This article is about the group of organic compounds. For the synthetic rubber product, see Nitrile rubber.
The structure of a nitrile: the functional group is highlighted blue.

A nitrile is any organic compound that has a −CN functional group.[1] The prefix cyano- is used interchangeably with the term nitrile in industrial literature. Nitriles are found in many useful compounds, including methyl cyanoacrylate, used in super glue, and nitrile rubber, a nitrile-containing polymer used in the latex-free laboratory and medical gloves. Nitrile rubber is also widely used as automotive and other seals since it is resistant to fuels and oils. Organic compounds containing multiple nitrile groups are known as cyanocarbons.

Inorganic compounds containing the −C≡N group are not called nitriles, but cyanides instead.[2] Though both nitriles and cyanides can be derived from cyanide salts, most nitriles are not nearly as toxic.

Structure and basic properties

The N−C−C geometry is linear in nitriles, reflecting the sp hybridization of the triply bonded carbon. The C−N distance is short at 1.16 Å, consistent with a triple bond.[3] Nitriles are polar, as indicated by high dipole moments. As liquids, they have high dielectric constants, often in the 30s.


The first compound of the homolog row of nitriles, the nitrile of formic acid, hydrogen cyanide was first synthesized by C. W. Scheele in 1782.[4][5] In 1811 J. L. Gay-Lussac was able to prepare the very toxic and volatile pure acid.[6] The nitrile of benzoic acids was first prepared by Friedrich Wöhler and Justus von Liebig, but due to minimal yield of the synthesis neither physical nor chemical properties were determined nor a structure suggested. Théophile-Jules Pelouze synthesized propionitrile in 1834 suggesting it to be an ether of propionic alcohol and hydrocyanic acid.[7] The synthesis of benzonitrile by Hermann Fehling in 1844, by heating ammonium benzoate, was the first method yielding enough of the substance for chemical research. He determined the structure by comparing it to the already known synthesis of hydrogen cyanide by heating ammonium formate to his results. He coined the name "nitrile" for the newfound substance, which became the name for this group of compounds.[8]


Industrially, the main methods for producing nitriles are ammoxidation and hydrocyanation. Both routes are green in the sense that they do not generate stoichiometric amounts of salts.


In ammoxidation, a hydrocarbon is partially oxidized in the presence of ammonia. This conversion is practiced on a large scale for acrylonitrile:[9]

CH3CH=CH2 + 32 O2 + NH3 → NCCH=CH2 + 3 H2O

In the production of acrylonitrile, a side product is acetonitrile. Most derivatives of benzonitrile, phthalonitrile, as well as Isobutyronitrile are prepared by ammoxidation. The process is catalysed by metal oxides and is assumed to proceed via the aldehyde.


Hydrocyanation is an industrial method for producing nitriles from hydrogen cyanide and alkenes. The process requires homogeneous catalysts. An example of hydrocyanation is the production of adiponitrile, a precursor to nylon-6,6 from 1,3-butadiene:

CH2=CH−CH=CH2 + 2 HCN → NC(CH2)4CN

From organic halides and cyanide salts

Often for more specialty applications, nitriles can be prepared by a wide variety of other methods. For example, alkyl halides undergo nucleophilic aliphatic substitution with alkali metal cyanides in the Kolbe nitrile synthesis. Aryl nitriles are prepared in the Rosenmund-von Braun synthesis.


The cyanohydrins are a special class of nitriles that result from the addition of metal cyanides to aldehydes in the cyanohydrin reaction. Because of the polarity of the organic carbonyl, this reaction requires no catalyst, unlike the hydrocyanation of alkenes.

Dehydration of amides and oximes

Nitriles can be prepared by the dehydration of primary amides. Many reagents are available, the combination of ethyl dichlorophosphate and DBU just one of them in this conversion of benzamide to benzonitrile:[10]

Two intermediates in this reaction are amide tautomer A and its phosphate adduct B.

