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Ketone

April 19, 2023

Not to be confused with ketone bodies.

In organic chemistry, a ketone /ˈktn/ is a functional group with the structure R−C(=O)−R', where R and R' can be a variety of carbon-containing substituents. Ketones contain a carbonyl group −C(=O)− (which contains a carbon-oxygen double bond C=O). The simplest ketone is acetone (where R and R' is methyl), with the formula (CH3)2CO. Many ketones are of great importance in biology and in industry. Examples include many sugars (ketoses), many steroids (e.g., testosterone), and the solvent acetone.[1]

Ketone
Acetone

Nomenclature and etymology

The word ketone is derived from Aketon, an old German word for acetone.[2][3]

According to the rules of IUPAC nomenclature, ketone names are derived by changing the suffix -ane of the parent alkane to -anone. Typically, the position of the carbonyl group is denoted by a number, but traditional nonsystematic names are still generally used for the most important ketones, for example acetone and benzophenone. These nonsystematic names are considered retained IUPAC names,[4] although some introductory chemistry textbooks use systematic names such as "2-propanone" or "propan-2-one" for the simplest ketone (CH3−C(=O)−CH3) instead of "acetone".

The derived names of ketones are obtained by writing separately the names of the two alkyl groups attached to the carbonyl group, followed by "ketone" as a separate word. Traditionally the names of the alkyl groups were written in order of increasing complexity, for example methyl ethyl ketone. However, according to the rules of IUPAC nomenclature, the alkyl groups are written alphabetically, for example ethyl methyl ketone. When the two alkyl groups are the same, the prefix "di-" is added before the name of alkyl group. The positions of other groups are indicated by Greek letters, the α-carbon being the atom adjacent to carbonyl group.

Although used infrequently, oxo is the IUPAC nomenclature for the oxo group (=O) and used as prefix when the ketone does not have the highest priority. Other prefixes, however, are also used. For some common chemicals (mainly in biochemistry), keto refer to the ketone functional group.

Structure and properties

 
Representative ketones, from the left: acetone, a common solvent; oxaloacetate, an intermediate in the metabolism of sugars; acetylacetone in its (mono) enol form (the enol highlighted in blue); cyclohexanone, precursor to nylon; muscone, an animal scent; and tetracycline, an antibiotic.

The ketone carbon is often described as sp2 hybridized, a description that includes both their electronic and molecular structure. Ketones are trigonal planar around the ketonic carbon, with C–C–O and C–C–C bond angles of approximately 120°. Ketones differ from aldehydes in that the carbonyl group (C=O) is bonded to two carbons within a carbon skeleton. In aldehydes, the carbonyl is bonded to one carbon and one hydrogen and are located at the ends of carbon chains. Ketones are also distinct from other carbonyl-containing functional groups, such as carboxylic acids, esters and amides.[5]

The carbonyl group is polar because the electronegativity of the oxygen is greater than that for carbon. Thus, ketones are nucleophilic at oxygen and electrophilic at carbon. Because the carbonyl group interacts with water by hydrogen bonding, ketones are typically more soluble in water than the related methylene compounds. Ketones are hydrogen-bond acceptors. Ketones are not usually hydrogen-bond donors and cannot hydrogen-bond to themselves. Because of their inability to serve both as hydrogen-bond donors and acceptors, ketones tend not to "self-associate" and are more volatile than alcohols and carboxylic acids of comparable molecular weights. These factors relate to the pervasiveness of ketones in perfumery and as solvents.

Classes of ketones

Ketones are classified on the basis of their substituents. One broad classification subdivides ketones into symmetrical and unsymmetrical derivatives, depending on the equivalency of the two organic substituents attached to the carbonyl center. Acetone and benzophenone ((C6H5)2CO) are symmetrical ketones. Acetophenone (C6H5C(O)CH3) is an unsymmetrical ketone.

Diketones

Main article: dicarbonyl

Many kinds of diketones are known, some with unusual properties. The simplest is diacetyl (CH3C(O)C(O)CH3), once used as butter-flavoring in popcorn. Acetylacetone (pentane-2,4-dione) is virtually a misnomer (inappropriate name) because this species exists mainly as the monoenol CH3C(O)CH=C(OH)CH3. Its enolate is a common ligand in coordination chemistry.

Unsaturated ketones

Ketones containing alkene and alkyne units are often called unsaturated ketones. The most widely used member of this class of compounds is methyl vinyl ketone, CH3C(O)CH=CH2, which is useful in the Robinson annulation reaction. Lest there be confusion, a ketone itself is a site of unsaturation; that is, it can be hydrogenated.

