fbpx
Wikipedia

Citric acid

February 16, 2024

"E330" redirects here. For the locomotive, see FS Class E330.

Citric acid is an organic compound with the chemical formula HOC(CO2H)(CH2CO2H)2.[9] It is a colorless weak organic acid.[9] It occurs naturally in citrus fruits. In biochemistry, it is an intermediate in the citric acid cycle, which occurs in the metabolism of all aerobic organisms.[9]

Citric acid
Stereo skeletal formula of citric acid
Ball-and-stick model of citric acid
Names
IUPAC name
Citric acid[1]
Preferred IUPAC name
2-Hydroxypropane-1,2,3-tricarboxylic acid[1]
Identifiers
  • 77-92-9 Y
3D model (JSmol)
  • Interactive image
ChEBI
  • CHEBI:30769 Y
ChEMBL
  • ChEMBL1261 Y
ChemSpider
  • 305 Y
DrugBank
  • DB04272 Y
ECHA InfoCard 100.000.973
EC Number
  • 201-069-1
E number E330 (antioxidants, ...)
  • 2478
KEGG
  • D00037 Y
  • 311
  • 22230 (monohydrate)
RTECS number
  • GE7350000
UNII
  • XF417D3PSL Y
  • DTXSID3020332
  • InChI=1S/C6H8O7/c7-3(8)1-6(13,5(11)12)2-4(9)10/h13H,1-2H2,(H,7,8)(H,9,10)(H,11,12) Y
    Key: KRKNYBCHXYNGOX-UHFFFAOYSA-N Y
  • InChI=1/C6H8O7/c7-3(8)1-6(13,5(11)12)2-4(9)10/h13H,1-2H2,(H,7,8)(H,9,10)(H,11,12)
    Key: KRKNYBCHXYNGOX-UHFFFAOYAM
  • OC(=O)CC(O)(C(=O)O)CC(=O)O
Properties
C6H8O7
Molar mass 192.123 g/mol (anhydrous), 210.14 g/mol (monohydrate)[2]
Appearance white solid
Odor Odorless
Density 1.665 g/cm3 (anhydrous)
1.542 g/cm3 (18 °C, monohydrate)
Melting point 156 °C (313 °F; 429 K)
Boiling point 310 °C (590 °F; 583 K) decomposes from 175 °C[3]
54% w/w (10 °C)
59.2% w/w (20 °C)
64.3% w/w (30 °C)
68.6% w/w (40 °C)
70.9% w/w (50 °C)
73.5% w/w (60 °C)
76.2% w/w (70 °C)
78.8% w/w (80 °C)
81.4% w/w (90 °C)
84% w/w (100 °C)[4]
Solubility Soluble in acetone, alcohol, ether, ethyl acetate, DMSO
Insoluble in C
6H
6, CHCl3, CS2, toluene[3]
Solubility in ethanol 62 g/100 g (25 °C)[3]
Solubility in amyl acetate 4.41 g/100 g (25 °C)[3]
Solubility in diethyl ether 1.05 g/100 g (25 °C)[3]
Solubility in 1,4-dioxane 35.9 g/100 g (25 °C)[3]
log P −1.64
Acidity (pKa) pKa1 = 3.13[5]
pKa2 = 4.76[5]
pKa3 = 6.39,[6] 6.40[7]
1.493–1.509 (20 °C)[4]
1.46 (150 °C)[3]
Viscosity 6.5 cP (50% aq. sol.)[4]
Structure
Monoclinic
Thermochemistry
226.51 J/(mol·K) (26.85 °C)[8]
252.1 J/(mol·K)[8]
−1543.8 kJ/mol[4]
1985.3 kJ/mol (474.5 kcal/mol, 2.47 kcal/g),[4] 1960.6 kJ/mol[8]
1972.34 kJ/mol (471.4 kcal/mol, 2.24 kcal/g) (monohydrate)[4]
Pharmacology
A09AB04 (WHO)
Hazards
Occupational safety and health (OHS/OSH):
Main hazards
 Skin and eye irritant
GHS labelling:
[5]
Warning
H290, H319, H315[5]
P305+P351+P338[5]
NFPA 704 (fire diamond)
Health 2: Intense or continued but not chronic exposure could cause temporary incapacitation or possible residual injury. E.g. chloroformFlammability 1: Must be pre-heated before ignition can occur. Flash point over 93 °C (200 °F). E.g. canola oilInstability 0: Normally stable, even under fire exposure conditions, and is not reactive with water. E.g. liquid nitrogenSpecial hazards (white): no code
2
1
0
Flash point 155 °C (311 °F; 428 K)
345 °C (653 °F; 618 K)
Explosive limits 8%[5]
Lethal dose or concentration (LD, LC):
3000 mg/kg (rats, oral)
Safety data sheet (SDS) HMDB
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
Y verify (what is YN ?)

More than two million tons of citric acid are manufactured every year. It is used widely as an acidifier, as a flavoring, and a chelating agent.[10]

A citrate is a derivative of citric acid; that is, the salts, esters, and the polyatomic anion found in solution. An example of the former, a salt is trisodium citrate; an ester is triethyl citrate. When part of a salt, the formula of the citrate anion is written as C
6H
5O3−
7 or C
3H
5O(COO)3−
3.

Natural occurrence and industrial production edit

 
Lemons, oranges, limes, and other citrus fruits contain high concentrations of citric acid.

