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Dicarboxylic acid

January 01, 1970

In organic chemistry, a dicarboxylic acid is an organic compound containing two carboxyl groups (−COOH). The general molecular formula for dicarboxylic acids can be written as HO2C−R−CO2H, where R can be aliphatic or aromatic. In general, dicarboxylic acids show similar chemical behavior and reactivity to monocarboxylic acids.

Dicarboxylic acids are used in the preparation of copolymers such as polyamides and polyesters. The most widely used dicarboxylic acid in the industry is adipic acid, which is a precursor in the production of nylon. Other examples of dicarboxylic acids include aspartic acid and glutamic acid, two amino acids in the human body. The name can be abbreviated to diacid.

Linear and cyclic saturated dicarboxylic acids edit

The general formula for acyclic dicarboxylic acid is HO
2C(CH
2)
nCO
2H.[1] The PubChem links gives access to more information on the compounds, including other names, ids, toxicity and safety.

Acids from the two-carbon oxalic acid to the ten-member sebacic acid may be remembered using the mnemonic 'Oh My Son, Go And Pray Softly And Silently', and also 'Oh my! Such great Apple Pie, sweet as sugar!'.

n Common name Systematic IUPAC name Structure pKa1 pKa2 PubChem
0 Oxalic acid ethanedioic acid   1.27 4.27 971
1 Malonic acid propanedioic acid   2.85 5.05 867
2 Succinic acid butanedioic acid   4.21 5.41 1110
3 Glutaric acid pentanedioic acid   4.34 5.41 743
4 Adipic acid hexanedioic acid   4.41 5.41 196
5 Pimelic acid heptanedioic acid   4.50 5.43 385
6 Suberic acid octanedioic acid   4.526 5.498 10457
6 1,4-Cyclohexanedicarboxylic acid   14106
7 Azelaic acid nonanedioic acid   4.550 5.498 2266
8 Sebacic acid decanedioic acid   4.720 5.450 5192
9 undecanedioic acid   15816
10 dodecanedioic acid   12736
11 Brassylic acid tridecanedioic acid   10458
14 Thapsic acid hexadecanedioic acid   10459
19 Japanic acid heneicosanedioic acid 9543668
20 Phellogenic acid docosanedioic acid   244872
28 Equisetolic acid triacontanedioic acid 5322010

Occurrence edit

  • Adipic acid, despite its name (in Latin, adipis means fat), is not a normal constituent of natural lipids but is a product of oxidative rancidity. It was first obtained by oxidation of castor oil (ricinoleic acid) with nitric acid. It is now produced industrially by oxidation of cyclohexanol or cyclohexane, mainly for the production of Nylon 6-6. It has several other industrial uses in the production of adhesives, plasticizers, gelatinizing agents, hydraulic fluids, lubricants, emollients, polyurethane foams, leather tanning, urethane and also as an acidulant in foods.
  • Pimelic acid (Greek pimelh, fat) was also first isolated from oxidized oil. Derivatives of pimelic acid are involved in the biosynthesis of lysine.
  • Suberic acid was first produced by nitric acid oxidation of cork (Latin suber). This acid is also produced when castor oil is oxidised. Suberic acid is used in the manufacture of alkyd resins and in the synthesis of polyamides (nylon variants).
  • Azelaic acid's name stems from the action of nitric acid (azote, nitrogen, or azotic, nitric) oxidation of oleic acid or elaidic acid. It was detected among products of rancid fats. Its origin explains for its presence in poorly preserved samples of linseed oil and in specimens of ointment removed from Egyptian tombs 5000 years old. Azelaic acid was prepared by oxidation of oleic acid with potassium permanganate, but now by oxidative cleavage of oleic acid with chromic acid or by ozonolysis. Azelaic acid is used, as simple esters or branched-chain esters) in the manufacture of plasticizers (for vinyl chloride resins, rubber), lubricants and greases. Azelaic acid is now used in cosmetics (treatment of acne). It displays bacteriostatic and bactericidal properties against a variety of aerobic and anaerobic micro-organisms present on acne-bearing skin. . Azelaic acid was identified as a molecule that accumulated at elevated levels in some parts of plants and was shown to be able to enhance the resistance of plants to infections.[2]
  • Sebacic acid, named from sebum (tallow). Thenard isolated this compound from distillation products of beef tallow in 1802. It is produced industrially by alkali fission of castor oil.[3] Sebacic acid and its derivatives have a variety of industrial uses as plasticizers, lubricants, diffusion pump oils, cosmetics, candles, etc. It is also used in the synthesis of polyamide, as nylon, and of alkyd resins. An isomer, isosebacic acid, has several applications in the manufacture of vinyl resin plasticizers, extrusion plastics, adhesives, ester lubricants, polyesters, polyurethane resins and synthetic rubber.
  • Brassylic acid can be produced from erucic acid by ozonolysis,[4] but also by microorganisms (Candida sp.) from tridecane. This diacid is produced on a small commercial scale in Japan for the manufacture of fragrances.[5]
  • Dodecanedioic acid is used in the production of nylon (nylon-6,12), polyamides, coatings, adhesives, greases, polyesters, dyestuffs, detergents, flame retardants, and fragrances. It is now produced by fermentation of long-chain alkanes with a specific strain of Candida tropicalis.[5] Traumatic acid is its monounsaturated counterpart.
  • Thapsic acid was isolated from the dried roots of the Mediterranean "deadly carrot", Thapsia garganica (Apiaceae).

Japan wax is a mixture containing triglycerides of C21, C22 and C23 dicarboxylic acids obtained from the sumac tree (Rhus sp.).

