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Carbonyl reduction

April 14, 2024

In organic chemistry, carbonyl reduction is the conversion of any carbonyl group, usually to an alcohol. It is a common transformation that is practiced in many ways.[1] Ketones, aldehydes, carboxylic acids, esters, amides, and acid halides - some of the most pervasive functional groups, -comprise carbonyl compounds. Carboxylic acids, esters, and acid halides can be reduced to either aldehydes or a step further to primary alcohols, depending on the strength of the reducing agent. Aldehydes and ketones can be reduced respectively to primary and secondary alcohols. In deoxygenation, the alcohol group can be further reduced and removed altogether by replacement with H.

Oxidation ladders such as this one are used to illustrate sequences of carbonyls which can be interconverted through oxidations or reductions.

Two broad strategies exist for carbonyl reduction. One method, which is favored in industry, uses hydrogen as the reductant. This approach is called hydrogenation and requires metal catalysts. The other broad approach employs stoichiometric reagents that deliver H- and H+ separately. This article focuses on the use of these reagents. Prominent among these reagents are the alkali metal salts of borohydrides and aluminium hydrides.

General considerations edit

 
Resonance structures of different carbonyls, ordered from most stable (least reactive) to least stable (most reactive)

In terms of reaction mechanism, metal hydrides effect nucleophilic addition of hydride to the carbonyl carbon. The ease of addition of hydride to the carbonyl is affected by electrophilicity and bulk of the carbonyl as well as the corresponding electronic and steric properties of the hydride reagent.. The result of these trends is that acid halides, ketones, and aldehydes are usually the most readily reduced compounds, while acids and esters require stronger reducing agents. Importantly and characteristically, these hydride reagents generally do not attack C=C bonds.[2]

Several factors contribute to the strength of metal hydride reducing agents. The reducing power of borohydride reagents is affected by the counter ion, such as Na+ vs Li+ which can activate carbonyls by coordinating to the carbonyl oxygen. Li+ binds to carbonyl oxygen more strongly than does Na+.[3] In the case of tetrahydroaluminates, however, NaAlH4 and LiAlH4 behave similarly.[2] Many metal additives have been investigated. For example, zinc borohydride, nominally Zn(BH4)2, is used for mild selective reduction of aldehydes and ketones in the presence of other reducible groups.[4]

The central metal (usually B vs Al) strongly influences reducing agent's strength. Aluminum hydrides are more nucleophilic and better reducing agents relative to borohydrides.[5] The relatively weak reducer sodium borohydride is typically used for reducing ketones and aldehydes. It tolerates many functional groups (nitro group, nitrile, ester).[6]

In their handling properties, lithium aluminium hydride and sodium borohydride (and their derivatives) strongly differ. NaBH4 is far easier to handle than LiAlH4, being air stable for weeks. It can be used with water or ethanol as solvents, whereas LiAlH4 reacts explosively with protic solvents.

Substituents on the boron or aluminium modulate the power, selectivity, and handling properties of these reducing agents. Electron-withdrawing groups such as acetoxy and cyano lower the reducing power such that NaBH(OAc)3 and NaBH3(CN) are weak reducing agents. Electron-donating groups such as alkyl groups enhance the reducing strength. superhydride (lithium triethylborohydride) and L-selectride are strong reductant. They are correspondingly hazardous to handle.

The following table[7] illustrates which carbonyl functional groups can be reduced by which reducing agents (some of these reagents vary in efficacy depending on reaction conditions):

 
Table of possible reactions between carbonyl groups and reducing agents

Substrates edit

Carboxylic acid and esters edit

Relative to aldehydes and ketones, carboxylic acid are difficult to reduce. Lithium aluminium hydride is typically is effective. The first step involves deprotonation of the carboxylic acid. The final step in the reduction of carboxylic acids and esters is hydrolysis of the aluminium alcoxide.[8] Esters (and amides) are more easily reduced than the parent carboxylic acids. Their reduction affords alcohols and amines, respectively.[9] The idealized equation for the reduction of an ester by lithium aluminium hydride is:

2 RCO2R' + LiAlH4 → LiAl(OCH2R)2(OR')
LiAl(OCH2R)2(OR') + 4 H2O → LiAl(OH)4 + 2 HOCH2R + 2 HOR'

Sodium borohydride can, under some circumstances, be used for ester reduction, especially with additives.[1]

Forming aldehydes from carboxylic acid derivatives is challenging because weaker reducing agents (NaBH4) are often very slow at reducing esters and carboxylic acids, whereas stronger reducing agents (LiAlH4) immediately reduce the formed aldehyde to an alcohol.[10]

 
Conversion to thioester followed by Fukuyama reduction

In the Fukuyama reduction, a carboxylic acid is first converted to a thioester through addition of a thiol (with a mechanism similar to esterification).[11] The thioester is then reduced to an aldehyde by a silyl hydride with a palladium catalyst.