Citric acid occurs in a variety of fruits and vegetables, most notably citrus fruits. Lemons and limes have particularly high concentrations of the acid; it can constitute as much as 8% of the dry weight of these fruits (about 47 g/L in the juices[11]).[a] The concentrations of citric acid in citrus fruits range from 0.005 mol/L for oranges and grapefruits to 0.30 mol/L in lemons and limes; these values vary within species depending upon the cultivar and the circumstances under which the fruit was grown.

Citric acid was first isolated in 1784 by the chemist Carl Wilhelm Scheele, who crystallized it from lemon juice.[12][13]

Industrial-scale citric acid production first began in 1890 based on the Italian citrus fruit industry, where the juice was treated with hydrated lime (calcium hydroxide) to precipitate calcium citrate, which was isolated and converted back to the acid using diluted sulfuric acid.[14] In 1893, C. Wehmer discovered Penicillium mold could produce citric acid from sugar.[15] However, microbial production of citric acid did not become industrially important until World War I disrupted Italian citrus exports.

In 1917, American food chemist James Currie discovered that certain strains of the mold Aspergillus niger could be efficient citric acid producers,[16] and the pharmaceutical company Pfizer began industrial-level production using this technique two years later, followed by Citrique Belge in 1929. In this production technique, which is still the major industrial route to citric acid used today, cultures of Aspergillus niger are fed on a sucrose or glucose-containing medium to produce citric acid. The source of sugar is corn steep liquor, molasses, hydrolyzed corn starch, or other inexpensive, carbohydrate solution.[17] After the mold is filtered out of the resulting suspension, citric acid is isolated by precipitating it with calcium hydroxide to yield calcium citrate salt, from which citric acid is regenerated by treatment with sulfuric acid, as in the direct extraction from citrus fruit juice.

In 1977, a patent was granted to Lever Brothers for the chemical synthesis of citric acid starting either from aconitic or isocitrate (also called alloisocitrate) calcium salts under high pressure conditions; this produced citric acid in near quantitative conversion under what appeared to be a reverse, non-enzymatic Krebs cycle reaction.[18]

Global production was in excess of 2,000,000 tons in 2018.[19] More than 50% of this volume was produced in China. More than 50% was used as an acidity regulator in beverages, some 20% in other food applications, 20% for detergent applications, and 10% for applications other than food, such as cosmetics, pharmaceuticals, and in the chemical industry.[14]

Chemical characteristics edit

 
Speciation diagram for a 10-millimolar solution of citric acid

Citric acid can be obtained as an anhydrous (water-free) form or as a monohydrate. The anhydrous form crystallizes from hot water, while the monohydrate forms when citric acid is crystallized from cold water. The monohydrate can be converted to the anhydrous form at about 78 °C. Citric acid also dissolves in absolute (anhydrous) ethanol (76 parts of citric acid per 100 parts of ethanol) at 15 °C. It decomposes with loss of carbon dioxide above about 175 °C.

Citric acid is a tribasic acid, with pKa values, extrapolated to zero ionic strength, of 3.128, 4.761, and 6.396 at 25 °C.[20] The pKa of the hydroxyl group has been found, by means of 13C NMR spectroscopy, to be 14.4.[21] The speciation diagram shows that solutions of citric acid are buffer solutions between about pH 2 and pH 8. In biological systems around pH 7, the two species present are the citrate ion and mono-hydrogen citrate ion. The SSC 20X hybridization buffer is an example in common use.[22][23] Tables compiled for biochemical studies are available.[24]

On the other hand, the pH of a 1 mM solution of citric acid will be about 3.2. The pH of fruit juices from citrus fruits like oranges and lemons depends on the citric acid concentration, with a higher concentration of citric acid resulting in a lower pH.

Acid salts of citric acid can be prepared by careful adjustment of the pH before crystallizing the compound. See, for example, sodium citrate.

The citrate ion forms complexes with metallic cations. The stability constants for the formation of these complexes are quite large because of the chelate effect. Consequently, it forms complexes even with alkali metal cations. However, when a chelate complex is formed using all three carboxylate groups, the chelate rings have 7 and 8 members, which are generally less stable thermodynamically than smaller chelate rings. In consequence, the hydroxyl group can be deprotonated, forming part of a more stable 5-membered ring, as in ammonium ferric citrate, (NH
4)
5Fe(C
6H
4O
7)
2·2H
2O.[25]

Citric acid can be esterified at one or more of its three carboxylic acid groups to form any of a variety of mono-, di-, tri-, and mixed esters.[26]

Biochemistry edit

Citric acid cycle edit

Main article: Citric acid cycle

Citrate is an intermediate in the citric acid cycle, also known as the TCA (TriCarboxylic Acid) cycle or the Krebs cycle, a central metabolic pathway for animals, plants, and bacteria. Citrate synthase catalyzes the condensation of oxaloacetate with acetyl CoA to form citrate. Citrate then acts as the substrate for aconitase and is converted into aconitic acid. The cycle ends with regeneration of oxaloacetate. This series of chemical reactions is the source of two-thirds of the food-derived energy in higher organisms. Hans Adolf Krebs received the 1953 Nobel Prize in Physiology or Medicine for the discovery.

Some bacteria (notably E. coli) can produce and consume citrate internally as part of their TCA cycle, but are unable to use it as food, because they lack the enzymes required to import it into the cell. After tens of thousands of evolutions in a minimal glucose medium that also contained citrate during Richard Lenski's Long-Term Evolution Experiment, a variant E. coli evolved with the ability to grow aerobically on citrate. Zachary Blount, a student of Lenski's, and colleagues studied these "Cit+" E. coli[27][28] as a model for how novel traits evolve. They found evidence that, in this case, the innovation was caused by a rare duplication mutation due to the accumulation of several prior "potentiating" mutations, the identity and effects of which are still under study. The evolution of the Cit+ trait has been considered a notable example of the role of historical contingency in evolution.