In a related dehydration, secondary amides give nitriles by the von Braun amide degradation. In this case, one C-N bond is cleaved. The dehydration of aldoximes (RCH=NOH) also affords nitriles. Typical reagents for this transformation are triethylamine/sulfur dioxide, zeolites, or sulfuryl chloride. Exploiting this approach is the One-pot synthesis of nitriles from aldehyde with hydroxylamine in the presence of sodium sulfate.[11]

Sandmeyer reaction

Aromatic nitriles are often prepared in the laboratory from the aniline via diazonium compounds. This is the Sandmeyer reaction. It requires transition metal cyanides.[12]

+ CuCN → ArCN + N2 + Cu+

Other methods

In the so-called Franchimont Reaction (which was developed by the Belgian doctoral student Antoine Paul Nicolas Franchimont (1844-1919) in 1872) an α-bromocarboxylic acid is dimerized after hydrolysis of the cyanogroup and decarboxylation[16]


Nitrile groups in organic compounds can undergo a variety of reactions depending on the reactants or conditions. A nitrile group can be hydrolyzed, reduced, or ejected from a molecule as a cyanide ion.


The hydrolysis of nitriles RCN proceeds in the distinct steps under acid or base treatment to achieve carboxamides RC(=O)NH2 and then carboxylic acids RCOOH. The hydrolysis of nitriles to carboxylic acids is efficient. When conducted with base or acids, the reactions cogenerate salts, which can be problematic.

The kinetic studies show that the second-order rate constant for hydroxide-ion catalyzed hydrolysis of acetonitrile to acetamide is 1.6 × 10−6, which is slower than the hydrolysis of the amide to the carboxylate (7.4 × 10−5 M−1 s−1). Thus, the base hydrolysis route will afford amides contaminated with the carboxylate. The acid catalyzed reactions requires a careful control of the temperature and of the ratio of reagents in order to avoid the formation of polymers, which is promoted by the exothermic character of the hydrolysis.[24] The mechanism is depicted in the enlisted link.


Main article: Nitrile reduction

Nitriles are susceptible to hydrogenation over diverse metal catalysts. The reaction can afford either the primary amine (RCH2NH2) or the tertiary amine ((RCH2)3N), depending on conditions.[25] In conventional organic reductions, nitrile is reduced by treatment with lithium aluminium hydride to the amine. Reduction to the imine followed by hydrolysis to the aldehyde takes place in the Stephen aldehyde synthesis, which uses stannous chloride in acid.


Alkyl nitriles are sufficiently acidic to form nitrile anions, which alkylate a wide variety of electrophiles.[26] Key to the exceptional nucleophilicity is the small steric demand of the CN unit combined with its inductive stabilization. These features make nitriles ideal for creating new carbon-carbon bonds in sterically demanding environments for use in syntheses of medicinal chemistry. Recent developments have shown that the nature of the metal counter-ion causes different coordination to either the nitrile nitrogen or the adjacent nucleophilic carbon, often with profound differences in reactivity and stereochemistry.[27]


The carbon center of a nitrile is electrophilic, hence it is susceptible to nucleophilic addition reactions:

Miscellaneous methods and compounds

Nitrile derivatives

Organic cyanamides

Cyanamides are N-cyano compounds with general structure R1R2N−CN and related to the inorganic parent cyanamide. For an example see: von Braun reaction.

Nitrile oxides

Nitrile oxides have the general structure R−CNO.

Occurrence and applications

Nitriles occur naturally in a diverse set of plant and animal sources. Over 120 naturally occurring nitriles have been isolated from terrestrial and marine sources. Nitriles are commonly encountered in fruit pits, especially almonds, and during cooking of Brassica crops (such as cabbage, brussel sprouts, and cauliflower), which release nitriles through hydrolysis. Mandelonitrile, a cyanohydrin produced by ingesting almonds or some fruit pits, releases hydrogen cyanide and is responsible for the toxicity of cyanogenic glycosides.[32]

Over 30 nitrile-containing pharmaceuticals are currently marketed for a diverse variety of medicinal indications with more than 20 additional nitrile-containing leads in clinical development. The nitrile group is quite robust and, in most cases, is not readily metabolized but passes through the body unchanged. The types of pharmaceuticals containing nitriles are diverse, from vildagliptin, an antidiabetic drug, to anastrozole, which is the gold standard in treating breast cancer. In many instances the nitrile mimics functionality present in substrates for enzymes, whereas in other cases the nitrile increases water solubility or decreases susceptibility to oxidative metabolism in the liver.[33] The nitrile functional group is found in several drugs.