Cyclic ketones

Many ketones are cyclic. The simplest class have the formula (CH2)nCO, where n varies from 2 for cyclopropanone ((CH2)2CO) to the tens. Larger derivatives exist. Cyclohexanone ((CH2)5CO), a symmetrical cyclic ketone, is an important intermediate in the production of nylon. Isophorone, derived from acetone, is an unsaturated, asymmetrical ketone that is the precursor to other polymers. Muscone, 3-methylpentadecanone, is an animal pheromone. Another cyclic ketone is cyclobutanone, having the formula (CH2)3CO.

Keto-enol tautomerization

Main article: Enol
 
Keto-enol tautomerism. 1 is the keto form; 2 is the enol.

Ketones that have at least one alpha-hydrogen, undergo keto-enol tautomerization; the tautomer is an enol. Tautomerization is catalyzed by both acids and bases. Usually, the keto form is more stable than the enol. This equilibrium allows ketones to be prepared via the hydration of alkynes.

Acid/base properties of ketones

C−H bonds adjacent to the carbonyl in ketones are more acidic pKa ≈ 20) than the C−H bonds in alkane (pKa ≈ 50). This difference reflects resonance stabilization of the enolate ion that is formed upon deprotonation. The relative acidity of the α-hydrogen is important in the enolization reactions of ketones and other carbonyl compounds. The acidity of the α-hydrogen also allows ketones and other carbonyl compounds to react as nucleophiles at that position, with either stoichiometric and catalytic base. Using very strong bases like lithium diisopropylamide (LDA, pKa of conjugate acid ~36) under non-equilibrating conditions (–78 °C, 1.1 equiv LDA in THF, ketone added to base), the less-substituted kinetic enolate is generated selectively, while conditions that allow for equilibration (higher temperature, base added to ketone, using weak or insoluble bases, e.g., CH3CH2ONa in CH3CH2OH, or NaH) provides the more-substituted thermodynamic enolate.

Ketones are also weak bases, undergoing protonation on the carbonyl oxygen in the presence of Brønsted acids. Ketonium ions (i.e., protonated ketones) are strong acids, with pKa values estimated to be somewhere between –5 and –7.[6][7] Although acids encountered in organic chemistry are seldom strong enough to fully protonate ketones, the formation of equilibrium concentrations of protonated ketones is nevertheless an important step in the mechanisms of many common organic reactions, like the formation of an acetal, for example. Acids as weak as pyridinium cation (as found in pyridinium tosylate) with a pKa of 5.2 are able to serve as catalysts in this context, despite the highly unfavorable equilibrium constant for protonation (Keq < 10−10).

Characterization

An aldehyde differs from a ketone in that it has a hydrogen atom attached to its carbonyl group, making aldehydes easier to oxidize. Ketones do not have a hydrogen atom bonded to the carbonyl group, and are therefore more resistant to oxidation. They are oxidized only by powerful oxidizing agents which have the ability to cleave carbon–carbon bonds.

Spectroscopy

Ketones and aldehydes absorb strongly in the infra-red spectrum near 1700 cm−1. The exact position of the peak depends on the substituents.

Whereas 1H NMR spectroscopy is generally not useful for establishing the presence of a ketone, 13C NMR spectra exhibit signals somewhat downfield of 200 ppm depending on structure. Such signals are typically weak due to the absence of nuclear Overhauser effects. Since aldehydes resonate at similar chemical shifts, multiple resonance experiments are employed to definitively distinguish aldehydes and ketones.

Qualitative organic tests

Ketones give positive results in Brady's test, the reaction with 2,4-dinitrophenylhydrazine to give the corresponding hydrazone. Ketones may be distinguished from aldehydes by giving a negative result with Tollens' reagent or with Fehling's solution. Methyl ketones give positive results for the iodoform test.[8] Ketones also give positive results when treated with m-dinitrobenzene in presence of dilute sodium hydroxide to give violet coloration.

Synthesis

Many methods exist for the preparation of ketones in industrial scale and academic laboratories. Ketones are also produced in various ways by organisms; see the section on biochemistry below.

In industry, the most important method probably involves oxidation of hydrocarbons, often with air. For example, a billion kilograms of cyclohexanone are produced annually by aerobic oxidation of cyclohexane. Acetone is prepared by air-oxidation of cumene.

For specialized or small scale organic synthetic applications, ketones are often prepared by oxidation of secondary alcohols:

R2CH(OH) + "O" → R2C=O + H2O

Typical strong oxidants (source of "O" in the above reaction) include potassium permanganate or a Cr(VI) compound. Milder conditions make use of the Dess–Martin periodinane or the Moffatt–Swern methods.