Other biological roles edit

Citrate can be transported out of the mitochondria and into the cytoplasm, then broken down into acetyl-CoA for fatty acid synthesis, and into oxaloacetate. Citrate is a positive modulator of this conversion, and allosterically regulates the enzyme acetyl-CoA carboxylase, which is the regulating enzyme in the conversion of acetyl-CoA into malonyl-CoA (the commitment step in fatty acid synthesis). In short, citrate is transported into the cytoplasm, converted into acetyl-CoA, which is then converted into malonyl-CoA by acetyl-CoA carboxylase, which is allosterically modulated by citrate.

High concentrations of cytosolic citrate can inhibit phosphofructokinase, the catalyst of a rate-limiting step of glycolysis. This effect is advantageous: high concentrations of citrate indicate that there is a large supply of biosynthetic precursor molecules, so there is no need for phosphofructokinase to continue to send molecules of its substrate, fructose 6-phosphate, into glycolysis. Citrate acts by augmenting the inhibitory effect of high concentrations of ATP, another sign that there is no need to carry out glycolysis.[29]

Citrate is a vital component of bone, helping to regulate the size of apatite crystals.[30]

Applications edit

Food and drink edit

 
Powdered citric acid being used to prepare lemon pepper seasoning

Because it is one of the stronger edible acids, the dominant use of citric acid is as a flavoring and preservative in food and beverages, especially soft drinks and candies.[14] Within the European Union it is denoted by E number E330. Citrate salts of various metals are used to deliver those minerals in a biologically available form in many dietary supplements. Citric acid has 247 kcal per 100 g.[31] In the United States the purity requirements for citric acid as a food additive are defined by the Food Chemicals Codex, which is published by the United States Pharmacopoeia (USP).

Citric acid can be added to ice cream as an emulsifying agent to keep fats from separating, to caramel to prevent sucrose crystallization, or in recipes in place of fresh lemon juice. Citric acid is used with sodium bicarbonate in a wide range of effervescent formulae, both for ingestion (e.g., powders and tablets) and for personal care (e.g., bath salts, bath bombs, and cleaning of grease). Citric acid sold in a dry powdered form is commonly sold in markets and groceries as "sour salt", due to its physical resemblance to table salt. It has use in culinary applications, as an alternative to vinegar or lemon juice, where a pure acid is needed. Citric acid can be used in food coloring to balance the pH level of a normally basic dye.[citation needed]

Cleaning and chelating agent edit

 
Structure of an iron(III) citrate complex[32][33]

Citric acid is an excellent chelating agent, binding metals by making them soluble. It is used to remove and discourage the buildup of limescale from boilers and evaporators.[14] It can be used to treat water, which makes it useful in improving the effectiveness of soaps and laundry detergents. By chelating the metals in hard water, it lets these cleaners produce foam and work better without need for water softening. Citric acid is the active ingredient in some bathroom and kitchen cleaning solutions. A solution with a six percent concentration of citric acid will remove hard water stains from glass without scrubbing. Citric acid can be used in shampoo to wash out wax and coloring from the hair. Illustrative of its chelating abilities, citric acid was the first successful eluant used for total ion-exchange separation of the lanthanides, during the Manhattan Project in the 1940s.[34] In the 1950s, it was replaced by the far more efficient[35] EDTA.

In industry, it is used to dissolve rust from steel, and to passivate stainless steels.[36]

Cosmetics, pharmaceuticals, dietary supplements, and foods edit

Citric acid is used as an acidulant in creams, gels, and liquids. Used in foods and dietary supplements, it may be classified as a processing aid if it was added for a technical or functional effect (e.g. acidulent, chelator, viscosifier, etc.). If it is still present in insignificant amounts, and the technical or functional effect is no longer present, it may be exempt from labeling <21 CFR §101.100(c)>.

Citric acid is an alpha hydroxy acid and is an active ingredient in chemical skin peels.[37]

Citric acid is commonly used as a buffer to increase the solubility of brown heroin.[38]

Citric acid is used as one of the active ingredients in the production of facial tissues with antiviral properties.[39]

Other uses edit

The buffering properties of citrates are used to control pH in household cleaners and pharmaceuticals.

Citric acid is used as an odorless alternative to white vinegar for fabric dyeing with acid dyes.

Sodium citrate is a component of Benedict's reagent, used for both qualitative and quantitative identification of reducing sugars.[40]

Citric acid can be used as an alternative to nitric acid in passivation of stainless steel.[41]

Citric acid can be used as a lower-odor stop bath as part of the process for developing photographic film. Photographic developers are alkaline, so a mild acid is used to neutralize and stop their action quickly, but commonly used acetic acid leaves a strong vinegar odor in the darkroom.[42]

Citric acid/potassium-sodium citrate can be used as a blood acid regulator. The citric acid is included to improve palatability[43]

Citric acid is an excellent soldering flux,[44] either dry or as a concentrated solution in water. It should be removed after soldering, especially with fine wires, as it is mildly corrosive. It dissolves and rinses quickly in hot water.