Acid chlorides to aldehydes edit

Acid chlorides can be reduced to give aldehydes with sterically hindered hydride donors. The reducing agent DIBAL-H (diisobutylaluminium hydride) is often used for this purpose, although it normally reduces any carbonyl. DIBAL-H can selectively reduce acid chlorides to the aldehyde level if only one equivalent is used at low temperatures.[12] LiAlH(OtBu)3 (formed from LiAlH4 and tBuOH in situ) behaves similarly.[13] The idealized equation for the reduction of an acid chloride to an aldehyde by lithium aluminium hydride is:

RCOCl + LiAlH(OtBu)3 → LiCl + "Al(OtBu)3" + RCHO

The traditional method of forming aldehydes without reducing to alcohols - by using hindered hydrides and reactive carbonyls - is limited by its narrow substrate scope and great dependence on reaction conditions. One workaround to avoid this method is to reduce the carboxylic acid derivative all the way down to an alcohol, then oxidize the alcohol back to an aldehyde. Other alternatives include forming a thioester or a Weinreb amide, then reducing the new species to an aldehyde through the Fukuyama reduction or Weinreb reaction respectively, or using catalytic hydrogenation as in the Rosenmund reaction.

In the Weinreb ketone synthesis, an acyl chloride is first converted to the Weinreb amide, then treated with an organometallic reagent to form a ketone, or lithium aluminum hydride to form an aldehyde:[14]

 

The Weinreb amide is reduced via a stable chelate, rather than the electrophilic carbonyl that is formed through metal hydride reductions; the chelate is therefore only reduced once, as illustrated below:

 

The Rosenmund reaction reduces acyl chlorides to aldehydes using hydrogen gas with a catalyst of palladium on barium sulfate, whose small surface area prevents over-reduction.[15]

Aldehydes and ketones edit

Ketones are less reactive than aldehydes, because of greater steric effects, and because the extra alkyl group contributes electron density to the C=O bond, making it less electrophilic.[16] Since, aldehydes reduce more easily than ketones, they require milder reagents and milder conditions. At the other extreme, carboxylic acids, amides, and esters are poorly electrophilic and require strong reducing agents.[17]

The idealized equation for the reduction of a ketone by sodium borohydride is:

4 RCOR' + NaBH4 → NaB(OCHRR')4
NaB(OCHRR')4) + 4 H2O → "NaB(OH)4" + 4 HOCHRR' + 4 HOR'
 
Complete idealized mechanism for the reduction of ketone with sodium borohydride.

Reductive amination edit

Main article: reductive amination
 

In addition to their reduction to alcohols, aldehydes and ketones can be converted to amines, i.e., reductive amination.[18] Because of its cyano substituent, NaBH3CN is a weak reducer at moderate pH (>4), so it preferentially reduces iminium cations that exist in the presence of carbonyls:

α,β-unsaturated carbonyls edit

 

When an α,β-unsaturated carbonyl is reduced, three products can result: an allyl alcohol from simple carbonyl reduction, a saturated ketone or aldehyde resulting from 1,4‑reduction (also called conjugate reduction), or the saturated alcohol from double reduction.[19] Use of NaBH4 can give any of these results, but InCl3 or NiCl2 catalyze specifically 1,4‑reductions.[1] Potassium or lithium tri‐sec‐butylborohydride sometimes selects 1,4‑reductions, but can be stymied by steric hindrance.[20] To selectively form the allyl alcohol and avoid the 1,4 product, the Luche reduction uses "cerium borohydride" generated in situ from NaBH4 and CeCl3(H2O)7 [21][22] The hydride source Zn(BH4)2 also shows 1,2 selectivity, as well as greater diastereoselectivity; it does so by coordinating not only to the carbonyl oxygen but also to adjacent atoms:[23]

 

Hydrogenolysis edit

A special case of carbonyl reduction entails complete deoxygenation, i.e. hydrogenolysis. This result is often undesirable because it involves defunctionalization.

Some reactions for this transformation include the Clemmensen reduction (in strongly acidic conditions) and the Wolff–Kishner reduction (in strongly basic conditions), as well as the various modifications of Wolff-Kishner reaction. The Caglioti modification, for instance, uses tosylhydrazone with a hydride donor in milder conditions with no base;[24] the Myers modification substitutes hydrazine with bis(tert-butyldimethylsilyl)-hydrazine, uses milder conditions at room temperature, and is rapid and efficient.[25]

 
Mechanism of Wolff-Kishner reduction

Aromatic carbonyls are more readily reduced to their respective alkanes than aliphatic compounds.[26] For example, ketones are reduced to their respective alkyl benzenes by catalytic hydrogenation[27][28] or by Birch reduction[29] under mild conditions.

Stereoselectivity edit

Main article: Asymmetric catalytic reduction

Diastereoselective reduction edit

In the reduction of cyclohexanones, the hydride source can attack axially to produce an equatorial alcohol, or equatorially to produce an axial alcohol. In axial attack (shown in red), the hydride encounters 1,3-diaxial strain. In equatorial attack (shown in blue), the hydride avoids the 1,3-diaxial interaction, but the substrate undergoes unfavorable torsional strain when the newly formed alcohol and added hydrogen atom eclipse each other in the reaction intermediate (as shown in the Newman projection for the axial alcohol).