Many other methods have been developed, examples include:[9]

Reactions

 
The Haller-Bauer reaction occurs between a non-enolizable ketone and a strong amide base. In this prototypical example involving benzophenone, the tetrahedral intermediate expels phenyl anion to give benzamide and benzene as the organic products

Ketones engage in many organic reactions. The most important reactions follow from the susceptibility of the carbonyl carbon toward nucleophilic addition and the tendency for the enolates to add to electrophiles. Nucleophilic additions include in approximate order of their generality:[9]

  • With strong oxidizing agents to give carboxylic acids. Ketones are generally oxidized under vigorous conditions, i.e., strong oxidizing agents and at elevated temperatures. Their oxidation involves carbon-carbon bond cleavage to afford a mixture of carboxylic acids having lesser number of carbon atoms than the parent ketone.
 

Biochemistry

See also: Coenzyme Q10 and Polyketide

Ketones are pervasive in nature. The formation of organic compounds in photosynthesis occurs via the ketone ribulose-1,5-bisphosphate. Many sugars are ketones, known collectively as ketoses. The best known ketose is fructose; it mostly exists as a cyclic hemiketal, which masks the ketone functional group. Fatty acid synthesis proceeds via ketones. Acetoacetate is an intermediate in the Krebs cycle which releases energy from sugars and carbohydrates.[22]

In medicine, acetone, acetoacetate, and beta-hydroxybutyrate are collectively called ketone bodies, generated from carbohydrates, fatty acids, and amino acids in most vertebrates, including humans. Ketone bodies are elevated in the blood (ketosis) after fasting, including a night of sleep; in both blood and urine in starvation; in hypoglycemia, due to causes other than hyperinsulinism; in various inborn errors of metabolism, and intentionally induced via a ketogenic diet, and in ketoacidosis (usually due to diabetes mellitus). Although ketoacidosis is characteristic of decompensated or untreated type 1 diabetes, ketosis or even ketoacidosis can occur in type 2 diabetes in some circumstances as well.

Applications

Ketones are produced on massive scales in industry as solvents, polymer precursors, and pharmaceuticals. In terms of scale, the most important ketones are acetone, methylethyl ketone, and cyclohexanone.[23] They are also common in biochemistry, but less so than in organic chemistry in general. The combustion of hydrocarbons is an uncontrolled oxidation process that gives ketones as well as many other types of compounds.

Toxicity

Although it is difficult to generalize on the toxicity of such a broad class of compounds, simple ketones are, in general, not highly toxic. This characteristic is one reason for their popularity as solvents. Exceptions to this rule are the unsaturated ketones such as methyl vinyl ketone with LD50 of 7 mg/kg (oral).[23]