Alkali citrate can be used as an inhibitor of kidney stones by increasing urine citrate levels, useful for prevention of calcium stones, and increasing urine pH, useful for preventing uric acid and cystine stones.[45]

Synthesis of other organic compounds edit

Citric acid is a versatile precursor to many other organic compounds. Dehydration routes give itaconic acid and its anhydride.[46] Citraconic acid can be produced via thermal isomerization of itaconic acid anhydride.[47] The required itaconic acid anhydride is obtained by dry distillation of citric acid. Aconitic acid can be synthesized by dehydration of citric acid using sulfuric acid:[48]

(HO2CCH2)2C(OH)CO2H → HO2CCH=C(CO2H)CH2CO2H + H2O

Acetonedicarboxylic acid can also be prepared by decarboxylation of citric acid in fuming sulfuric acid.[49]

Safety edit

Although a weak acid, exposure to pure citric acid can cause adverse effects. Inhalation may cause cough, shortness of breath, or sore throat. Over-ingestion may cause abdominal pain and sore throat. Exposure of concentrated solutions to skin and eyes can cause redness and pain.[50] Long-term or repeated consumption may cause erosion of tooth enamel.[50][51][52]

Compendial status edit

See also edit

Explanatory notes edit

  1. ^ This still does not make the lemon particularly strongly acidic. This is because, as a weak acid, most of the acid molecules are not dissociated so not contributing to acidity inside the lemon or its juice.