See also


  1. IUPAC Gold Book nitriles
  2. NCBI-MeSH Nitriles
  3. Karakida, Ken-ichi, Tsutomu Fukuyama, and Kozo Kuchitsu. "Molecular Structures of Hydrogen Cyanide and Acetonitrile as Studied by Gas Electron Diffraction" Bulletin of the Chemical Society of Japan 1974, vol. 47, pp. 299-304.
  4. See:
    • Carl W. Scheele (1782) "Försök, beträffande det färgande ämnet uti Berlinerblå" (Experiment concerning the colored substance in Berlin blue), Kungliga Svenska Vetenskapsakademiens handlingar (Royal Swedish Academy of Science's Proceedings), 3: 264–275 (in Swedish).
    • Reprinted in Latin as: "De materia tingente caerulei berolinensis" in: Carl Wilhelm Scheele with Ernst Benjamin Gottlieb Hebenstreit (ed.) and Gottfried Heinrich Schäfer (trans.), Opuscula Chemica et Physica (Leipzig ("Lipsiae"), (Germany): Johann Godfried Müller, 1789), vol. 2, pages 148–174.
  5. David T. Mowry (1948). "The Preparation of Nitriles" (– Scholar search). Chemical Reviews. 42 (2): 189–283. doi:10.1021/cr60132a001. PMID 18914000.
  6. Gay-Lussac produced pure, liquified hydrogen cyanide in: Gay-Lussac (1811) "Note sur l'acide prussique" (Note on prussic acid), Annales de chimie, 44: 128 – 133.
  7. J. Pelouze (1834). "Notiz über einen neuen Cyanäther" [Note on a new cyano-ether]. Annalen der Pharmacie. 10 (3): 249. doi:10.1002/jlac.18340100302.
  8. Hermann Fehling (1844). "Ueber die Zersetzung des benzoësauren Ammoniaks durch die Wärme (On the decomposition of ammonium benzoate by heat)". Annalen der Chemie und Pharmacie. 49 (1): 91–97. doi:10.1002/jlac.18440490106. On page 96, Fehling writes: "Da Laurent den von ihm entdeckten Körper schon Nitrobenzoyl genannt hat, auch schon ein Azobenzoyl existirt, so könnte man den aus benzoësaurem Ammoniak entstehenden Körper vielleicht Benzonitril nennen." (Since Laurent named the substance that was discovered by him "nitrobenzoyl" – also an "azobenzoyl" already exists – so one could name the substance that originates from ammonium benzoate perhaps "benzonitril".)
  9. Peter Pollak, Gérard Romeder, Ferdinand Hagedorn, Heinz-Peter Gelbke "Nitriles" Ullmann's Encyclopedia of Industrial Chemistry 2002, Wiley-VCH, Weinheim. doi:10.1002/14356007.a17_363
  10. Chun-Wei Kuo, Jia-Liang Zhu, Jen-Dar Wu, Cheng-Ming Chu, Ching-Fa Yao and Kak-Shan Shia (2007). "A convenient new procedure for converting primary amides into nitriles". Chem. Commun. 2007 (3): 301–303. doi:10.1039/b614061k. PMID 17299646.
  11. Sharwan K, Dewan, Ravinder Singh, and Anil Kumar (2006). "One pot synthesis of nitriles from aldehydes and hydroxylamine hydrochloride using sodium sulfate (anhyd) and sodium bicarbonate in dry media under microwave irradiation" (open access). Arkivoc: (ii) 41–44.
  12. "o-Tolunitrile and p-Tolunitrile" H. T. Clarke and R. R. Read Org. Synth. 1941, Coll. Vol. 1, 514.
  13. W. Nagata and M. Yoshioka (1988). "Diethylaluminum cyanide". Org. Synth.; Coll. Vol., 6, p. 436
  14. W. Nagata, M. Yoshioka, and M. Murakami (1988). "Preparation of cyano compounds using alkylaluminum intermediates: 1-cyano-6-methoxy-3,4-dihydronaphthalene". Org. Synth.; Coll. Vol., 6, p. 307
  15. Reynold C. Fuson; Oscar R. Kreimeier & Gilbert L. Nimmo (1930). "Ring Closures in the Cyclobutane Series. II. Cyclization Of α,α′-Dibromo-Adipic Esters". J. Am. Chem. Soc. 52 (10): 4074–4076. doi:10.1021/ja01373a046.
  16. A. P. N. Franchimont (1872). "Ueber die Dibenzyldicarbonsäure" [On 2,3-diphenylsuccinic acid]. Berichte der deutschen chemischen Gesellschaft. 5: 1048–1050.