See also

References

  1. ^ Raymond, Kenneth W. (2010). General Organic and Biological Chemistry (3rd ed.). Wiley. p. 297.
  2. ^ Harper, Douglas. "ketone". Online Etymology Dictionary.
  3. ^ The word "ketone" was coined in 1848 by the German chemist Leopold Gmelin. See: Leopold Gmelin, ed., Handbuch der organischen Chemie: Organische Chemie im Allgemeinen … (Handbook of organic chemistry: Organic chemistry in general … ), 4th ed., (Heidelberg, (Germany): Karl Winter, 1848), volume 1, p. 40. From page 40: "Zu diesen Syndesmiden scheinen auch diejenigen Verbindungen zu gehören, die als Acetone im Allegemeinen (Ketone?) bezeichnet werden." (To these syndesmides*, those compounds also seem to belong, which are designated as acetones in general (ketones?).") [*Note: In 1844, the French chemist Auguste Laurent suggested a new nomenclature for organic compounds. One of his new classes of compounds was "syndesmides", which were compounds formed by the combination of two or more simpler organic molecules (from the Greek σύνδεσμος (syndesmos, union) + -ide (indicating a group of related compounds)). For example, acetone could be formed by the dry distillation of metal acetates, so acetone was the syndesmide of two acetate ions. See: Laurent, Auguste (1844) "Classification chimique," Comptes rendus, 19 : 1089–1100 ; see especially p. 1097.
  4. ^ List of retained IUPAC names retained IUPAC names Link
  5. ^ McMurry, John E. (1992), Organic Chemistry (3rd ed.), Belmont: Wadsworth, ISBN 0-534-16218-5
  6. ^ Evans, David A. (4 November 2005). "Evans pKa table" (PDF). Evans group website. Retrieved 14 June 2018.
  7. ^ Smith, Michael B. (2013). March's Advanced Organic Chemistry (7th ed.). Hoboken, N.J.: Wiley. pp. 314–315. ISBN 978-0-470-46259-1.
  8. ^ Mendham, J.; Denney, R. C.; Barnes, J. D.; Thomas, M. J. K. (2000), Vogel's Quantitative Chemical Analysis (6th ed.), New York: Prentice Hall, ISBN 0-582-22628-7
  9. ^ a b Smith, Michael B.; March, Jerry (2007), Advanced Organic Chemistry: Reactions, Mechanisms, and Structure (6th ed.), New York: Wiley-Interscience, ISBN 978-0-471-72091-1
  10. ^ Marvel, C. S.; Sperry, W. M. (1928). "Benzophenone". Organic Syntheses. 8: 26. doi:10.15227/orgsyn.008.0026.
  11. ^ a b c d e Furniss, Brian; Hannaford, Antony; Smith, Peter; Tatchell, Austin (1996). Vogel's Textbook of Practical Organic Chemistry (5th ed.). London: Longman Science & Technical. pp. 612–623, 976–977, 982–983. ISBN 9780582462366.
  12. ^ Allen, C. F. H.; Barker, W. E. (1932). "Desoxybenzoin". Organic Syntheses. 12: 16. doi:10.15227/orgsyn.012.0016.
  13. ^ Gulati, K. C.; Seth, S.R.; Venkataraman, K. (1935). "Phloroacetophenone". Organic Syntheses. 15: 70. doi:10.15227/orgsyn.015.0070.
  14. ^ Tietze, Lutz F.; Bratz, Matthias (1993). "Dialkyl Mesoxalates by Ozonolysis of Dialkyl Benzalmalonates: Dimethyl Mesoxalate". Organic Syntheses. 71: 214. doi:10.15227/orgsyn.071.0214.
  15. ^ Heinzelman, R. V. (1955). "o-Methoxyphenylacetone". Organic Syntheses. 35: 74. doi:10.15227/orgsyn.035.0074.
  16. ^ Wiley, Richard H.; Borum, O. H. (1953). "3-Acetamido-2-butanone". Organic Syntheses. 33: 1. doi:10.15227/orgsyn.033.0001.
  17. ^ Moffett, R. B.; Shriner, R. L. (1941). "ω-Methoxyacetophenone". Organic Syntheses. 21: 79. doi:10.15227/orgsyn.021.0079.
  18. ^ Thorpe, J. F.; Kon, G. A. R. (1925). "Cyclopentanone". Organic Syntheses. 5: 37. doi:10.15227/orgsyn.005.0037.
  19. ^ Fieser, Louis F. (1937). "1,2-Naphthoquinone". Organic Syntheses. 17: 68. doi:10.15227/orgsyn.017.0068.
  20. ^ Herbst, R. M.; Shemin, D. (1939). "Phenylpyruvic acid". Organic Syntheses. 19: 77. doi:10.15227/orgsyn.019.0077.
  21. ^ . homeip.net
  22. ^ Nelson, D. L.; Cox, M. M. (2000) Lehninger, Principles of Biochemistry. 3rd Ed. Worth Publishing: New York. ISBN 1-57259-153-6.
  23. ^ a b Siegel, Hardo; Eggersdorfer, Manfred (2000). "Ketones". Ullmann's Encyclopedia of Industrial Chemistry. doi:10.1002/14356007.a15077 (inactive 31 December 2022). ISBN 9783527306732.{{cite book}}: CS1 maint: DOI inactive as of December 2022 (link)