References edit

  1. ^ a b International Union of Pure and Applied Chemistry (2014). Nomenclature of Organic Chemistry: IUPAC Recommendations and Preferred Names 2013. The Royal Society of Chemistry. p. 747. doi:10.1039/9781849733069. ISBN 978-0-85404-182-4.
  2. ^ CID 22230 from PubChem
  3. ^ a b c d e f g . chemister.ru. Archived from the original on November 29, 2014. Retrieved June 1, 2014.
  4. ^ a b c d e f CID 311 from PubChem
  5. ^ a b c d e f Fisher Scientific, Citric acid. Retrieved on 2014-06-02.
  6. ^ "Data for Biochemical Research". ZirChrom Separations, Inc. Retrieved January 11, 2012.
  7. ^ "Ionization Constants of Organic Acids". Michigan State University. Retrieved January 11, 2012.
  8. ^ a b c Citric acid in Linstrom, Peter J.; Mallard, William G. (eds.); NIST Chemistry WebBook, NIST Standard Reference Database Number 69, National Institute of Standards and Technology, Gaithersburg (MD) (retrieved 2014-06-02)
  9. ^ a b c . Archived from the original on January 19, 2022. Retrieved December 19, 2021.
  10. ^ Apleblat, Alexander (2014). Citric acid. Springer. ISBN 978-3-319-11232-9.
  11. ^ Penniston KL, Nakada SY, Holmes RP, Assimos DG (2008). "Quantitative Assessment of Citric Acid in Lemon Juice, Lime Juice, and Commercially-Available Fruit Juice Products". Journal of Endourology. 22 (3): 567–570. doi:10.1089/end.2007.0304. PMC 2637791. PMID 18290732.
  12. ^ Scheele, Carl Wilhelm (1784). "Anmärkning om Citron-saft, samt sätt at crystallisera densamma" [Note about lemon juice, as well as ways to crystallize it]. Kungliga Vetenskaps Academiens Nya Handlingar [New Proceedings of the Royal Academy of Science]. 2nd series (in Swedish). 5: 105–109.
  13. ^ Graham, Thomas (1842). Elements of chemistry, including the applications of the science in the arts. Hippolyte Baillière, foreign bookseller to the Royal College of Surgeons, and to the Royal Society, 219, Regent Street. p. 944. Retrieved June 4, 2010.
  14. ^ a b c d Verhoff, Frank H.; Bauweleers, Hugo (2014). "Citric Acid". Ullmann's Encyclopedia of Industrial Chemistry. Weinheim: Wiley-VCH. doi:10.1002/14356007.a07_103.pub3. ISBN 978-3527306732.
  15. ^ H. Benninga (June 30, 1990). A History of Lactic Acid Making: A Chapter in the History of Biotechnology. Springer Science & Business Media. pp. 140–5. ISBN 978-0-7923-0625-2.
  16. ^ Currie, James (1917). The Journal of Biological Chemistry. American Society for Biochemistry and Molecular Biology. pp. 15–27.
  17. ^ Lotfy, Walid A.; Ghanem, Khaled M.; El-Helow, Ehab R. (2007). "Citric acid production by a novel Aspergillus niger isolate: II. Optimization of process parameters through statistical experimental designs". Bioresource Technology. 98 (18): 3470–3477. doi:10.1016/j.biortech.2006.11.032. PMID 17317159.
  18. ^ US 4056567-V.Lamberti and E.Gutierrez
  19. ^ "Global Citric Acid Markets Report, 2011-2018 & 2019-2024". prnewswire.com. March 19, 2019. Retrieved October 28, 2019.
  20. ^ Goldberg, Robert N.; Kishore, Nand; Lennen, Rebecca M. (2002). "Thermodynamic Quantities for the Ionization Reactions of Buffers". J. Phys. Chem. Ref. Data. 31 (1): 231–370. Bibcode:2002JPCRD..31..231G. doi:10.1063/1.1416902. S2CID 94614267.
  21. ^ Silva, Andre M. N.; Kong, Xiaole; Hider, Robert C. (2009). "Determination of the pKa value of the hydroxyl group in the α-hydroxycarboxylates citrate, malate and lactate by 13C NMR: implications for metal coordination in biological systems". Biometals. 22 (5): 771–778. doi:10.1007/s10534-009-9224-5. PMID 19288211. S2CID 11615864.
  22. ^ "SSC - OpenWetWare".
  23. ^ Maniatis, T.; Fritsch, E. F.; Sambrook, J. 1982. Molecular Cloning: A Laboratory Manual. Cold Spring Harbor Laboratory, Cold Spring Harbor, NY.
  24. ^ Gomori, G. (1955). "16 Preparation of buffers for use in enzyme studies". Methods in Enzymology Volume 1. Vol. 1. pp. 138–146. doi:10.1016/0076-6879(55)01020-3. ISBN 9780121818012.
  25. ^ Matzapetakis, M.; Raptopoulou, C. P.; Tsohos, A.; Papaefthymiou, V.; Moon, S. N.; Salifoglou, A. (1998). "Synthesis, Spectroscopic and Structural Characterization of the First Mononuclear, Water Soluble Iron−Citrate Complex, (NH4)5Fe(C6H4O7)2·2H2O". J. Am. Chem. Soc. 120 (50): 13266–13267. doi:10.1021/ja9807035.
  26. ^ Bergeron, Raymond J.; Xin, Meiguo; Smith, Richard E.; Wollenweber, Markus; McManis, James S.; Ludin, Christian; Abboud, Khalil A. (1997). "Total synthesis of rhizoferrin, an iron chelator". Tetrahedron. 53 (2): 427–434. doi:10.1016/S0040-4020(96)01061-7.
  27. ^ Powell, Alvin (February 14, 2014). "59,000 generations of bacteria, plus freezer, yield startling results". phys.org. Retrieved April 13, 2017.
  28. ^ Blount, Z. D.; Borland, C. Z.; Lenski, R. E. (June 4, 2008). "Historical contingency and the evolution of a key innovation in an experimental population of Escherichia coli". Proceedings of the National Academy of Sciences. 105 (23): 7899–7906. Bibcode:2008PNAS..105.7899B. doi:10.1073/pnas.0803151105. PMC 2430337. PMID 18524956.