A large survey of the dicarboxylic acids present in Mediterranean nuts revealed unusual components.[6] A total of 26 minor acids (from 2 in pecan to 8% in peanut) were determined: 8 species derived from succinic acid, likely in relation with photosynthesis, and 18 species with a chain from 5 to 22 carbon atoms. Higher weight acids (>C20) are found in suberin present at vegetal surfaces (outer bark, root epidermis). C16 to C26 a, ω-dioic acids are considered as diagnostic for suberin. With C18:1 and C18:2, their content amount from 24 to 45% of whole suberin. They are present at low levels (< 5%) in plant cutin, except in Arabidopsis thaliana where their content can be higher than 50%.[7]

It was shown that hyperthermophilic microorganisms specifically contained a large variety of dicarboxylic acids.[8] This is probably the most important difference between these microorganisms and other marine bacteria. Dioic fatty acids from C16 to C22 were found in an hyperthermophilic archaeon, Pyrococcus furiosus. Short and medium chain (up to 11 carbon atoms) dioic acids have been discovered in Cyanobacteria of the genus Aphanizomenon.[9]

Dicarboxylic acids may be produced by ω-oxidation of fatty acids during their catabolism. It was discovered that these compounds appeared in urine after administration of tricaprin and triundecylin. Although the significance of their biosynthesis remains poorly understood, it was demonstrated that ω-oxidation occurs in rat liver but at a low rate, needs oxygen, NADPH and cytochrome P450. It was later shown that this reaction is more important in starving or diabetic animals where 15% of palmitic acid is subjected to ω-oxidation and then tob-oxidation, this generates malonyl-coA which is further used in saturated fatty acid synthesis.[10] The determination of the dicarboxylic acids generated by permanganate-periodate oxidation of monoenoic fatty acids was useful to study the position of the double bond in the carbon chain.[11]

Branched-chain dicarboxylic acids edit

Long-chain dicarboxylic acids containing vicinal dimethyl branching near the centre of the carbon chain have been discovered in the genus Butyrivibrio, bacteria which participate in the digestion of cellulose in the rumen.[12] These fatty acids, named diabolic acids, have a chain length depending on the fatty acid used in the culture medium. The most abundant diabolic acid in Butyrivibrio had a 32-carbon chain length. Diabolic acids were also detected in the core lipids of the genus Thermotoga of the order Thermotogales, bacteria living in solfatara springs, deep-sea marine hydrothermal systems and high-temperature marine and continental oil fields.[13] It was shown that about 10% of their lipid fraction were symmetrical C30 to C34 diabolic acids. The C30 (13,14-dimethyloctacosanedioic acid) and C32 (15,16-dimethyltriacontanedioic acid) diabolic acids have been described in Thermotoga maritima.[14]

Some parent C29 to C32 diacids but with methyl groups on the carbons C-13 and C-16 have been isolated and characterized from the lipids of thermophilic anaerobic bacterium Thermoanaerobacter ethanolicus.[15] The most abundant diacid was the C30 a,ω-13,16-dimethyloctacosanedioic acid.

Biphytanic diacids are present in geological sediments and are considered as tracers of past anaerobic oxidation of methane.[16] Several forms without or with one or two pentacyclic rings have been detected in Cenozoic seep limestones. These lipids may be unrecognized metabolites from Archaea.

 
Crocetin

Crocetin is the core compound of crocins (crocetin glycosides) which are the main red pigments of the stigmas of saffron (Crocus sativus) and the fruits of gardenia (Gardenia jasminoides). Crocetin is a 20-carbon chain dicarboxylic acid which is a diterpenenoid and can be considered as a carotenoid. It was the first plant carotenoid to be recognized as early as 1818 while the history of saffron cultivation reaches back more than 3,000 years. The major active ingredient of saffron is the yellow pigment crocin 2 (three other derivatives with different glycosylations are known) containing a gentiobiose (disaccharide) group at each end of the molecule. A simple and specific HPLC-UV method has been developed to quantify the five major biologically active ingredients of saffron, namely the four crocins and crocetin.[17]

Unsaturated dicarboxylic acids edit

Main articles: Maleic acid and Fumaric acid
See also: Cis–trans isomerism and E-Z notation
Type Common name IUPAC name Isomer Structural formula PubChem
Monounsaturated Maleic acid (Z)-Butenedioic acid cis   444266
Fumaric acid (E)-Butenedioic acid trans   444972
Acetylenedicarboxylic acid But-2-ynedioic acid not applicable   371
Glutaconic acid (Z)-Pent-2-enedioic acid cis   5370328
(E)-Pent-2-enedioic acid trans   5280498
2-Decenedioic acid trans   6442613
Traumatic acid Dodec-2-enedioic acid trans   5283028
Diunsaturated Muconic acid (2E,4E)-Hexa-2,4-dienedioic acid trans,trans   5356793
(2Z,4E)-Hexa-2,4-dienedioic acid cis,trans   280518
(2Z,4Z)-Hexa-2,4-dienedioic acid cis,cis   5280518
Glutinic acid
(Allene-1,3-dicarboxylic acid)		 (RS)-Penta-2,3-dienedioic acid HO2CCH=C=CHCO2H 5242834
Branched Citraconic acid (2Z)-2-Methylbut-2-enedioic acid cis   643798
Mesaconic acid (2E)-2-Methyl-2-butenedioic acid trans   638129
Itaconic acid 2-Methylidenebutanedioic acid   811

Traumatic acid, was among the first biologically active molecules isolated from plant tissues. This dicarboxylic acid was shown to be a potent wound healing agent in plant that stimulates cell division near a wound site,[18] it derives from 18:2 or 18:3 fatty acid hydroperoxides after conversion into oxo- fatty acids.

trans,trans-Muconic acid is a metabolite of benzene in humans. The determination of its concentration in urine is therefore used as a biomarker of occupational or environmental exposure to benzene.[19][20]

Glutinic acid, a substituted allene, was isolated from Alnus glutinosa (Betulaceae).[21]

While polyunsaturated fatty acids are unusual in plant cuticles, a diunsaturated dicarboxylic acid has been reported as a component of the surface waxes or polyesters of some plant species. Thus, octadeca-c6,c9-diene-1,18-dioate, a derivative of linoleic acid, is present in Arabidopsis and Brassica napus cuticle.[22]

Alkylitaconates edit

 
Itaconic acid
PubChem 811

Several dicarboxylic acids having an alkyl side chain and an itaconate core have been isolated from lichens and fungi, itaconic acid (methylenesuccinic acid) being a metabolite produced by filamentous fungi. Among these compounds, several analogues, called chaetomellic acids with different chain lengths and degrees of unsaturation have been isolated from various species of the lichen Chaetomella. These molecules were shown to be valuable as basis for the development of anticancer drugs due to their strong farnesyltransferase inhibitory effects.[23]

