearrangement of 2-substituted oxazolines to dihydrooxazinones: Isotopic labeling and kinetic studies". Tetrahedron. 52 (46): 14475–14486. doi:10.1016/0040-4020(96)00902-7.
  8. Stephenson, L. M.; Speth, D. R. (1979). "Mechanism of allylic hydroxylation by selenium dioxide". The Journal of Organic Chemistry. 44 (25): 4683–4689. doi:10.1021/jo00393a045.
  9. Woodward, R. B.; Cava, Michael P.; Ollis, W. D.; Hunger, A.; Daeniker, H. U.; Schenker, K. (1954-09-01). "The Total Synthesis of Strychnine". Journal of the American Chemical Society. 76 (18): 4749–4751. doi:10.1021/ja01647a088. ISSN   0002-7863. PMID   13305562. S2CID   42677858.
  10. Chuang, Kangway V.; Xu, Chen; Reisman, Sarah E. (2016-08-26). "A 15-step synthesis of (+)-ryanodol". Science. 353 (6302): 912–915. Bibcode:2016Sci...353..912C. doi:10.1126/science.aag1028. ISSN   0036-8075. PMC   5505075 . PMID   27563092.
  11. Jørgensen, Lars; McKerrall, Steven J.; Kuttruff, Christian A.; Ungeheuer, Felix; Felding, Jakob; Baran, Phil S. (2013-08-23). "14-Step Synthesis of (+)-Ingenol from (+)-3-Carene". Science. 341 (6148): 878–882. Bibcode:2013Sci...341..878J. doi:10.1126/science.1241606. ISSN   0036-8075. PMID   23907534. S2CID   26998997.