  29. ^ Stryer, Lubert; Berg, Jeremy; Tymoczko, John (2003). "Section 16.2: The Glycolytic Pathway Is Tightly Controlled". Biochemistry (5. ed., international ed., 3. printing ed.). New York: Freeman. ISBN 978-0716746843.
  30. ^ Hu, Y.-Y.; Rawal, A.; Schmidt-Rohr, K. (December 2010). "Strongly bound citrate stabilizes the apatite nanocrystals in bone". Proceedings of the National Academy of Sciences. 107 (52): 22425–22429. Bibcode:2010PNAS..10722425H. doi:10.1073/pnas.1009219107. PMC 3012505. PMID 21127269.
  31. ^ Greenfield, Heather; Southgate, D.A.T. (2003). Food Composition Data: Production, Management and Use. Rome: FAO. p. 146. ISBN 9789251049495.
  32. ^ Xiang Hao, Yongge Wei, Shiwei Zhang (2001): "Synthesis, crystal structure and magnetic property of a binuclear iron(III) citrate complex". Transition Metal Chemistry, volume 26, issue 4, pages 384–387. doi:10.1023/A:1011055306645
  33. ^ Shweky, Itzhak; Bino, Avi; Goldberg, David P.; Lippard, Stephen J. (1994). "Syntheses, Structures, and Magnetic Properties of Two Dinuclear Iron(III) Citrate Complexes". Inorganic Chemistry. 33 (23): 5161–5162. doi:10.1021/ic00101a001.
  34. ^ JOHNSON, WARREN C.; QUILL, LAURENCE L.; DANIELS, FARRINGTON (September 1, 1947). "Rare Earths Separation Developed on Manhattan Project". Chemical & Engineering News Archive. 25 (35): 2494. doi:10.1021/cen-v025n035.p2494. ISSN 0009-2347.
  35. ^ Saleem, Muhammad Hamzah; Ali, Shafaqat; Rehman, Muzammal; Rizwan, Muhammad; Kamran, Muhammad; Mohamed, Ibrahim A.A.; Khan, Zaid; Bamagoos, Atif A.; Alharby, Hesham F.; Hakeem, Khalid Rehman; Liu, Lijun (August 1, 2020). "Individual and combined application of EDTA and citric acid assisted phytoextraction of copper using jute (Corchorus capsularis L.) seedlings". Environmental Technology & Innovation. 19: 100895. doi:10.1016/j.eti.2020.100895. ISSN 2352-1864. S2CID 219432688.
  36. ^ "ASTM A967 / A967M - 17 Standard Specification for Chemical Passivation Treatments for Stainless Steel Parts". www.astm.org.
  37. ^ Tang, Sheau-Chung; Yang, Jen-Hung (April 10, 2018). "Dual Effects of Alpha-Hydroxy Acids on the Skin". Molecules. 23 (4): 863. doi:10.3390/molecules23040863. ISSN 1420-3049. PMC 6017965. PMID 29642579.
  38. ^ Strang J, Keaney F, Butterworth G, Noble A, Best D (April 2001). "Different forms of heroin and their relationship to cook-up techniques: data on, and explanation of, use of lemon juice and other acids". Subst Use Misuse. 36 (5): 573–88. doi:10.1081/ja-100103561. PMID 11419488. S2CID 8516420.
  39. ^ "Tissues that fight germs". CNN. July 14, 2004. Retrieved May 8, 2008.
  40. ^ Chen, Wei; Abramowitz, Matthew K. (February 2014). "Treatment of Metabolic Acidosis in Patients With CKD". American Journal of Kidney Diseases. 63 (2): 311–317. doi:10.1053/j.ajkd.2013.06.017. ISSN 0272-6386. PMC 3946919. PMID 23932089.
  41. ^ (PDF). Euro-inox.org. Archived from the original (PDF) on September 12, 2012. Retrieved 2013-01-01.
  42. ^ Anchell, Steve. "The Darkroom Cookbook: 3rd Edition (Paperback)". Focal Press. Retrieved January 1, 2013.
  43. ^ PubChem. "Sodium citrate". pubchem.ncbi.nlm.nih.gov. Retrieved August 2, 2021.
  44. ^ "An Investigation of the Chemistry of Citric Acid in Military Soldering Applications" (PDF). June 19, 1995. (PDF) from the original on March 15, 2020.
  45. ^ Berg, C.; Larsson, L.; Tiselius, H. G. (1992). "The effects of a single evening dose of alkaline citrate on urine composition and calcium stone formation". The Journal of Urology. 148 (3 Pt 2): 979–985. doi:10.1016/s0022-5347(17)36795-2. ISSN 0022-5347. PMID 1507355.
  46. ^ R. L. Shriner; S. G. Ford; l. J. Roll (1931). "Itaconic anhydride and itaconic acid". Org. Synth. 11: 70. doi:10.15227/orgsyn.011.0070.
  47. ^ R. L. Shriner; S. G. Ford; l. J. Roll (1931). "Citraconic Anhydride and Citraconic Acid". Org. Synth. 28: 28. doi:10.15227/orgsyn.011.0028.
  48. ^ Bruce, W. F. (1937). "Aconitic Acid". Organic Syntheses. 17: 1. doi:10.15227/orgsyn.017.0001.
  49. ^ Roger Adams; H. M. Chiles; C. F. Rassweiler (1925). "Acetonedicarboxylic Acid". Organic Syntheses. 5: 5. doi:10.15227/orgsyn.005.0005.
  50. ^ a b . International Chemical Safety Cards. NIOSH. September 18, 2018. Archived from the original on July 12, 2018. Retrieved September 9, 2017.
  51. ^ J. Zheng; F. Xiao; L. M. Qian; Z. R. Zhou (December 2009). "Erosion behavior of human tooth enamel in citric acid solution". Tribology International. 42 (11–12): 1558–1564. doi:10.1016/j.triboint.2008.12.008.
  52. ^ "Effect of Citric Acid on Tooth Enamel".
  53. ^ British Pharmacopoeia Commission Secretariat (2009). (PDF). Archived from the original (PDF) on April 11, 2009. Retrieved February 4, 2010.
  54. ^ (PDF). 2006. Archived from the original (PDF) on July 22, 2011. Retrieved 4 February 2010.