 

Large reducing agents, such as LiBH(Me2CHCHMe)3, are hindered by the 1,3-axial interactions and therefore attack equatorially.[6] Small reducing agents, such as NaBH4, preferentially attack axially in order to avoid the eclipsing interactions, because the 1,3-diaxial interaction for small molecules is minimal; stereoelectronic reasons have also been cited for small reducing agents' axial preference.[30] Making the substrate bulkier (and increasing 1,3-axial interactions), however, decreases the prevalence of axial attacks, even for small hydride donors.[31]

Enantioselective reduction edit

Main article: Enantioselective reduction of ketones

When asymmetrical ketones are reduced, the resulting secondary alcohol has a chiral center whose can be controlled using chiral catalysts.

Well-known carbonyl reductions in asymmetric synthesis are the Noyori asymmetric hydrogenation (beta-ketoester reduction/Ru/BINAP) and the CBS reduction (BH3, proline derived chiral catalyst).

History and alternative methods edit

The Bouveault–Blanc reduction, employing a mixture of sodium metal in the presence of alcohols, was an early method for reduction of carbonyls.[32] It is now largely obsolete. Subsequent to the discovery of the Bouveault–Blanc reduction, many methods were developed, including the major breakthrough of catalytic hydrogenation where H2 serves as the reductant.[33] Salts boron and aluminium hydrides, discovered starting in the 1940s, proved to be highly convenient reagents for carbonyl reduction.

In the Meerwein-Ponndorf-Verley reduction, aluminium isopropoxide functions as the hydride source. The status of this reaction has been summarized thusly "the synthetic organic chemist will rarely attempt to use such a conventional technique as the Meerwein−Ponndorf−Verley (MPV) reaction".[34]