  17. J. Houben, Walter Fischer (1930) "Über eine neue Methode zur Darstellung cyclischer Nitrile durch katalytischen Abbau (I. Mitteil.)," Berichte der deutschen chemischen Gesellschaft (A and B Series) 63 (9): 2464 – 2472. doi:10.1002/cber.19300630920
  18. Yamazaki, Shigekazu; Yamazaki, Yasuyuki (1990). "Nickel-catalyzed dehydrogenation of amines to nitriles". Bulletin of the Chemical Society of Japan. 63 (1): 301–303. doi:10.1246/bcsj.63.301.
  19. Chen, Fen-Er; Kuang, Yun-Yan; Hui-Fang, Dai; Lu, Liang (2003). "A Selective and Mild Oxidation of Primary Amines to Nitriles with Trichloroisocyanuric Acid". Synthesis. 17: 2629–2631. doi:10.1055/s-2003-42431.
  20. Schäfer, H. J.; Feldhues, U. (1982). "Oxidation of Primary Aliphatic Amines to Nitriles at the Nickel Hydroxide Electrode". Synthesis. 2: 145–146. doi:10.1055/s-1982-29721.
  21. Hiegel, Gene; Lewis, Justin; Bae, Jason (2004). "Conversion of α‐Amino Acids into Nitriles by Oxidative Decarboxylation with Trichloroisocyanuric Acid". Synthetic Communications. 34 (19): 3449–3453. doi:10.1081/SCC-200030958.
  22. Hampson, N; Lee, J; MacDonald, K (1972). "The oxidation of amino compounds at anodic silver". Electrochimica Acta. 17 (5): 921–955. doi:10.1016/0013-4686(72)90014-X.
  23. Dakin, Henry Drysdale (1916). "The Oxidation of Amino-Acids to Cyanides". Biochemical Journal. 10 (2): 319–323. PMC 1258710Freely accessible. PMID 16742643.
  24. Kukushkin, V. Yu.; Pombeiro, A. J. L. (2005). "Metal-mediated and metal-catalyzed hydrolysis of nitriles". Inorg. Chim. Acta. 358: 1–21.
  25. Barrault, J.; Pouilloux, Y. (1997). "Catalytic Amination Reactions: Synthesis of fatty amines. Selectivity control in presence of multifunctional catalysts". Catalysis Today. 1997: 137–153. doi:10.1016/S0920-5861(97)00006-0.
  26. Adams, Roger (1957). Organic Reactions, Volume 9. New York: John Wiley & Sons, Inc. ISBN 9780471007265. Retrieved 18 July 2014.
  27. Tetrahedron. 61 (4): 747–789. 24 January 2005. doi:10.1016/j.tet.2004.11.012. Missing or empty |title= (help)
  28. Smith, Andri L.; Tan, Paula (2006). "Creatine Synthesis: An Undergraduate Organic Chemistry Laboratory Experiment". J. Chem. Educ. 83 (11): 1654. Bibcode:2006JChEd..83.1654S. doi:10.1021/ed083p1654.
  29. 1 2 The reductive decyanation reaction: chemical methods and synthetic applications Jean-Marc Mattalia, Caroline Marchi-Delapierre, Hassan Hazimeh, and Michel Chanon Arkivoc (AL-1755FR) pp 90–118 2006 Article
  30. Berkoff, Charles E.; Rivard, Donald E.; Kirkpatrick, David; Ives, Jeffrey L. (1980). "The Reductive Decyanation of Nitriles by Alkali Fusion". Synthetic Communications. 10 (12): 939–945. doi:10.1080/00397918008061855.
  31. Yoshiaki Nakao; Akira Yada; Shiro Ebata & Tamejiro Hiyama (2007). "A Dramatic Effect of Lewis-Acid Catalysts on Nickel-Catalyzed Carbocyanation of Alkynes". J. Am. Chem. Soc. (Communication). 129 (9): 2428–2429. doi:10.1021/ja067364x. PMID 17295484.
  32. Natural Product Reports Issue 5, 1999 Nitrile-containing natural products
  33. Fleming, Fraser F.; Yao, Lihua; Ravikumar, P. C.; Funk, Lee; Shook, Brian C. (November 2010). "Nitrile-containing pharmaceuticals: efficacious roles of the nitrile pharmacophore". J Med Chem. 53 (22): 7902–17. doi:10.1021/jm100762r. PMC 2988972Freely accessible. PMID 20804202.
This article is issued from Wikipedia - version of the 10/5/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.