A series of alkyl- and alkenyl-itaconates, known as ceriporic acids (Pub Chem 52921868), were found in cultures of a selective lignin-degrading fungus (white rot fungus), Ceriporiopsis subvermispora.[24][25] The absolute configuration of ceriporic acids, their stereoselective biosynthetic pathway and the diversity of their metabolites have been discussed in detail.[26]

Substituted dicarboxylic acids edit

Common name IUPAC name Structural formula PubChem
Tartronic acid 2-Hydroxypropanedioic acid   45
Mesoxalic acid Oxopropanedioic acid   10132
Malic acid Hydroxybutanedioic acid   525
Tartaric acid 2,3-Dihydroxybutanedioic acid   875
Oxaloacetic acid Oxobutanedioic acid   970
Aspartic acid 2-Aminobutanedioic acid   5960
dioxosuccinic acid dioxobutanedioic acid   82062
α-hydroxyGlutaric acid 2-hydroxypentanedioic acid   43
Arabinaric acid 2,3,4-Trihydroxypentanedioic acid 109475
Acetonedicarboxylic acid 3-Oxopentanedioic acid   68328
α-Ketoglutaric acid 2-Oxopentanedioic acid   51
Glutamic acid 2-Aminopentanedioic acid   611
Diaminopimelic acid (2R,6S)-2,6-Diaminoheptanedioic acid   865
Saccharic acid (2S,3S,4S,5R)-2,3,4,5-Tetrahydroxyhexanedioic acid   33037

Aromatic dicarboxylic acids edit

Common names IUPAC name Structure PubChem
Phthalic acid
o-phthalic acid		 Benzene-1,2-dicarboxylic acid   1017
Isophthalic acid
m-phthalic acid		 Benzene-1,3-dicarboxylic acid   8496
Terephthalic acid
p-phthalic acid		 Benzene-1,4-dicarboxylic acid   7489
Diphenic acid
Biphenyl-2,2′-dicarboxylic acid		 2-(2-Carboxyphenyl)benzoic acid   10210
2,6-Naphthalenedicarboxylic acid 2,6-Naphthalenedicarboxylic acid   14357

Terephthalic acid is a commodity chemical used in the manufacture of the polyester known by brand names such as PET, Terylene, Dacron and Lavsan.

Properties edit

Dicarboxylic acids are crystalline solids. Solubility in water and melting point of the α,ω- compounds progress in a series as the carbon chains become longer with alternating between odd and even numbers of carbon atoms, so that for even numbers of carbon atoms the melting point is higher than for the next in the series with an odd number.[27] These compounds are weak dibasic acids with pKa tending towards values of ca. 4.5 and 5.5 as the separation between the two carboxylate groups increases. Thus, in an aqueous solution at pH about 7, typical of biological systems, the Henderson–Hasselbalch equation indicates they exist predominantly as dicarboxylate anions.

The dicarboxylic acids, especially the small and linear ones, can be used as crosslinking reagents.[28] Dicarboxylic acids where the carboxylic groups are separated by none or one carbon atom decompose when they are heated to give off carbon dioxide and leave behind a monocarboxylic acid.[27]

Blanc's Rule says that heating a barium salt of a dicarboxylic acid, or dehydrating it with acetic anhydride will yield a cyclic acid anhydride if the carbon atoms bearing acid groups are in position 1 and (4 or 5). So succinic acid will yield succinic anhydride. For acids with carboxylic groups at position 1 and 6 this dehydration causes loss of carbon dioxide and water to form a cyclic ketone, for example, adipic acid will form cyclopentanone.[27]

Derivatives edit

As for monofunctional carboxylic acids, derivatives of the same types exist. However, there is the added complication that either one or two of the carboxylic groups could be altered. If only one is changed then the derivative is termed "acid", and if both ends are altered it is called "normal". These derivatives include salts, chlorides, esters, amides, and anhydrides. In the case of anhydrides or amides, two of the carboxyl groups can come together to form a cyclic compound, for example succinimide.[29]