External links

 
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April 19, 2023
ketone, confused, with, ketone, bodies, organic, chemistry, ketone, functional, group, with, structure, where, variety, carbon, containing, substituents, contain, carbonyl, group, which, contains, carbon, oxygen, double, bond, simplest, ketone, acetone, where,. Not to be confused with ketone bodies In organic chemistry a ketone ˈ k iː t oʊ n is a functional group with the structure R C O R where R and R can be a variety of carbon containing substituents Ketones contain a carbonyl group C O which contains a carbon oxygen double bond C O The simplest ketone is acetone where R and R is methyl with the formula CH3 2CO Many ketones are of great importance in biology and in industry Examples include many sugars ketoses many steroids e g testosterone and the solvent acetone 1 Ketone Acetone Contents 1 Nomenclature and etymology 2 Structure and properties 2 1 Classes of ketones 2 1 1 Diketones 2 1 2 Unsaturated ketones 2 1 3 Cyclic ketones 2 2 Keto enol tautomerization 2 3 Acid base properties of ketones 3 Characterization 3 1 Spectroscopy 3 2 Qualitative organic tests 4 Synthesis 5 Reactions 6 Biochemistry 7 Applications 8 Toxicity 9 See also 10 References 11 External linksNomenclature and etymology EditThe word ketone is derived from Aketon an old German word for acetone 2 3 According to the rules of IUPAC nomenclature ketone names are derived by changing the suffix ane of the parent alkane to anone Typically the position of the carbonyl group is denoted by a number but traditional nonsystematic names are still generally used for the most important ketones for example acetone and benzophenone These nonsystematic names are considered retained IUPAC names 4 although some introductory chemistry textbooks use systematic names such as 2 propanone or propan 2 one for the simplest ketone CH3 C O CH3 instead of acetone The derived names of ketones are obtained by writing separately the names of the two alkyl groups attached to the carbonyl group followed by ketone as a separate word Traditionally the names of the alkyl groups were written in order of increasing complexity for example methyl ethyl ketone However according to the rules of IUPAC nomenclature the alkyl groups are written alphabetically for example ethyl methyl ketone When the two alkyl groups are the same the prefix di is added before the name of alkyl group The positions of other groups are indicated by Greek letters the a carbon being the atom adjacent to carbonyl group Although used infrequently oxo is the IUPAC nomenclature for the oxo group O and used as prefix when the ketone does not have the highest priority Other prefixes however are also used For some common chemicals mainly in biochemistry keto refer to the ketone functional group Structure and properties Edit Representative ketones from the left acetone a common solvent oxaloacetate an intermediate in the metabolism of sugars acetylacetone in its mono enol form the enol highlighted in blue cyclohexanone precursor to nylon muscone an animal scent and tetracycline an antibiotic The ketone carbon is often described as sp2 hybridized a description that includes both their electronic and molecular structure Ketones are trigonal planar around the ketonic carbon with C C O and C C C bond angles of approximately 120 Ketones differ from aldehydes in that the carbonyl group C O is bonded to two carbons within a carbon skeleton In aldehydes the carbonyl is bonded to one carbon and one hydrogen and are located at the ends of carbon chains Ketones are also distinct from other carbonyl containing functional groups such as carboxylic acids esters and amides 5 The carbonyl group is polar because the electronegativity of the oxygen is greater than that for carbon Thus ketones are nucleophilic at oxygen and electrophilic at carbon Because the carbonyl group interacts with water by hydrogen bonding ketones are typically more soluble in water than the related methylene compounds Ketones are hydrogen bond acceptors Ketones are not usually hydrogen bond donors and cannot hydrogen bond to themselves Because of their inability to serve both as hydrogen bond donors and acceptors ketones tend not to self associate and are more volatile than alcohols and carboxylic acids of comparable molecular weights These factors relate to the pervasiveness of ketones in perfumery and as solvents Classes of ketones Edit Ketones are classified on the basis of their substituents One broad classification subdivides ketones into symmetrical and unsymmetrical derivatives depending on the equivalency of the two organic substituents attached to the carbonyl center Acetone and benzophenone C6H5 2CO are symmetrical ketones Acetophenone C6H5C O CH3 is an unsymmetrical ketone Diketones Edit Main article dicarbonyl Many kinds of diketones are known some with unusual properties The simplest is diacetyl CH3C O C O CH3 once used as butter flavoring in popcorn Acetylacetone pentane 2 4 dione is virtually a misnomer inappropriate name because this species exists