See also edit

References edit

  1. ^ a b c Banfi, Luca; Narisano, Enrica; Riva, Renata; Stiasni, Nikola; Hiersemann, Martin; Yamada, Tohru; Tsubo, Tatsuyuki (2014). "Sodium Borohydride". Encyclopedia of Reagents for Organic Synthesis. pp. 1–13. doi:10.1002/047084289X.rs052.pub3. ISBN 9780470842898.
  2. ^ a b Brown, Herbert C.; Ramachandran, P. Veeraraghavan (1996). "Sixty Years of Hydride Reductions". Reductions in Organic Synthesis. ACS Symposium Series. Vol. 641. pp. 1–30. doi:10.1021/bk-1996-0641.ch001. ISBN 9780841233812.
  3. ^ König, Burkhard (2009). (PDF). Modern Methods in Organic Synthesis. Institut für Organische Chemie, Uni Regensburg. Archived from the original (PDF) on August 24, 2015. Retrieved December 1, 2015.
  4. ^ Oishi, Takeshi; Nakata, Tadashi (2001). "Zinc Borohydride". Encyclopedia of Reagents for Organic Synthesis. doi:10.1002/047084289X.rz004. ISBN 0471936235.
  5. ^ Sweeting, Linda M. (2001). . Towson University. Archived from the original on November 16, 2015. Retrieved December 1, 2015.
  6. ^ a b Banfi, Luca; Narisano, Enrica; Riva, Renata (2001-01-01). Sodium Borohydride. John Wiley & Sons, Ltd. doi:10.1002/047084289x.rs052. ISBN 9780470842898.
  7. ^ Smith, Michael B.; March, Jerry (2007), Advanced Organic Chemistry: Reactions, Mechanisms, and Structure (6th ed.), New York: Wiley-Interscience, p. 1790, ISBN 978-0-471-72091-1
  8. ^ Moffett, Robert Bruce (1953). "2-(1-Pyrrolidyl)propanol". Organic Syntheses. 33: 82. doi:10.15227/orgsyn.033.0082.
  9. ^ McMurry, John E. (1973). "Isoxazole Annelation Reaction: 1-Methyl-4,4a,5,6,7,8-hexahydronaphthalen-2(3H)-one". Organic Syntheses. 53: 70. doi:10.15227/orgsyn.053.0070.
  10. ^ Gaylord, Norman G. (1957-08-01). "Reduction with complex metal hydrides". Journal of Chemical Education. 34 (8): 367. Bibcode:1957JChEd..34..367G. doi:10.1021/ed034p367.
  11. ^ Fukuyama, Tohru; Lin, Shao Cheng; Li, Leping (1990-09-01). "Facile reduction of ethyl thiol esters to aldehydes: application to a total synthesis of (+)-neothramycin A methyl ether". Journal of the American Chemical Society. 112 (19): 7050–7051. doi:10.1021/ja00175a043. ISSN 0002-7863.
  12. ^ Zakharkin, L.I.; Khorlina, I.M. (1962). "Reduction of esters of carboxylic acids into aldehydes with diisobutylaluminium hydride". Tetrahedron Letters. 3 (14): 619–620. doi:10.1016/s0040-4039(00)70918-x.
  13. ^ Cortes, Sergio (2010). "Using Hydrogen as a Nucleophile in Hydride Reductions" (PDF). Dr. Sergio Cortes' Organic Chemistry Page. University of Texas at Dallas. Retrieved December 1, 2015.
  14. ^ Nahm, Steven; Weinreb, Steven M. (1981). "N-methoxy-n-methylamides as effective acylating agents". Tetrahedron Letters. 22 (39): 3815–3818. doi:10.1016/s0040-4039(01)91316-4.
  15. ^ Mosettig, Erich; Mozingo, Ralph (2004-01-01). The Rosenmund Reduction of Acid Chlorides to Aldehydes. John Wiley & Sons, Inc. doi:10.1002/0471264180.or004.07. ISBN 9780471264187.
  16. ^ Roche, Alex. "Ketones and Aldehydes" (PDF). Rutgers University. Retrieved December 1, 2015.
  17. ^ Clayden, Jonathan (2012). Organic Chemistry. OUP Oxford. p. 200. ISBN 978-0199270293.
  18. ^ Afanasyev, Oleg I.; Kuchuk, Ekaterina; Usanov, Dmitry L.; Chusov, Denis (2019). "Reductive Amination in the Synthesis of Pharmaceuticals". Chemical Reviews. 119 (23): 11857–11911. doi:10.1021/acs.chemrev.9b00383. PMID 31633341. S2CID 204814584.
  19. ^ Smith, Michael B.; March, Jerry (2007), Advanced Organic Chemistry: Reactions, Mechanisms, and Structure (6th ed.), New York: Wiley-Interscience, p. 1070, ISBN 978-0-471-72091-1
  20. ^ Note that although Banfi et al. 2014 unequivocally recommends the sec-butyl derivative for 1,4‑reductions, Hubbard's initial commentary in Hubbard & Dake (2012) "Lithium Tri-sec-butylborohydride". Ibid. doi:10.1002/047084289X.rl145.pub2 gives only examples of 1,2‑reductions.
  21. ^ Strategic Applications of Named Reactions in Organic Synthesis (Paperback) by Laszlo Kurti, Barbara Czako ISBN 0-12-429785-4
  22. ^ Paquette, Leo A.; Sabitha, G.; Yadav, J. S.; Scheuermann, Angelique M.; Merchant, Rohan R. (2021). "Cerium(III) Chloride". Encyclopedia of Reagents for Organic Synthesis. pp. 1–15. doi:10.1002/047084289X.rc041.pub3. ISBN 9780471936237.
  23. ^ Greeves, Nick (2015). "Diastereoselective Ketone Reduction". ChemTube3D. University of Liverpool. Retrieved December 1, 2015.
  24. ^ Caglioti, L.; Magi, M. (1963-01-01). "The reaction of tosylhydrazones with lithium aluminium hydride". Tetrahedron. 19 (7): 1127–1131. doi:10.1016/S0040-4020(01)98571-0.
  25. ^ Furrow, Michael E.; Myers, Andrew G. (2004-05-01). "Practical Procedures for the Preparation of N-tert-Butyldimethylsilylhydrazones and Their Use in Modified Wolff−Kishner Reductions and in the Synthesis of Vinyl Halides and gem-Dihalides". Journal of the American Chemical Society. 126 (17): 5436–5445. doi:10.1021/ja049694s. ISSN 0002-7863. PMID 15113215.
  26. ^ Nishimura, Shigeo (2001). Handbook of Heterogeneous Catalytic Hydrogenation for Organic Synthesis (1st ed.). New York: Wiley-Interscience. p. 583. ISBN 9780471396987.
  27. ^ Zaccheria, Federica; Ravasio, Nicoletta; Ercoli, Mauro; Allegrini, Pietro (2005). "Heterogeneous Cu-catalysts for the reductive deoxygenation of aromatic ketones without additives". Tetrahedron Letters. 46 (45): 7743–7745. doi:10.1016/j.tetlet.2005.09.041.
  28. ^ Walker, Gordon (1956). "Reduction of Enols. New Synthesis of Certain Methoxybenzsuberenes via Hydrogenation of Dehydroacetic Acids". Journal of the American Chemical Society. 78 (13): 3201–3205. doi:10.1021/ja01594a062.
  29. ^ Hall, Stan; Lipsky, Sharon; McEnroe, Frank; Bartels, Anne (1971). "Lithium-ammonia reduction of aromatic ketones to aromatic hydrocarbons". The Journal of Organic Chemistry. 36 (18): 2588–2591. doi:10.1021/jo00817a004.
  30. ^ Wong, Stephen S.; Paddon-Row, Michael N. (January 1990). "Theoretical evidence in support of the Anh?Eisenstein electronic model in controlling ?-facial stereoselectivity in nucleophilic additions to carbonyl compounds". Journal of the Chemical Society, Chemical Communications (6): 456–458. doi:10.1039/c39900000456.
  31. ^ Krishnamurthy, S.; Brown, Herbert C. (1976-05-01). "Lithium trisiamylborohydride. A new sterically hindered reagent for the reduction of cyclic ketones with exceptional stereoselectivity". Journal of the American Chemical Society. 98 (11): 3383–3384. doi:10.1021/ja00427a061. ISSN 0002-7863.
  32. ^ Bouveault, Louis; Blanc, Gustave Louis (1903). "Préparation des alcools primaires au moyen des acides correspondants" [Preparation of primary alcohols by means of the corresponding acids]. Compt. Rend. (in French). 136: 1676–1678.
  33. ^ Wheeler, Owen H. (1966). "Reduction of carbonyl groups". In Saul Patai (ed.). The Carbonyl Group: Vol. 1 (1966). PATAI'S Chemistry of Functional Groups. pp. 507–566. doi:10.1002/9780470771051.ch11. ISBN 9780470771051.
  34. ^ Cha, Jin Soon (2006). "Recent Developments in Meerwein−Ponndorf−Verley and Related Reactions for the Reduction of Organic Functional Groups Using Aluminum, Boron, and Other Metal Reagents: A Review". Organic Process Research & Development. 10 (5): 1032–1053. doi:10.1021/op068002c.