See also edit

References edit

  1. ^ Boy Cornils, Peter Lappe "Dicarboxylic Acids, Aliphatic" in Ullmann's Encyclopedia of Industrial Chemistry 2014, Wiley-VCH, Weinheim. doi:10.1002/14356007.a08_523.pub3
  2. ^ Jung, Ho Won; Tschaplinski, Timothy J.; Wang, Lin; Glazebrook, Jane; Greenberg, Jean T. (2009). "Priming in Systemic Plant Immunity". Science. 324 (3 April 2009): 89–91. Bibcode:2009Sci...324...89W. doi:10.1126/science.1170025. PMID 19342588. S2CID 206518245.
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  6. ^ Dembitsky, Valery M; Goldshlag, Paulina; Srebnik, Morris (April 2002). "Occurrence of dicarboxylic (dioic) acids in some Mediterranean nuts". Food Chemistry. 76 (4): 469–473. doi:10.1016/S0308-8146(01)00308-9.
  7. ^ Pollard, Mike; Beisson, Fred; Ohlrogge, John B. (3 April 2009). "Building lipid barriers: biosynthesis of cutin and suberin". Trends in Plant Science. 13 (5): 89–91. doi:10.1016/j.tplants.2008.03.003. PMID 18440267.
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  10. ^ Wada, F.; Usami, M. (1997). "Studies on fatty acid ω-oxidation antiketogenic effect and gluconeogenicity of dicarboxylic acids". Biochimica et Biophysica Acta (BBA) - Lipids and Lipid Metabolism. 487 (2): 261–268. doi:10.1016/0005-2760(77)90002-9.
  11. ^ Longmuir, Kenneth J.; Rossi, Mary E.; Resele-Tiden, Christine (1987). "Determination of monoenoic fatty acid double bond position by permanganate-periodate oxidation followed by high-performance liquid chromatography of carboxylic acid phenacyl esters". Analytical Biochemistry. 167 (2): 213–221. doi:10.1016/0003-2697(87)90155-2. PMID 2831753.
  12. ^ Klein, RA; Hazlewood, GP; Kemp, P; Dawson, RM (1 December 1979). "A new series of long-chain dicarboxylic acids with vicinal dimethyl branching found as major components of the lipids of Butyrivibrio spp". The Biochemical Journal. 183 (3): 691–700. doi:10.1042/bj1830691. PMC 1161651. PMID 540040.
  13. ^ Huber, Robert; Langworthy, Thomas A.; König, Helmut; Thomm, Michael; Woese, Carl R.; Sleytr, Uwe B.; Stetter, Karl O. (May 1986). "Thermotoga maritima sp. nov. represents a new genus of unique extremely thermophilic eubacteria growing up to 90 °C". Archives of Microbiology. 144 (4): 324–333. doi:10.1007/BF00409880. S2CID 12709437.
  14. ^ Carballeira, NM; Reyes, M; Sostre, A; Huang, H; Verhagen, MF; Adams, MW (April 1997). "Unusual fatty acid compositions of the hyperthermophilic archaeon Pyrococcus furiosus and the bacterium Thermotoga maritima". Journal of Bacteriology. 179 (8): 2766–8. doi:10.1128/jb.179.8.2766-2768.1997. PMC 179030. PMID 9098079.
  15. ^ Jung, S; Zeikus, JG; Hollingsworth, RI (June 1994). "A new family of very long chain alpha,omega-dicarboxylic acids is a major structural fatty acyl component of the membrane lipids of Thermoanaerobacter ethanolicus 39E". Journal of Lipid Research. 35 (6): 1057–65. doi:10.1016/S0022-2275(20)40101-4. PMID 8077844.
  16. ^ Birgel, Daniel; Elvert, Marcus; Han, Xiqiu; Peckmann, Jörn (January 2008). "13C-depleted biphytanic diacids as tracers of past anaerobic oxidation of methane". Organic Geochemistry. 39 (1): 152–156. Bibcode:2008OrGeo..39..152B. doi:10.1016/j.orggeochem.2007.08.013.
  17. ^ Li, Na; Lin, Ge; Kwan, Yiu-Wa; Min, Zhi-Da (July 1999). "Simultaneous quantification of five major biologically active ingredients of saffron by high-performance liquid chromatography". Journal of Chromatography A. 849 (2): 349–355. doi:10.1016/S0021-9673(99)00600-7. PMID 10457433.
  18. ^ Farmer, Edward E. (1994). "Fatty acid signalling in plants and their associated microorganisms". Plant Molecular Biology. 26 (5): 1423–1437. doi:10.1007/BF00016483. PMID 7858198. S2CID 3712976.
  19. ^ Wiwanitkit V, Soogarun S, Suwansaksri J (2007). "A correlative study on red blood cell parameters and urine trans, trans-muconic acid in subjects with occupational benzene exposure". Toxicologic Pathology. 35 (2): 268–9. doi:10.1080/01926230601156278. PMID 17366320. S2CID 6392962.
  20. ^ Weaver VM, Davoli CT, Heller PJ, et al. (1996). "Benzene exposure, assessed by urinary trans,trans-muconic acid, in urban children with elevated blood lead levels". Environ. Health Perspect. 104 (3): 318–23. doi:10.2307/3432891. JSTOR 3432891. PMC 1469300. PMID 8919771.
  21. ^ Sati, Sushil Chandra; Sati, Nitin; Sati, O. P. (2011). "Bioactive constituents and medicinal importance of genus Alnus". Pharmacognosy Reviews. 5 (10): 174–183. doi:10.4103/0973-7847.91115. PMC 3263052. PMID 22279375.
  22. ^ Bonaventure, Gustavo; Ohlrogge, John; Pollard, Mike (2004). "Analysis of the aliphatic monomer composition of polyesters associated with Arabidopsis epidermis: occurrence of octadeca-cis-6, cis-9-diene-1,18-dioate as the major component". The Plant Journal. 40 (6): 920–930. doi:10.1111/j.1365-313X.2004.02258.x. PMID 15584957.
  23. ^ Singh, SB; Jayasuriya, H; Silverman, KC; Bonfiglio, CA; Williamson, JM; Lingham, RB (March 2000). "Efficient syntheses, human and yeast farnesyl-protein transferase inhibitory activities of chaetomellic acids and analogues". Bioorganic & Medicinal Chemistry. 8 (3): 571–80. doi:10.1016/S0968-0896(99)00312-0. PMID 10732974. – via ScienceDirect (Subscription may be required or content may be available in libraries.)
  24. ^ Enoki, Makiko; Watanabe, Takashi; Honda, Yoichi; Kuwahara, Masaaki (2000). "A Novel Fluorescent Dicarboxylic Acid, (Z)-1,7-Nonadecadiene-2,3-dicarboxylic Acid, Produced by White-Rot Fungus Ceriporiopsis subvermispora". Chemistry Letters. 29 (1): 54–55. doi:10.1246/cl.2000.54.
  25. ^ Amirta, Rudianto; Fujimori, Kenya; Shirai, Nobuaki; Honda, Yoichi; Watanabe, Takashi (December 2003). "Ceriporic acid C, a hexadecenylitaconate produced by a lignin-degrading fungus, Ceriporiopsis subvermispora". Chemistry and Physics of Lipids. 126 (2): 121–131. doi:10.1016/S0009-3084(03)00098-7. PMID 14623447.
  26. ^ Nishimura, Hiroshi; Murayama, Kyoko; Watanabe, Takahito; Honda, Yoichi; Watanabe, Takashi (June 2009). "Absolute configuration of ceriporic acids, the iron redox-silencing metabolites produced by a selective lignin-degrading fungus, Ceriporiopsis subvermispora". Chemistry and Physics of Lipids. 159 (2): 77–80. doi:10.1016/j.chemphyslip.2009.03.006. PMID 19477313.
  27. ^ a b c Schmidt, Julius (1955). Organic Chemistry. London: Oliver and Boyd. pp. 283–284.
  28. ^ Moghadas, Babak; Solouk, Atefeh; Sadeghi, Davoud (2020-08-24). "Development of chitosan membrane using non-toxic crosslinkers for potential wound dressing applications". Polymer Bulletin. 78 (9): 4919–4929. doi:10.1007/s00289-020-03352-8. ISSN 1436-2449. S2CID 221283821.
  29. ^ Bernthsen, A. (1922). Organic Chemistry. London: Blackie & Son. p. 242.

External links edit

  • Lipidomics gateway Structure Database Dicarboxylic acids
  • Dijkstra, Albert J. "Trivial names of fatty acids-Part 1". lipidlibrary.aocs.org. Retrieved 24 June 2019.