External links edit

 
Wikimedia Commons has media related to Citric acid.
 
Wikisource has the text of the 1911 Encyclopædia Britannica article "Citric Acid".

February 16, 2024
citric, acid, e330, redirects, here, locomotive, class, e330, organic, compound, with, chemical, formula, co2h, ch2co2h, colorless, weak, organic, acid, occurs, naturally, citrus, fruits, biochemistry, intermediate, citric, acid, cycle, which, occurs, metaboli. E330 redirects here For the locomotive see FS Class E330 Citric acid is an organic compound with the chemical formula HOC CO2H CH2CO2H 2 9 It is a colorless weak organic acid 9 It occurs naturally in citrus fruits In biochemistry it is an intermediate in the citric acid cycle which occurs in the metabolism of all aerobic organisms 9 Citric acid Stereo skeletal formula of citric acid Ball and stick model of citric acidNamesIUPAC name Citric acid 1 Preferred IUPAC name 2 Hydroxypropane 1 2 3 tricarboxylic acid 1 IdentifiersCAS Number 77 92 9 Y3D model JSmol Interactive imageChEBI CHEBI 30769 YChEMBL ChEMBL1261 YChemSpider 305 YDrugBank DB04272 YECHA InfoCard 100 000 973EC Number 201 069 1E number E330 antioxidants IUPHAR BPS 2478KEGG D00037 YPubChem CID 31122230 monohydrate RTECS number GE7350000UNII XF417D3PSL YCompTox Dashboard EPA DTXSID3020332InChI InChI 1S C6H8O7 c7 3 8 1 6 13 5 11 12 2 4 9 10 h13H 1 2H2 H 7 8 H 9 10 H 11 12 YKey KRKNYBCHXYNGOX UHFFFAOYSA N YInChI 1 C6H8O7 c7 3 8 1 6 13 5 11 12 2 4 9 10 h13H 1 2H2 H 7 8 H 9 10 H 11 12 Key KRKNYBCHXYNGOX UHFFFAOYAMSMILES OC O CC O C O O CC O OPropertiesChemical formula C 6H 8O 7Molar mass 192 123 g mol anhydrous 210 14 g mol monohydrate 2 Appearance white solidOdor OdorlessDensity 1 665 g cm3 anhydrous 1 542 g cm3 18 C monohydrate Melting point 156 C 313 F 429 K Boiling point 310 C 590 F 583 K decomposes from 175 C 3 Solubility in water 54 w w 10 C 59 2 w w 20 C 64 3 w w 30 C 68 6 w w 40 C 70 9 w w 50 C 73 5 w w 60 C 76 2 w w 70 C 78 8 w w 80 C 81 4 w w 90 C 84 w w 100 C 4 Solubility Soluble in acetone alcohol ether ethyl acetate DMSO Insoluble in C6 H6 CHCl3 CS2 toluene 3 Solubility in ethanol 62 g 100 g 25 C 3 Solubility in amyl acetate 4 41 g 100 g 25 C 3 Solubility in diethyl ether 1 05 g 100 g 25 C 3 Solubility in 1 4 dioxane 35 9 g 100 g 25 C 3 log P 1 64Acidity pKa pKa1 3 13 5 pKa2 4 76 5 pKa3 6 39 6 6 40 7 Refractive index nD 1 493 1 509 20 C 4 1 46 150 C 3 Viscosity 6 5 cP 50 aq sol 4 StructureCrystal structure MonoclinicThermochemistryHeat capacity C 226 51 J mol K 26 85 C 8 Std molarentropy S 298 252 1 J mol K 8 Std enthalpy offormation DfH 298 1543 8 kJ mol 4 Heat of combustion higher value HHV 1985 3 kJ mol 474 5 kcal mol 2 47 kcal g 4 1960 6 kJ mol 8 1972 34 kJ mol 471 4 kcal mol 2 24 kcal g monohydrate 4 PharmacologyATC code A09AB04 WHO HazardsOccupational safety and health OHS OSH Main hazards Skin and eye irritantGHS labelling Pictograms 5 Signal word WarningHazard statements H290 H319 H315 5 Precautionary statements P305 P351 P338 5 NFPA 704 fire diamond 210Flash point 155 C 311 F 428 K Autoignitiontemperature 345 C 653 F 618 K Explosive limits 8 5 Lethal dose or concentration LD LC LD50 median dose 3000 mg kg rats oral Safety data sheet SDS HMDBExcept where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa Y verify what is Y N Infobox references More than two million tons of citric acid are manufactured every year It is used widely as an acidifier as a flavoring and a chelating agent 10 A citrate is a derivative of citric acid that is the salts esters and the polyatomic anion found in solution An example of the former a salt is trisodium citrate an ester is triethyl citrate When part of a salt the formula of the citrate anion is written as C6 H5 O3 7 or C3 H5 O COO 3 3 Contents 1 Natural occurrence and industrial production 2 Chemical characteristics 3 Biochemistry 3 1 Citric acid cycle 3 2 Other biological roles 4 Applications 4 1 Food and drink 4 2 Cleaning and chelating agent 4 3 Cosmetics pharmaceuticals dietary supplements and foods 4 4 Other uses 5 Synthesis of other organic compounds 6 Safety 7 Compendial status 8 See also 9 Explanatory notes 10 References 11 External linksNatural occurrence and industrial production edit nbsp Lemons oranges limes and other citrus fruits contain high concentrations of citric acid Citric acid occurs in a variety of fruits and vegetables most notably citrus fruits Lemons and limes have particularly high concentrations of the acid it can constitute as much as 8 of the dry weight of these fruits about 47 g L in the juices 11 a The concentrations of citric acid in citrus fruits range from 0 005 mol L for oranges and grapefruits to 0 30 mol L in lemons and limes these values vary within species depending upon the cultivar and the circumstances under which the fruit was grown Citric acid was first isolated in 1784 by the chemist Carl Wilhelm Scheele who crystallized it from lemon juice 12 13 Industrial scale citric acid production first began in 1890 based on the Italian citrus fruit industry where the juice was treated with hydrated lime calcium hydroxide to precipitate calcium citrate which was isolated and converted back to the acid using diluted sulfuric acid 14 In 1893 C Wehmer discovered Penicillium mold could produce citric acid from sugar 15 However microbial production of citric acid did not become industrially important until World War I disrupted Italian citrus exports In 1917 American food chemist James Currie discovered that certain strains of the mold Aspergillus niger could be efficient citric acid producers 16 and the pharmaceutical company Pfizer began industrial level production using this technique two years later followed by Citrique Belge in 1929 In this production technique which is still the major industrial route to citric acid used today cultures of Aspergillus niger are fed on a sucrose or glucose containing medium to produce citric acid The source of sugar is corn steep liquor molasses hydrolyzed corn starch or other inexpensive carbohydrate solution 17 After the mold is filtered out of the resulting suspension citric acid is isolated by precipitating it with calcium hydroxide to yield calcium citrate salt from which citric acid is regenerated by treatment with sulfuric acid as in the direct extraction from citrus fruit juice In 1977 a patent was granted to Lever Brothers for the chemical synthesis of citric acid starting either from aconitic or isocitrate also called alloisocitrate calcium salts under high pressure conditions this produced citric acid in near quantitative conversion under what appeared to be a reverse non enzymatic Krebs cycle reaction 18 Global production was in excess of 2 000 000 tons in 2018 19 More than 50 of this volume was produced in China More than 50 was used as an acidity regulator in beverages some 20 in other food applications 20 for detergent applications and 10 for applications other than food such as cosmetics pharmaceuticals and in the chemical industry 14 Chemical characteristics edit nbsp Speciation diagram