April 14, 2024
carbonyl, reduction, organic, chemistry, carbonyl, reduction, conversion, carbonyl, group, usually, alcohol, common, transformation, that, practiced, many, ways, ketones, aldehydes, carboxylic, acids, esters, amides, acid, halides, some, most, pervasive, funct. In organic chemistry carbonyl reduction is the conversion of any carbonyl group usually to an alcohol It is a common transformation that is practiced in many ways 1 Ketones aldehydes carboxylic acids esters amides and acid halides some of the most pervasive functional groups comprise carbonyl compounds Carboxylic acids esters and acid halides can be reduced to either aldehydes or a step further to primary alcohols depending on the strength of the reducing agent Aldehydes and ketones can be reduced respectively to primary and secondary alcohols In deoxygenation the alcohol group can be further reduced and removed altogether by replacement with H Oxidation ladders such as this one are used to illustrate sequences of carbonyls which can be interconverted through oxidations or reductions Two broad strategies exist for carbonyl reduction One method which is favored in industry uses hydrogen as the reductant This approach is called hydrogenation and requires metal catalysts The other broad approach employs stoichiometric reagents that deliver H and H separately This article focuses on the use of these reagents Prominent among these reagents are the alkali metal salts of borohydrides and aluminium hydrides Contents 1 General considerations 2 Substrates 2 1 Carboxylic acid and esters 2 2 Acid chlorides to aldehydes 2 3 Aldehydes and ketones 2 3 1 Reductive amination 2 3 2 a b unsaturated carbonyls 3 Hydrogenolysis 4 Stereoselectivity 4 1 Diastereoselective reduction 4 2 Enantioselective reduction 5 History and alternative methods 6 See also 7 ReferencesGeneral considerations edit nbsp Resonance structures of different carbonyls ordered from most stable least reactive to least stable most reactive In terms of reaction mechanism metal hydrides effect nucleophilic addition of hydride to the carbonyl carbon The ease of addition of hydride to the carbonyl is affected by electrophilicity and bulk of the carbonyl as well as the corresponding electronic and steric properties of the hydride reagent The result of these trends is that acid halides ketones and aldehydes are usually the most readily reduced compounds while acids and esters require stronger reducing agents Importantly and characteristically these hydride reagents generally do not attack C C bonds 2 Several factors contribute to the strength of metal hydride reducing agents The reducing power of borohydride reagents is affected by the counter ion such as Na vs Li which can activate carbonyls by coordinating to the carbonyl oxygen Li binds to carbonyl oxygen more strongly than does Na 3 In the case of tetrahydroaluminates however NaAlH4 and LiAlH4 behave similarly 2 Many metal additives have been investigated For example zinc borohydride nominally Zn BH4 2 is used for mild selective reduction of aldehydes and ketones in the presence of other reducible groups 4 The central metal usually B vs Al strongly influences reducing agent s strength Aluminum hydrides are more nucleophilic and better reducing agents relative to borohydrides 5 The relatively weak reducer sodium borohydride is typically used for reducing ketones and aldehydes It tolerates many functional groups nitro group nitrile ester 6 In their handling properties lithium aluminium hydride and sodium borohydride and their derivatives strongly differ NaBH4 is far easier to handle than LiAlH4 being air stable for weeks It can be used with water or ethanol as solvents whereas LiAlH4 reacts explosively with protic solvents Substituents on the boron or aluminium modulate the power selectivity and handling properties of these reducing agents Electron withdrawing groups such as acetoxy and cyano lower the reducing power such that NaBH OAc 3 and NaBH3 CN are weak reducing agents Electron donating groups such as alkyl groups enhance the reducing strength superhydride lithium triethylborohydride and L selectride are strong reductant They are correspondingly hazardous to handle The following table 7 illustrates which carbonyl functional groups can be reduced by which reducing agents some of these reagents vary in efficacy depending on reaction conditions nbsp Table of possible reactions between carbonyl groups and reducing agentsSubstrates editCarboxylic acid and esters edit Relative to aldehydes and ketones carboxylic acid are difficult to reduce Lithium aluminium hydride is typically is effective The first step involves deprotonation of the carboxylic acid The final step in the reduction of carboxylic acids and esters is hydrolysis of the aluminium alcoxide 8 Esters and amides are more easily reduced than the