January 01, 1970
dicarboxylic, acid, organic, chemistry, dicarboxylic, acid, organic, compound, containing, carboxyl, groups, cooh, general, molecular, formula, dicarboxylic, acids, written, ho2c, co2h, where, aliphatic, aromatic, general, dicarboxylic, acids, show, similar, c. In organic chemistry a dicarboxylic acid is an organic compound containing two carboxyl groups COOH The general molecular formula for dicarboxylic acids can be written as HO2C R CO2H where R can be aliphatic or aromatic In general dicarboxylic acids show similar chemical behavior and reactivity to monocarboxylic acids Dicarboxylic acids are used in the preparation of copolymers such as polyamides and polyesters The most widely used dicarboxylic acid in the industry is adipic acid which is a precursor in the production of nylon Other examples of dicarboxylic acids include aspartic acid and glutamic acid two amino acids in the human body The name can be abbreviated to diacid Contents 1 Linear and cyclic saturated dicarboxylic acids 2 Occurrence 3 Branched chain dicarboxylic acids 4 Unsaturated dicarboxylic acids 4 1 Alkylitaconates 5 Substituted dicarboxylic acids 6 Aromatic dicarboxylic acids 7 Properties 8 Derivatives 9 See also 10 References 11 External linksLinear and cyclic saturated dicarboxylic acids editThe general formula for acyclic dicarboxylic acid is HO2 C CH2 n CO2 H 1 The PubChem links gives access to more information on the compounds including other names ids toxicity and safety Acids from the two carbon oxalic acid to the ten member sebacic acid may be remembered using the mnemonic Oh My Son Go And Pray Softly And Silently and also Oh my Such great Apple Pie sweet as sugar n Common name Systematic IUPAC name Structure pKa1 pKa2 PubChem 0 Oxalic acid ethanedioic acid nbsp 1 27 4 27 971 1 Malonic acid propanedioic acid nbsp 2 85 5 05 867 2 Succinic acid butanedioic acid nbsp 4 21 5 41 1110 3 Glutaric acid pentanedioic acid nbsp 4 34 5 41 743 4 Adipic acid hexanedioic acid nbsp 4 41 5 41 196 5 Pimelic acid heptanedioic acid nbsp 4 50 5 43 385 6 Suberic acid octanedioic acid nbsp 4 526 5 498 10457 6 1 4 Cyclohexanedicarboxylic acid nbsp 14106 7 Azelaic acid nonanedioic acid nbsp 4 550 5 498 2266 8 Sebacic acid decanedioic acid nbsp 4 720 5 450 5192 9 undecanedioic acid nbsp 15816 10 dodecanedioic acid nbsp 12736 11 Brassylic acid tridecanedioic acid nbsp 10458 14 Thapsic acid hexadecanedioic acid nbsp 10459 19 Japanic acid heneicosanedioic acid 9543668 20 Phellogenic acid docosanedioic acid nbsp 244872 28 Equisetolic acid triacontanedioic acid 5322010Occurrence editAdipic acid despite its name in Latin adipis means fat is not a normal constituent of natural lipids but is a product of oxidative rancidity It was first obtained by oxidation of castor oil ricinoleic acid with nitric acid It is now produced industrially by oxidation of cyclohexanol or cyclohexane mainly for the production of Nylon 6 6 It has several other industrial uses in the production of adhesives plasticizers gelatinizing agents hydraulic fluids lubricants emollients polyurethane foams leather tanning urethane and also as an acidulant in foods Pimelic acid Greek pimelh fat was also first isolated from oxidized oil Derivatives of pimelic acid are involved in the biosynthesis of lysine Suberic acid was first produced by nitric acid oxidation of cork Latin suber This acid is also produced when castor oil is oxidised Suberic acid is used in the manufacture of alkyd resins and in the synthesis of polyamides nylon variants Azelaic acid s name stems from the action of nitric acid azote nitrogen or azotic nitric oxidation of oleic acid or elaidic acid It was detected among products of rancid fats Its origin explains for its presence in poorly preserved samples of linseed oil and in specimens of ointment removed from Egyptian tombs 5000 years old Azelaic acid was prepared by oxidation of oleic acid with potassium permanganate but now by oxidative cleavage of oleic acid with chromic acid or by ozonolysis Azelaic acid is used as simple esters or branched chain esters in the manufacture of plasticizers for vinyl chloride resins rubber lubricants and greases Azelaic acid is now used in cosmetics treatment of acne It displays bacteriostatic and bactericidal properties against a variety of aerobic and anaerobic micro organisms present on acne bearing skin Azelaic acid was identified as a molecule that accumulated at elevated levels in some parts of plants and was shown to be able to enhance the resistance of plants to infections 2 Sebacic acid named from sebum tallow Thenard isolated this compound from distillation products of beef tallow in 1802 It is produced industrially by alkali fission of castor oil 3 Sebacic acid and its derivatives have a variety of industrial uses as plasticizers lubricants diffusion pump oils cosmetics candles etc It is also used in the synthesis of polyamide as nylon and of alkyd resins An isomer isosebacic acid has several applications in the manufacture of vinyl resin plasticizers extrusion plastics adhesives ester lubricants polyesters polyurethane resins and synthetic rubber Brassylic acid can be produced from erucic acid by ozonolysis 4 but also by microorganisms Candida sp from tridecane This diacid is produced on a small commercial scale in Japan for the manufacture of fragrances 5 Dodecanedioic acid is used in the production of nylon nylon 6 12 polyamides coatings adhesives greases polyesters dyestuffs detergents flame retardants and fragrances It is now produced by fermentation of long chain alkanes with a specific strain of Candida tropicalis 5 Traumatic acid is its monounsaturated counterpart Thapsic acid was isolated from the dried roots of the Mediterranean deadly carrot Thapsia garganica Apiaceae Japan wax is a mixture containing triglycerides of C21 C22 and C23 dicarboxylic acids obtained from the sumac tree Rhus sp A large survey of the