mainly as the monoenol CH3C O CH C OH CH3 Its enolate is a common ligand in coordination chemistry Unsaturated ketones Edit Ketones containing alkene and alkyne units are often called unsaturated ketones The most widely used member of this class of compounds is methyl vinyl ketone CH3C O CH CH2 which is useful in the Robinson annulation reaction Lest there be confusion a ketone itself is a site of unsaturation that is it can be hydrogenated Cyclic ketones Edit Many ketones are cyclic The simplest class have the formula CH2 nCO where n varies from 2 for cyclopropanone CH2 2CO to the tens Larger derivatives exist Cyclohexanone CH2 5CO a symmetrical cyclic ketone is an important intermediate in the production of nylon Isophorone derived from acetone is an unsaturated asymmetrical ketone that is the precursor to other polymers Muscone 3 methylpentadecanone is an animal pheromone Another cyclic ketone is cyclobutanone having the formula CH2 3CO Keto enol tautomerization Edit Main article Enol Keto enol tautomerism 1 is the keto form 2 is the enol Ketones that have at least one alpha hydrogen undergo keto enol tautomerization the tautomer is an enol Tautomerization is catalyzed by both acids and bases Usually the keto form is more stable than the enol This equilibrium allows ketones to be prepared via the hydration of alkynes Acid base properties of ketones Edit C H bonds adjacent to the carbonyl in ketones are more acidic pKa 20 than the C H bonds in alkane pKa 50 This difference reflects resonance stabilization of the enolate ion that is formed upon deprotonation The relative acidity of the a hydrogen is important in the enolization reactions of ketones and other carbonyl compounds The acidity of the a hydrogen also allows ketones and other carbonyl compounds to react as nucleophiles at that position with either stoichiometric and catalytic base Using very strong bases like lithium diisopropylamide LDA pKa of conjugate acid 36 under non equilibrating conditions 78 C 1 1 equiv LDA in THF ketone added to base the less substituted kinetic enolate is generated selectively while conditions that allow for equilibration higher temperature base added to ketone using weak or insoluble bases e g CH3CH2ONa in CH3CH2OH or NaH provides the more substituted thermodynamic enolate Ketones are also weak bases undergoing protonation on the carbonyl oxygen in the presence of Bronsted acids Ketonium ions i e protonated ketones are strong acids with pKa values estimated to be somewhere between 5 and 7 6 7 Although acids encountered in organic chemistry are seldom strong enough to fully protonate ketones the formation of equilibrium concentrations of protonated ketones is nevertheless an important step in the mechanisms of many common organic reactions like the formation of an acetal for example Acids as weak as pyridinium cation as found in pyridinium tosylate with a pKa of 5 2 are able to serve as catalysts in this context despite the highly unfavorable equilibrium constant for protonation Keq lt 10 10 Characterization EditAn aldehyde differs from a ketone in that it has a hydrogen atom attached to its carbonyl group making aldehydes easier to oxidize Ketones do not have a hydrogen atom bonded to the carbonyl group and are therefore more resistant to oxidation They are oxidized only by powerful oxidizing agents which have the ability to cleave carbon carbon bonds Spectroscopy Edit Ketones and aldehydes absorb strongly in the infra red spectrum near 1700 cm 1 The exact position of the peak depends on the substituents Whereas 1H NMR spectroscopy is generally not useful for establishing the presence of a ketone 13C NMR spectra exhibit signals somewhat downfield of 200 ppm depending on structure Such signals are typically weak due to the absence of nuclear Overhauser effects Since aldehydes resonate at similar chemical shifts multiple resonance experiments are employed to definitively distinguish aldehydes and ketones Qualitative organic tests Edit Ketones give positive results in Brady s test the reaction with 2 4 dinitrophenylhydrazine to give the corresponding hydrazone Ketones may be distinguished from aldehydes by giving a negative result with Tollens reagent or with Fehling s solution Methyl ketones give positive results for the iodoform test 8 Ketones also give positive results when treated with m dinitrobenzene in presence of dilute sodium hydroxide to give violet coloration Synthesis EditMany methods exist for the preparation of ketones in industrial scale and academic laboratories Ketones are also produced in various ways by organisms see the section on biochemistry below In industry the most important method probably involves oxidation of hydrocarbons often with air For example a billion kilograms of cyclohexanone are produced annually by aerobic oxidation of cyclohexane Acetone is prepared by air oxidation of cumene For specialized or small scale organic synthetic applications ketones are often prepared by oxidation of secondary alcohols R2CH OH O R2C O H2OTypical strong oxidants source of O in the above reaction