parent carboxylic acids Their reduction affords alcohols and amines respectively 9 The idealized equation for the reduction of an ester by lithium aluminium hydride is 2 RCO2R LiAlH4 LiAl OCH2R 2 OR LiAl OCH2R 2 OR 4 H2O LiAl OH 4 2 HOCH2R 2 HOR Sodium borohydride can under some circumstances be used for ester reduction especially with additives 1 Forming aldehydes from carboxylic acid derivatives is challenging because weaker reducing agents NaBH4 are often very slow at reducing esters and carboxylic acids whereas stronger reducing agents LiAlH4 immediately reduce the formed aldehyde to an alcohol 10 nbsp Conversion to thioester followed by Fukuyama reductionIn the Fukuyama reduction a carboxylic acid is first converted to a thioester through addition of a thiol with a mechanism similar to esterification 11 The thioester is then reduced to an aldehyde by a silyl hydride with a palladium catalyst Acid chlorides to aldehydes edit Acid chlorides can be reduced to give aldehydes with sterically hindered hydride donors The reducing agent DIBAL H diisobutylaluminium hydride is often used for this purpose although it normally reduces any carbonyl DIBAL H can selectively reduce acid chlorides to the aldehyde level if only one equivalent is used at low temperatures 12 LiAlH OtBu 3 formed from LiAlH4 and tBuOH in situ behaves similarly 13 The idealized equation for the reduction of an acid chloride to an aldehyde by lithium aluminium hydride is RCOCl LiAlH OtBu 3 LiCl Al OtBu 3 RCHOThe traditional method of forming aldehydes without reducing to alcohols by using hindered hydrides and reactive carbonyls is limited by its narrow substrate scope and great dependence on reaction conditions One workaround to avoid this method is to reduce the carboxylic acid derivative all the way down to an alcohol then oxidize the alcohol back to an aldehyde Other alternatives include forming a thioester or a Weinreb amide then reducing the new species to an aldehyde through the Fukuyama reduction or Weinreb reaction respectively or using catalytic hydrogenation as in the Rosenmund reaction In the Weinreb ketone synthesis an acyl chloride is first converted to the Weinreb amide then treated with an organometallic reagent to form a ketone or lithium aluminum hydride to form an aldehyde 14 nbsp The Weinreb amide is reduced via a stable chelate rather than the electrophilic carbonyl that is formed through metal hydride reductions the chelate is therefore only reduced once as illustrated below nbsp The Rosenmund reaction reduces acyl chlorides to aldehydes using hydrogen gas with a catalyst of palladium on barium sulfate whose small surface area prevents over reduction 15 Aldehydes and ketones edit Ketones are less reactive than aldehydes because of greater steric effects and because the extra alkyl group contributes electron density to the C O bond making it less electrophilic 16 Since aldehydes reduce more easily than ketones they require milder reagents and milder conditions At the other extreme carboxylic acids amides and esters are poorly electrophilic and require strong reducing agents 17 The idealized equation for the reduction of a ketone by sodium borohydride is 4 RCOR NaBH4 NaB OCHRR 4 NaB OCHRR 4 4 H2O NaB OH 4 4 HOCHRR 4 HOR nbsp Complete idealized mechanism for the reduction of ketone with sodium borohydride Reductive amination edit Main article reductive amination nbsp In addition to their reduction to alcohols aldehydes and ketones can be converted to amines i e reductive amination 18 Because of its cyano substituent NaBH3CN is a weak reducer at moderate pH gt 4 so it preferentially reduces iminium cations that exist in the presence of carbonyls a b unsaturated carbonyls edit nbsp When an a b unsaturated carbonyl is reduced three products can result an allyl alcohol from simple carbonyl reduction a saturated ketone or aldehyde resulting from 1 4 reduction also called conjugate reduction or the saturated alcohol from double reduction 19 Use of NaBH4 can give any of these results but InCl3 or NiCl2 catalyze specifically 1 4 reductions 1 Potassium or lithium tri sec butylborohydride sometimes selects 1 4 reductions but can be stymied by steric hindrance 20 To selectively form the allyl alcohol and avoid the 1 4 product the Luche reduction uses cerium borohydride generated in situ from NaBH4 and CeCl3 H2O 7 21 22 The hydride source Zn BH4 2 also shows 1 2 selectivity as well as greater diastereoselectivity it does so by coordinating not only to the carbonyl oxygen but also to adjacent atoms 23 nbsp Hydrogenolysis editA special case of carbonyl reduction entails complete deoxygenation i e hydrogenolysis This result is often undesirable because it involves defunctionalization Some reactions for this transformation include the Clemmensen reduction in strongly acidic conditions and the Wolff Kishner