dicarboxylic acids present in Mediterranean nuts revealed unusual components 6 A total of 26 minor acids from 2 in pecan to 8 in peanut were determined 8 species derived from succinic acid likely in relation with photosynthesis and 18 species with a chain from 5 to 22 carbon atoms Higher weight acids gt C20 are found in suberin present at vegetal surfaces outer bark root epidermis C16 to C26 a w dioic acids are considered as diagnostic for suberin With C18 1 and C18 2 their content amount from 24 to 45 of whole suberin They are present at low levels lt 5 in plant cutin except in Arabidopsis thaliana where their content can be higher than 50 7 It was shown that hyperthermophilic microorganisms specifically contained a large variety of dicarboxylic acids 8 This is probably the most important difference between these microorganisms and other marine bacteria Dioic fatty acids from C16 to C22 were found in an hyperthermophilic archaeon Pyrococcus furiosus Short and medium chain up to 11 carbon atoms dioic acids have been discovered in Cyanobacteria of the genus Aphanizomenon 9 Dicarboxylic acids may be produced by w oxidation of fatty acids during their catabolism It was discovered that these compounds appeared in urine after administration of tricaprin and triundecylin Although the significance of their biosynthesis remains poorly understood it was demonstrated that w oxidation occurs in rat liver but at a low rate needs oxygen NADPH and cytochrome P450 It was later shown that this reaction is more important in starving or diabetic animals where 15 of palmitic acid is subjected to w oxidation and then tob oxidation this generates malonyl coA which is further used in saturated fatty acid synthesis 10 The determination of the dicarboxylic acids generated by permanganate periodate oxidation of monoenoic fatty acids was useful to study the position of the double bond in the carbon chain 11 Branched chain dicarboxylic acids editLong chain dicarboxylic acids containing vicinal dimethyl branching near the centre of the carbon chain have been discovered in the genus Butyrivibrio bacteria which participate in the digestion of cellulose in the rumen 12 These fatty acids named diabolic acids have a chain length depending on the fatty acid used in the culture medium The most abundant diabolic acid in Butyrivibrio had a 32 carbon chain length Diabolic acids were also detected in the core lipids of the genus Thermotoga of the order Thermotogales bacteria living in solfatara springs deep sea marine hydrothermal systems and high temperature marine and continental oil fields 13 It was shown that about 10 of their lipid fraction were symmetrical C30 to C34 diabolic acids The C30 13 14 dimethyloctacosanedioic acid and C32 15 16 dimethyltriacontanedioic acid diabolic acids have been described in Thermotoga maritima 14 Some parent C29 to C32 diacids but with methyl groups on the carbons C 13 and C 16 have been isolated and characterized from the lipids of thermophilic anaerobic bacterium Thermoanaerobacter ethanolicus 15 The most abundant diacid was the C30 a w 13 16 dimethyloctacosanedioic acid Biphytanic diacids are present in geological sediments and are considered as tracers of past anaerobic oxidation of methane 16 Several forms without or with one or two pentacyclic rings have been detected in Cenozoic seep limestones These lipids may be unrecognized metabolites from Archaea nbsp Crocetin Crocetin is the core compound of crocins crocetin glycosides which are the main red pigments of the stigmas of saffron Crocus sativus and the fruits of gardenia Gardenia jasminoides Crocetin is a 20 carbon chain dicarboxylic acid which is a diterpenenoid and can be considered as a carotenoid It was the first plant carotenoid to be recognized as early as 1818 while the history of saffron cultivation reaches back more than 3 000 years The major active ingredient of saffron is the yellow pigment crocin 2 three other derivatives with different glycosylations are known containing a gentiobiose disaccharide group at each end of the molecule A simple and specific HPLC UV method has been developed to quantify the five major biologically active ingredients of saffron namely the four crocins and crocetin 17 Unsaturated dicarboxylic acids editMain articles Maleic acid and Fumaric acid See also Cis trans isomerism and E Z notation Type Common name IUPAC name Isomer Structural formula PubChem Monounsaturated Maleic acid Z Butenedioic acid cis nbsp 444266 Fumaric acid E Butenedioic acid trans nbsp 444972 Acetylenedicarboxylic acid But 2 ynedioic acid not applicable nbsp 371 Glutaconic acid Z Pent 2 enedioic acid cis nbsp 5370328 E Pent 2 enedioic acid trans nbsp 5280498 2 Decenedioic acid trans nbsp 6442613 Traumatic acid Dodec 2 enedioic acid trans nbsp 5283028 Diunsaturated Muconic acid 2E 4E Hexa 2 4 dienedioic acid trans trans nbsp 5356793 2Z 4E Hexa 2 4 dienedioic acid cis trans nbsp 280518 2Z 4Z Hexa 2 4 dienedioic acid cis cis nbsp 5280518 Glutinic acid Allene 1 3 dicarboxylic acid RS Penta 2 3 dienedioic acid HO2CCH C CHCO2H 5242834 Branched Citraconic acid 2Z 2 Methylbut 2 enedioic acid cis nbsp 643798 Mesaconic acid 2E 2 Methyl 2 butenedioic acid trans nbsp 638129 Itaconic acid 2 Methylidenebutanedioic acid nbsp 811 Traumatic acid was among the first biologically active molecules isolated from plant tissues This dicarboxylic acid was shown to be a potent wound healing agent in plant that stimulates cell division near a wound site 18 it derives from 18 2 or 18 3 fatty acid hydroperoxides after conversion into oxo fatty acids trans trans Muconic acid is a metabolite of benzene in humans The determination of its concentration in urine is therefore used as a biomarker of occupational or environmental exposure to benzene 19 20 Glutinic acid a substituted allene was isolated from Alnus glutinosa Betulaceae 21 While polyunsaturated fatty acids are unusual in plant