include potassium permanganate or a Cr VI compound Milder conditions make use of the Dess Martin periodinane or the Moffatt Swern methods Many other methods have been developed examples include 9 By geminal halide hydrolysis 10 By hydration of alkynes 11 Such processes occur via enols and require the presence of an acid and mercury II sulfate HgSO4 Subsequent enol keto tautomerization gives a ketone This reaction always produces a ketone even with a terminal alkyne the only exception being the hydration of acetylene which produces acetaldehyde From Weinreb Amides using stoichiometric organometallic reagents Aromatic ketones can be prepared in the Friedel Crafts acylation 12 the related Houben Hoesch reaction 13 and the Fries rearrangement 11 Ozonolysis and related dihydroxylation oxidative sequences cleave alkenes to give aldehydes or ketones depending on alkene substitution pattern 14 In the Kornblum DeLaMare rearrangement ketones are prepared from peroxides and base In the Ruzicka cyclization cyclic ketones are prepared from dicarboxylic acids In the Nef reaction ketones form by hydrolysis of salts of secondary nitro compounds 15 In the Fukuyama coupling ketones form from a thioester and an organozinc compound By the reaction of an acid chloride with organocadmium compounds or organocopper compounds The Dakin West reaction provides an efficient method for preparation of certain methyl ketones from carboxylic acids 16 Ketones can also be prepared by the reaction of Grignard reagents with nitriles followed by hydrolysis 17 By decarboxylation of carboxylic anhydride Ketones can be prepared from haloketones in reductive dehalogenation of halo ketones In ketonic decarboxylation symmetrical ketones are prepared from carboxylic acids 11 18 Oxidation of amines with iron III chloride 19 Hydrolysis of unsaturated secondary amides 20 b Keto acid esters 11 or b diketones Acid catalysed rearrangement of 1 2 diols 11 Reactions Edit The Haller Bauer reaction occurs between a non enolizable ketone and a strong amide base In this prototypical example involving benzophenone the tetrahedral intermediate expels phenyl anion to give benzamide and benzene as the organic products Ketones engage in many organic reactions The most important reactions follow from the susceptibility of the carbonyl carbon toward nucleophilic addition and the tendency for the enolates to add to electrophiles Nucleophilic additions include in approximate order of their generality 9 With water hydration gives geminal diols which are usually not formed in appreciable or observable amounts With an acetylide to give the a hydroxyalkyne With ammonia or a primary amine gives an imine With secondary amine gives an enamine With Grignard and organolithium reagents to give after aqueous workup a tertiary alcohol With an alcohols or alkoxides to gives the hemiketal or its conjugate base With a diol to the ketal This reaction is employed to protect ketones With sodium amide resulting in C C bond cleavage with formation of the amide RCONH2 and the alkane or arene R H a reaction called the Haller Bauer reaction 21 With strong oxidizing agents to give carboxylic acids Ketones are generally oxidized under vigorous conditions i e strong oxidizing agents and at elevated temperatures Their oxidation involves carbon carbon bond cleavage to afford a mixture of carboxylic acids having lesser number of carbon atoms than the parent ketone Electrophilic addition reaction with an electrophile gives a resonance stabilized cation With phosphonium ylides in the Wittig reaction to give the alkenes With thiols to give the thioacetal With hydrazine or 1 disubstituted derivatives of hydrazine to give hydrazones With a metal hydride gives a metal alkoxide salt hydrolysis of which gives the alcohol an example of ketone reduction With halogens to form an a haloketone a reaction that proceeds via an enol see Haloform reaction With heavy water to give an a deuterated ketone Fragmentation in photochemical Norrish reaction Reaction of 1 4 aminodiketones to oxazoles by dehydration in the Robinson Gabriel synthesis In the case of aryl alkyl ketones with sulfur and an amine give amides in the Willgerodt reaction With hydroxylamine to produce oximes With reducing agents to form secondary alcohols With peroxy acids to form esters in the Baeyer Villiger oxidationBiochemistry EditSee also Coenzyme Q10 and Polyketide Ketones are pervasive in nature The formation of organic compounds in photosynthesis occurs via the ketone ribulose 1 5 bisphosphate Many sugars are ketones known collectively as ketoses The best known ketose is fructose it mostly exists as a cyclic hemiketal which masks the ketone functional group Fatty acid synthesis proceeds via ketones Acetoacetate is an intermediate in the Krebs cycle which releases energy from sugars and carbohydrates 22 In medicine acetone acetoacetate and beta hydroxybutyrate are collectively called ketone bodies generated from carbohydrates fatty acids and amino acids in most vertebrates including humans Ketone bodies are elevated in the blood ketosis