reduction in strongly basic conditions as well as the various modifications of Wolff Kishner reaction The Caglioti modification for instance uses tosylhydrazone with a hydride donor in milder conditions with no base 24 the Myers modification substitutes hydrazine with bis tert butyldimethylsilyl hydrazine uses milder conditions at room temperature and is rapid and efficient 25 nbsp Mechanism of Wolff Kishner reductionAromatic carbonyls are more readily reduced to their respective alkanes than aliphatic compounds 26 For example ketones are reduced to their respective alkyl benzenes by catalytic hydrogenation 27 28 or by Birch reduction 29 under mild conditions Stereoselectivity editMain article Asymmetric catalytic reduction Diastereoselective reduction edit In the reduction of cyclohexanones the hydride source can attack axially to produce an equatorial alcohol or equatorially to produce an axial alcohol In axial attack shown in red the hydride encounters 1 3 diaxial strain In equatorial attack shown in blue the hydride avoids the 1 3 diaxial interaction but the substrate undergoes unfavorable torsional strain when the newly formed alcohol and added hydrogen atom eclipse each other in the reaction intermediate as shown in the Newman projection for the axial alcohol nbsp Large reducing agents such as LiBH Me2CHCHMe 3 are hindered by the 1 3 axial interactions and therefore attack equatorially 6 Small reducing agents such as NaBH4 preferentially attack axially in order to avoid the eclipsing interactions because the 1 3 diaxial interaction for small molecules is minimal stereoelectronic reasons have also been cited for small reducing agents axial preference 30 Making the substrate bulkier and increasing 1 3 axial interactions however decreases the prevalence of axial attacks even for small hydride donors 31 Enantioselective reduction edit Main article Enantioselective reduction of ketones When asymmetrical ketones are reduced the resulting secondary alcohol has a chiral center whose can be controlled using chiral catalysts Well known carbonyl reductions in asymmetric synthesis are the Noyori asymmetric hydrogenation beta ketoester reduction Ru BINAP and the CBS reduction BH3 proline derived chiral catalyst History and alternative methods editThe Bouveault Blanc reduction employing a mixture of sodium metal in the presence of alcohols was an early method for reduction of carbonyls 32 It is now largely obsolete Subsequent to the discovery of the Bouveault Blanc reduction many methods were developed including the major breakthrough of catalytic hydrogenation where H2 serves as the reductant 33 Salts boron and aluminium hydrides discovered starting in the 1940s proved to be highly convenient reagents for carbonyl reduction In the Meerwein Ponndorf Verley reduction aluminium isopropoxide functions as the hydride source The status of this reaction has been summarized thusly the synthetic organic chemist will rarely attempt to use such a conventional technique as the Meerwein Ponndorf Verley MPV reaction 34 See also editBaker s yeast a biotransformation route for carbonyl reductions References edit a b c Banfi Luca Narisano Enrica Riva Renata Stiasni Nikola Hiersemann Martin Yamada Tohru Tsubo Tatsuyuki 2014 Sodium Borohydride Encyclopedia of Reagents for Organic Synthesis pp 1 13 doi 10 1002 047084289X rs052 pub3 ISBN 9780470842898 a b Brown Herbert C Ramachandran P Veeraraghavan 1996 Sixty Years of Hydride Reductions Reductions in Organic Synthesis ACS Symposium Series Vol 641 pp 1 30 doi 10 1021 bk 1996 0641 ch001 ISBN 9780841233812 Konig Burkhard 2009 Reduction Reactions PDF Modern Methods in Organic Synthesis Institut fur Organische Chemie Uni Regensburg Archived from the original PDF on August 24 2015 Retrieved December 1 2015 Oishi Takeshi Nakata Tadashi 2001 Zinc Borohydride Encyclopedia of Reagents for Organic Synthesis doi 10 1002 047084289X rz004 ISBN 0471936235 Sweeting Linda M 2001 Reducing Agents Towson University Archived from the original on November 16 2015 Retrieved December 1 2015 a b Banfi Luca Narisano Enrica Riva Renata 2001 01 01 Sodium Borohydride John Wiley amp Sons Ltd doi 10 1002 047084289x rs052 ISBN 9780470842898 Smith Michael B March Jerry 2007 Advanced Organic Chemistry Reactions Mechanisms and Structure 6th ed New York Wiley Interscience p 1790 ISBN 978 0 471 72091 1 Moffett Robert Bruce 1953 2 1 Pyrrolidyl propanol Organic Syntheses 33 82 doi 10 15227 orgsyn 033 0082 McMurry John E 1973 Isoxazole Annelation Reaction 1 Methyl 4 4a 5 6 7 8 hexahydronaphthalen 2 3H one Organic Syntheses 53 70 doi 10 15227 orgsyn 053 0070 Gaylord Norman G 1957 08 01 Reduction with complex metal hydrides Journal of Chemical Education 34 8 367 Bibcode 1957JChEd 34 367G doi 10 1021 ed034p367 Fukuyama Tohru Lin Shao Cheng Li Leping 1990 09 01 Facile reduction of ethyl thiol esters