cuticles a diunsaturated dicarboxylic acid has been reported as a component of the surface waxes or polyesters of some plant species Thus octadeca c6 c9 diene 1 18 dioate a derivative of linoleic acid is present in Arabidopsis and Brassica napus cuticle 22 Alkylitaconates edit nbsp Itaconic acidPubChem 811 Several dicarboxylic acids having an alkyl side chain and an itaconate core have been isolated from lichens and fungi itaconic acid methylenesuccinic acid being a metabolite produced by filamentous fungi Among these compounds several analogues called chaetomellic acids with different chain lengths and degrees of unsaturation have been isolated from various species of the lichen Chaetomella These molecules were shown to be valuable as basis for the development of anticancer drugs due to their strong farnesyltransferase inhibitory effects 23 A series of alkyl and alkenyl itaconates known as ceriporic acids Pub Chem 52921868 were found in cultures of a selective lignin degrading fungus white rot fungus Ceriporiopsis subvermispora 24 25 The absolute configuration of ceriporic acids their stereoselective biosynthetic pathway and the diversity of their metabolites have been discussed in detail 26 Substituted dicarboxylic acids editCommon name IUPAC name Structural formula PubChem Tartronic acid 2 Hydroxypropanedioic acid nbsp 45 Mesoxalic acid Oxopropanedioic acid nbsp 10132 Malic acid Hydroxybutanedioic acid nbsp 525 Tartaric acid 2 3 Dihydroxybutanedioic acid nbsp 875 Oxaloacetic acid Oxobutanedioic acid nbsp 970 Aspartic acid 2 Aminobutanedioic acid nbsp 5960 dioxosuccinic acid dioxobutanedioic acid nbsp 82062 a hydroxyGlutaric acid 2 hydroxypentanedioic acid nbsp 43 Arabinaric acid 2 3 4 Trihydroxypentanedioic acid 109475 Acetonedicarboxylic acid 3 Oxopentanedioic acid nbsp 68328 a Ketoglutaric acid 2 Oxopentanedioic acid nbsp 51 Glutamic acid 2 Aminopentanedioic acid nbsp 611 Diaminopimelic acid 2R 6S 2 6 Diaminoheptanedioic acid nbsp 865 Saccharic acid 2S 3S 4S 5R 2 3 4 5 Tetrahydroxyhexanedioic acid nbsp 33037Aromatic dicarboxylic acids editCommon names IUPAC name Structure PubChem Phthalic acido phthalic acid Benzene 1 2 dicarboxylic acid nbsp 1017 Isophthalic acidm phthalic acid Benzene 1 3 dicarboxylic acid nbsp 8496 Terephthalic acidp phthalic acid Benzene 1 4 dicarboxylic acid nbsp 7489 Diphenic acidBiphenyl 2 2 dicarboxylic acid 2 2 Carboxyphenyl benzoic acid nbsp 10210 2 6 Naphthalenedicarboxylic acid 2 6 Naphthalenedicarboxylic acid nbsp 14357 Terephthalic acid is a commodity chemical used in the manufacture of the polyester known by brand names such as PET Terylene Dacron and Lavsan Properties editDicarboxylic acids are crystalline solids Solubility in water and melting point of the a w compounds progress in a series as the carbon chains become longer with alternating between odd and even numbers of carbon atoms so that for even numbers of carbon atoms the melting point is higher than for the next in the series with an odd number 27 These compounds are weak dibasic acids with pKa tending towards values of ca 4 5 and 5 5 as the separation between the two carboxylate groups increases Thus in an aqueous solution at pH about 7 typical of biological systems the Henderson Hasselbalch equation indicates they exist predominantly as dicarboxylate anions The dicarboxylic acids especially the small and linear ones can be used as crosslinking reagents 28 Dicarboxylic acids where the carboxylic groups are separated by none or one carbon atom decompose when they are heated to give off carbon dioxide and leave behind a monocarboxylic acid 27 Blanc s Rule says that heating a barium salt of a dicarboxylic acid or dehydrating it with acetic anhydride will yield a cyclic acid anhydride if the carbon atoms bearing acid groups are in position 1 and 4 or 5 So succinic acid will yield succinic anhydride For acids with carboxylic groups at position 1 and 6 this dehydration causes loss of carbon dioxide and water to form a cyclic ketone for example adipic acid will form cyclopentanone 27 Derivatives editAs for monofunctional carboxylic acids derivatives of the same types exist However there is the added complication that either one or two of the carboxylic groups could be altered If only one is changed then the derivative is termed acid and if both ends are altered it is called normal These derivatives include salts chlorides esters amides and anhydrides In the case of anhydrides or amides two of the carboxyl groups can come together to form a cyclic compound for example succinimide 29 See also editTricarboxylic acidReferences edit Boy Cornils Peter Lappe Dicarboxylic Acids Aliphatic in Ullmann s Encyclopedia of Industrial Chemistry 2014 Wiley VCH Weinheim doi 10 1002 14356007 a08 523 pub3 Jung Ho Won Tschaplinski Timothy J Wang Lin Glazebrook Jane Greenberg Jean T 2009 Priming in Systemic Plant Immunity Science 324 3 April 2009 89 91 Bibcode 2009Sci 324 89W doi 10 1126 science 1170025 PMID 19342588 S2CID 206518245 Kadesch Richard G November 1954 Dibasic acids Journal of the American Oil Chemists Society 31 11 568 573 doi 10 1007 BF02638574 S2CID 189786702 Mascia P N Scheffran J Widholm J M 2010 Plant Biotechnology for Sustainable Production of Energy and co products Biotechnology in Agriculture and Forestry Springer Berlin Heidelberg p 231 ISBN 978 3 642 13440 1 Retrieved 18 May 2021 a b Kroha Kyle September 2004 Industrial biotechnology provides opportunities for commercial production of new long chain dibasic acids Inform 15 568 571 Dembitsky Valery M Goldshlag Paulina Srebnik Morris April 2002 Occurrence of dicarboxylic dioic acids in some Mediterranean nuts Food Chemistry 76 4 469 473 doi 10 1016 S0308 8146 01 00308 9 Pollard Mike Beisson Fred Ohlrogge John B 3 April 2009 Building lipid barriers biosynthesis of cutin and suberin Trends in Plant Science 13 5 89 91 doi 10 1016 j tplants 2008 03 003 PMID 18440267 Carballeira N M