after fasting including a night of sleep in both blood and urine in starvation in hypoglycemia due to causes other than hyperinsulinism in various inborn errors of metabolism and intentionally induced via a ketogenic diet and in ketoacidosis usually due to diabetes mellitus Although ketoacidosis is characteristic of decompensated or untreated type 1 diabetes ketosis or even ketoacidosis can occur in type 2 diabetes in some circumstances as well Applications EditKetones are produced on massive scales in industry as solvents polymer precursors and pharmaceuticals In terms of scale the most important ketones are acetone methylethyl ketone and cyclohexanone 23 They are also common in biochemistry but less so than in organic chemistry in general The combustion of hydrocarbons is an uncontrolled oxidation process that gives ketones as well as many other types of compounds Toxicity EditAlthough it is difficult to generalize on the toxicity of such a broad class of compounds simple ketones are in general not highly toxic This characteristic is one reason for their popularity as solvents Exceptions to this rule are the unsaturated ketones such as methyl vinyl ketone with LD50 of 7 mg kg oral 23 See also EditDiketone Ketone bodies Thioketone Triketone Ynone KetosisReferences Edit Raymond Kenneth W 2010 General Organic and Biological Chemistry 3rd ed Wiley p 297 Harper Douglas ketone Online Etymology Dictionary The word ketone was coined in 1848 by the German chemist Leopold Gmelin See Leopold Gmelin ed Handbuch der organischen Chemie Organische Chemie im Allgemeinen Handbook of organic chemistry Organic chemistry in general 4th ed Heidelberg Germany Karl Winter 1848 volume 1 p 40 From page 40 Zu diesen Syndesmiden scheinen auch diejenigen Verbindungen zu gehoren die alsAcetone im Allegemeinen Ketone bezeichnet werden To these syndesmides those compounds also seem to belong which are designated as acetones in general ketones Note In 1844 the French chemist Auguste Laurent suggested a new nomenclature for organic compounds One of his new classes of compounds was syndesmides which were compounds formed by the combination of two or more simpler organic molecules from the Greek syndesmos syndesmos union ide indicating a group of related compounds For example acetone could be formed by the dry distillation of metal acetates so acetone was the syndesmide of two acetate ions See Laurent Auguste 1844 Classification chimique Comptes rendus 19 1089 1100 see especially p 1097 List of retained IUPAC names retained IUPAC names Link McMurry John E 1992 Organic Chemistry 3rd ed Belmont Wadsworth ISBN 0 534 16218 5 Evans David A 4 November 2005 Evans pKa table PDF Evans group website Retrieved 14 June 2018 Smith Michael B 2013 March s Advanced Organic Chemistry 7th ed Hoboken N J Wiley pp 314 315 ISBN 978 0 470 46259 1 Mendham J Denney R C Barnes J D Thomas M J K 2000 Vogel s Quantitative Chemical Analysis 6th ed New York Prentice Hall ISBN 0 582 22628 7 a b Smith Michael B March Jerry 2007 Advanced Organic Chemistry Reactions Mechanisms and Structure 6th ed New York Wiley Interscience ISBN 978 0 471 72091 1 Marvel C S Sperry W M 1928 Benzophenone Organic Syntheses 8 26 doi 10 15227 orgsyn 008 0026 a b c d e Furniss Brian Hannaford Antony Smith Peter Tatchell Austin 1996 Vogel s Textbook of Practical Organic Chemistry 5th ed London Longman Science amp Technical pp 612 623 976 977 982 983 ISBN 9780582462366 Allen C F H Barker W E 1932 Desoxybenzoin Organic Syntheses 12 16 doi 10 15227 orgsyn 012 0016 Gulati K C Seth S R Venkataraman K 1935 Phloroacetophenone Organic Syntheses 15 70 doi 10 15227 orgsyn 015 0070 Tietze Lutz F Bratz Matthias 1993 Dialkyl Mesoxalates by Ozonolysis of Dialkyl Benzalmalonates Dimethyl Mesoxalate Organic Syntheses 71 214 doi 10 15227 orgsyn 071 0214 Heinzelman R V 1955 o Methoxyphenylacetone Organic Syntheses 35 74 doi 10 15227 orgsyn 035 0074 Wiley Richard H Borum O H 1953 3 Acetamido 2 butanone Organic Syntheses 33 1 doi 10 15227 orgsyn 033 0001 Moffett R B Shriner R L 1941 w Methoxyacetophenone Organic Syntheses 21 79 doi 10 15227 orgsyn 021 0079 Thorpe J F Kon G A R 1925 Cyclopentanone Organic Syntheses 5 37 doi 10 15227 orgsyn 005 0037 Fieser Louis F 1937 1 2 Naphthoquinone Organic Syntheses 17 68 doi 10 15227 orgsyn 017 0068 Herbst R M Shemin D 1939 Phenylpyruvic acid Organic Syntheses 19 77 doi 10 15227 orgsyn 019 0077 Haller Bauer Reaction homeip net Nelson D L Cox M M 2000 Lehninger Principles of Biochemistry 3rd Ed Worth Publishing New York ISBN 1 57259 153 6 a b Siegel Hardo Eggersdorfer Manfred 2000 Ketones Ullmann s Encyclopedia of Industrial Chemistry doi 10 1002 14356007 a15077 inactive 31 December 2022 ISBN 9783527306732 a href Template Cite book html title Template Cite book cite book a CS1 maint DOI inactive as of December 2022 link External links Edit Wikiquote has quotations related to Ketone Media related to Ketones at Wikimedia Commons Retrieved from https en wikipedia org w index php title Ketone amp oldid 1141398571, wikipedia, 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