to aldehydes application to a total synthesis of neothramycin A methyl ether Journal of the American Chemical Society 112 19 7050 7051 doi 10 1021 ja00175a043 ISSN 0002 7863 Zakharkin L I Khorlina I M 1962 Reduction of esters of carboxylic acids into aldehydes with diisobutylaluminium hydride Tetrahedron Letters 3 14 619 620 doi 10 1016 s0040 4039 00 70918 x Cortes Sergio 2010 Using Hydrogen as a Nucleophile in Hydride Reductions PDF Dr Sergio Cortes Organic Chemistry Page University of Texas at Dallas Retrieved December 1 2015 Nahm Steven Weinreb Steven M 1981 N methoxy n methylamides as effective acylating agents Tetrahedron Letters 22 39 3815 3818 doi 10 1016 s0040 4039 01 91316 4 Mosettig Erich Mozingo Ralph 2004 01 01 The Rosenmund Reduction of Acid Chlorides to Aldehydes John Wiley amp Sons Inc doi 10 1002 0471264180 or004 07 ISBN 9780471264187 Roche Alex Ketones and Aldehydes PDF Rutgers University Retrieved December 1 2015 Clayden Jonathan 2012 Organic Chemistry OUP Oxford p 200 ISBN 978 0199270293 Afanasyev Oleg I Kuchuk Ekaterina Usanov Dmitry L Chusov Denis 2019 Reductive Amination in the Synthesis of Pharmaceuticals Chemical Reviews 119 23 11857 11911 doi 10 1021 acs chemrev 9b00383 PMID 31633341 S2CID 204814584 Smith Michael B March Jerry 2007 Advanced Organic Chemistry Reactions Mechanisms and Structure 6th ed New York Wiley Interscience p 1070 ISBN 978 0 471 72091 1 Note that although Banfi et al 2014 unequivocally recommends the sec butyl derivative for 1 4 reductions Hubbard s initial commentary in Hubbard amp Dake 2012 Lithium Tri sec butylborohydride Ibid doi 10 1002 047084289X rl145 pub2 gives only examples of 1 2 reductions Strategic Applications of Named Reactions in Organic Synthesis Paperback by Laszlo Kurti Barbara Czako ISBN 0 12 429785 4 Paquette Leo A Sabitha G Yadav J S Scheuermann Angelique M Merchant Rohan R 2021 Cerium III Chloride Encyclopedia of Reagents for Organic Synthesis pp 1 15 doi 10 1002 047084289X rc041 pub3 ISBN 9780471936237 Greeves Nick 2015 Diastereoselective Ketone Reduction ChemTube3D University of Liverpool Retrieved December 1 2015 Caglioti L Magi M 1963 01 01 The reaction of tosylhydrazones with lithium aluminium hydride Tetrahedron 19 7 1127 1131 doi 10 1016 S0040 4020 01 98571 0 Furrow Michael E Myers Andrew G 2004 05 01 Practical Procedures for the Preparation of N tert Butyldimethylsilylhydrazones and Their Use in Modified Wolff Kishner Reductions and in the Synthesis of Vinyl Halides and gem Dihalides Journal of the American Chemical Society 126 17 5436 5445 doi 10 1021 ja049694s ISSN 0002 7863 PMID 15113215 Nishimura Shigeo 2001 Handbook of Heterogeneous Catalytic Hydrogenation for Organic Synthesis 1st ed New York Wiley Interscience p 583 ISBN 9780471396987 Zaccheria Federica Ravasio Nicoletta Ercoli Mauro Allegrini Pietro 2005 Heterogeneous Cu catalysts for the reductive deoxygenation of aromatic ketones without additives Tetrahedron Letters 46 45 7743 7745 doi 10 1016 j tetlet 2005 09 041 Walker Gordon 1956 Reduction of Enols New Synthesis of Certain Methoxybenzsuberenes via Hydrogenation of Dehydroacetic Acids Journal of the American Chemical Society 78 13 3201 3205 doi 10 1021 ja01594a062 Hall Stan Lipsky Sharon McEnroe Frank Bartels Anne 1971 Lithium ammonia reduction of aromatic ketones to aromatic hydrocarbons The Journal of Organic Chemistry 36 18 2588 2591 doi 10 1021 jo00817a004 Wong Stephen S Paddon Row Michael N January 1990 Theoretical evidence in support of the Anh Eisenstein electronic model in controlling facial stereoselectivity in nucleophilic additions to carbonyl compounds Journal of the Chemical Society Chemical Communications 6 456 458 doi 10 1039 c39900000456 Krishnamurthy S Brown Herbert C 1976 05 01 Lithium trisiamylborohydride A new sterically hindered reagent for the reduction of cyclic ketones with exceptional stereoselectivity Journal of the American Chemical Society 98 11 3383 3384 doi 10 1021 ja00427a061 ISSN 0002 7863 Bouveault Louis Blanc Gustave Louis 1903 Preparation des alcools primaires au moyen des acides correspondants Preparation of primary alcohols by means of the corresponding acids Compt Rend in French 136 1676 1678 Wheeler Owen H 1966 Reduction of carbonyl groups In Saul Patai ed The Carbonyl Group Vol 1 1966 PATAI S Chemistry of Functional Groups pp 507 566 doi 10 1002 9780470771051 ch11 ISBN 9780470771051 Cha Jin Soon 2006 Recent Developments in Meerwein Ponndorf Verley and Related Reactions for the Reduction of Organic Functional Groups Using Aluminum Boron and Other Metal Reagents A Review Organic Process Research amp Development 10 5 1032 1053 doi 10 1021 op068002c Retrieved from https en wikipedia org w index php title Carbonyl reduction amp oldid 1195505640 1 2C4 reduction, wikipedia, wiki, book, books, library,

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