Reyes M Sostre A Huang H Verhagen M F Adams M W 2009 Unusual fatty acid compositions of the hyperthermophilic archaeon Pyrococcus furiosus and the bacterium Thermotoga maritima J Bacteriol 179 8 2766 2768 doi 10 1128 jb 179 8 2766 2768 1997 PMC 179030 PMID 9098079 Dembitsky V M Shkrob I Go J V 2001 Dicarboxylic and Fatty Acid Compositions of Cyanobacteria of the Genus Aphanizomenon Biochemistry Moscow 66 1 72 76 doi 10 1023 A 1002837830653 PMID 11240396 S2CID 34894138 Wada F Usami M 1997 Studies on fatty acid w oxidation antiketogenic effect and gluconeogenicity of dicarboxylic acids Biochimica et Biophysica Acta BBA Lipids and Lipid Metabolism 487 2 261 268 doi 10 1016 0005 2760 77 90002 9 Longmuir Kenneth J Rossi Mary E Resele Tiden Christine 1987 Determination of monoenoic fatty acid double bond position by permanganate periodate oxidation followed by high performance liquid chromatography of carboxylic acid phenacyl esters Analytical Biochemistry 167 2 213 221 doi 10 1016 0003 2697 87 90155 2 PMID 2831753 Klein RA Hazlewood GP Kemp P Dawson RM 1 December 1979 A new series of long chain dicarboxylic acids with vicinal dimethyl branching found as major components of the lipids of Butyrivibrio spp The Biochemical Journal 183 3 691 700 doi 10 1042 bj1830691 PMC 1161651 PMID 540040 Huber Robert Langworthy Thomas A Konig Helmut Thomm Michael Woese Carl R Sleytr Uwe B Stetter Karl O May 1986 Thermotoga maritima sp nov represents a new genus of unique extremely thermophilic eubacteria growing up to 90 C Archives of Microbiology 144 4 324 333 doi 10 1007 BF00409880 S2CID 12709437 Carballeira NM Reyes M Sostre A Huang H Verhagen MF Adams MW April 1997 Unusual fatty acid compositions of the hyperthermophilic archaeon Pyrococcus furiosus and the bacterium Thermotoga maritima Journal of Bacteriology 179 8 2766 8 doi 10 1128 jb 179 8 2766 2768 1997 PMC 179030 PMID 9098079 Jung S Zeikus JG Hollingsworth RI June 1994 A new family of very long chain alpha omega dicarboxylic acids is a major structural fatty acyl component of the membrane lipids of Thermoanaerobacter ethanolicus 39E Journal of Lipid Research 35 6 1057 65 doi 10 1016 S0022 2275 20 40101 4 PMID 8077844 Birgel Daniel Elvert Marcus Han Xiqiu Peckmann Jorn January 2008 13C depleted biphytanic diacids as tracers of past anaerobic oxidation of methane Organic Geochemistry 39 1 152 156 Bibcode 2008OrGeo 39 152B doi 10 1016 j orggeochem 2007 08 013 Li Na Lin Ge Kwan Yiu Wa Min Zhi Da July 1999 Simultaneous quantification of five major biologically active ingredients of saffron by high performance liquid chromatography Journal of Chromatography A 849 2 349 355 doi 10 1016 S0021 9673 99 00600 7 PMID 10457433 Farmer Edward E 1994 Fatty acid signalling in plants and their associated microorganisms Plant Molecular Biology 26 5 1423 1437 doi 10 1007 BF00016483 PMID 7858198 S2CID 3712976 Wiwanitkit V Soogarun S Suwansaksri J 2007 A correlative study on red blood cell parameters and urine trans trans muconic acid in subjects with occupational benzene exposure Toxicologic Pathology 35 2 268 9 doi 10 1080 01926230601156278 PMID 17366320 S2CID 6392962 Weaver VM Davoli CT Heller PJ et al 1996 Benzene exposure assessed by urinary trans trans muconic acid in urban children with elevated blood lead levels Environ Health Perspect 104 3 318 23 doi 10 2307 3432891 JSTOR 3432891 PMC 1469300 PMID 8919771 Sati Sushil Chandra Sati Nitin Sati O P 2011 Bioactive constituents and medicinal importance of genus Alnus Pharmacognosy Reviews 5 10 174 183 doi 10 4103 0973 7847 91115 PMC 3263052 PMID 22279375 Bonaventure Gustavo Ohlrogge John Pollard Mike 2004 Analysis of the aliphatic monomer composition of polyesters associated with Arabidopsis epidermis occurrence of octadeca cis 6 cis 9 diene 1 18 dioate as the major component The Plant Journal 40 6 920 930 doi 10 1111 j 1365 313X 2004 02258 x PMID 15584957 Singh SB Jayasuriya H Silverman KC Bonfiglio CA Williamson JM Lingham RB March 2000 Efficient syntheses human and yeast farnesyl protein transferase inhibitory activities of chaetomellic acids and analogues Bioorganic amp Medicinal Chemistry 8 3 571 80 doi 10 1016 S0968 0896 99 00312 0 PMID 10732974 via ScienceDirect Subscription may be required or content may be available in libraries Enoki Makiko Watanabe Takashi Honda Yoichi Kuwahara Masaaki 2000 A Novel Fluorescent Dicarboxylic Acid Z 1 7 Nonadecadiene 2 3 dicarboxylic Acid Produced by White Rot Fungus Ceriporiopsis subvermispora Chemistry Letters 29 1 54 55 doi 10 1246 cl 2000 54 Amirta Rudianto Fujimori Kenya Shirai Nobuaki Honda Yoichi Watanabe Takashi December 2003 Ceriporic acid C a hexadecenylitaconate produced by a lignin degrading fungus Ceriporiopsis subvermispora Chemistry and Physics of Lipids 126 2 121 131 doi 10 1016 S0009 3084 03 00098 7 PMID 14623447 Nishimura Hiroshi Murayama Kyoko Watanabe Takahito Honda Yoichi Watanabe Takashi June 2009 Absolute configuration of ceriporic acids the iron redox silencing metabolites produced by a selective lignin degrading fungus Ceriporiopsis subvermispora Chemistry and Physics of Lipids 159 2 77 80 doi 10 1016 j chemphyslip 2009 03 006 PMID 19477313 a b c Schmidt Julius 1955 Organic Chemistry London Oliver and Boyd pp 283 284 Moghadas Babak Solouk Atefeh Sadeghi Davoud 2020 08 24 Development of chitosan membrane using non toxic crosslinkers for potential wound dressing applications Polymer Bulletin 78 9 4919 4929 doi 10 1007 s00289 020 03352 8 ISSN 1436 2449 S2CID 221283821 Bernthsen A 1922 Organic Chemistry London Blackie amp Son p 242 External links editLipidomics gateway Structure Database Dicarboxylic acids Dijkstra Albert J Trivial names of fatty acids Part 1 lipidlibrary aocs org Retrieved 24 June 2019 Retrieved from https en wikipedia org w index php title Dicarboxylic acid amp oldid 1218579426, wikipedia, wiki, book, books, library,

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