for a 10 millimolar solution of citric acidCitric acid can be obtained as an anhydrous water free form or as a monohydrate The anhydrous form crystallizes from hot water while the monohydrate forms when citric acid is crystallized from cold water The monohydrate can be converted to the anhydrous form at about 78 C Citric acid also dissolves in absolute anhydrous ethanol 76 parts of citric acid per 100 parts of ethanol at 15 C It decomposes with loss of carbon dioxide above about 175 C Citric acid is a tribasic acid with pKa values extrapolated to zero ionic strength of 3 128 4 761 and 6 396 at 25 C 20 The pKa of the hydroxyl group has been found by means of 13C NMR spectroscopy to be 14 4 21 The speciation diagram shows that solutions of citric acid are buffer solutions between about pH 2 and pH 8 In biological systems around pH 7 the two species present are the citrate ion and mono hydrogen citrate ion The SSC 20X hybridization buffer is an example in common use 22 23 Tables compiled for biochemical studies are available 24 On the other hand the pH of a 1 mM solution of citric acid will be about 3 2 The pH of fruit juices from citrus fruits like oranges and lemons depends on the citric acid concentration with a higher concentration of citric acid resulting in a lower pH Acid salts of citric acid can be prepared by careful adjustment of the pH before crystallizing the compound See for example sodium citrate The citrate ion forms complexes with metallic cations The stability constants for the formation of these complexes are quite large because of the chelate effect Consequently it forms complexes even with alkali metal cations However when a chelate complex is formed using all three carboxylate groups the chelate rings have 7 and 8 members which are generally less stable thermodynamically than smaller chelate rings In consequence the hydroxyl group can be deprotonated forming part of a more stable 5 membered ring as in ammonium ferric citrate NH4 5 Fe C6 H4 O7 2 2H2 O 25 Citric acid can be esterified at one or more of its three carboxylic acid groups to form any of a variety of mono di tri and mixed esters 26 Biochemistry editCitric acid cycle edit Main article Citric acid cycle Citrate is an intermediate in the citric acid cycle also known as the TCA TriCarboxylic Acid cycle or the Krebs cycle a central metabolic pathway for animals plants and bacteria Citrate synthase catalyzes the condensation of oxaloacetate with acetyl CoA to form citrate Citrate then acts as the substrate for aconitase and is converted into aconitic acid The cycle ends with regeneration of oxaloacetate This series of chemical reactions is the source of two thirds of the food derived energy in higher organisms Hans Adolf Krebs received the 1953 Nobel Prize in Physiology or Medicine for the discovery Some bacteria notably E coli can produce and consume citrate internally as part of their TCA cycle but are unable to use it as food because they lack the enzymes required to import it into the cell After tens of thousands of evolutions in a minimal glucose medium that also contained citrate during Richard Lenski s Long Term Evolution Experiment a variant E coli evolved with the ability to grow aerobically on citrate Zachary Blount a student of Lenski s and colleagues studied these Cit E coli 27 28 as a model for how novel traits evolve They found evidence that in this case the innovation was caused by a rare duplication mutation due to the accumulation of several prior potentiating mutations the identity and effects of which are still under study The evolution of the Cit trait has been considered a notable example of the role of historical contingency in evolution Other biological roles edit Citrate can be transported out of the mitochondria and into the cytoplasm then broken down into acetyl CoA for fatty acid synthesis and into oxaloacetate Citrate is a positive modulator of this conversion and allosterically regulates the enzyme acetyl CoA carboxylase which is the regulating enzyme in the conversion of acetyl CoA into malonyl CoA the commitment step in fatty acid synthesis In short citrate is transported into the cytoplasm converted into acetyl CoA which is then converted into malonyl CoA by acetyl CoA carboxylase which is allosterically modulated by citrate High concentrations of cytosolic citrate can inhibit phosphofructokinase the catalyst of a rate limiting step of glycolysis This effect is advantageous high concentrations of citrate indicate that there is a large supply of biosynthetic precursor molecules so there is no need for phosphofructokinase to continue to send molecules of its substrate fructose 6 phosphate into glycolysis Citrate acts by augmenting the inhibitory effect of high concentrations of ATP another sign that there is no need to carry out glycolysis 29 Citrate is a vital component of bone helping to regulate the size of apatite crystals 30 Applications editFood and drink edit nbsp Powdered citric acid being used to prepare lemon pepper seasoningBecause it is one of the stronger edible acids the dominant use of citric acid is as a flavoring and preservative in food and beverages especially soft drinks and candies 14 Within the European Union it is denoted by E number E330 Citrate salts of various metals are used to deliver those minerals in a biologically available form in many dietary supplements Citric acid has 247 kcal per 100 g 31 In the United States the purity requirements for citric acid as a food additive are defined by the Food Chemicals Codex which is published by the United States Pharmacopoeia USP Citric acid can be added to ice cream as an emulsifying agent to keep fats from separating to caramel to prevent sucrose crystallization or in recipes in place of fresh lemon juice Citric acid is used with sodium bicarbonate in a wide range of effervescent formulae both for ingestion e g powders and tablets and for personal care e g bath salts bath bombs and cleaning of grease Citric acid sold in a dry powdered form is commonly sold in markets and groceries as sour salt due to its physical resemblance to table salt It has use in culinary applications as an alternative to vinegar or lemon juice where a pure acid is needed Citric acid can be used in food coloring to balance the pH level of a normally basic dye citation needed Cleaning and chelating agent edit nbsp Structure of an iron III citrate complex 32 33 Citric acid is an excellent chelating agent binding metals by making them soluble It is used to remove and discourage the buildup of limescale from boilers and evaporators 14 It can be used to treat water which makes it useful in improving the effectiveness of soaps and laundry detergents By chelating the metals in hard water it lets these cleaners produce foam and work better without need for water softening Citric acid is the active ingredient in some bathroom and kitchen cleaning solutions A solution with a six percent concentration of citric acid will remove hard water stains from glass without scrubbing Citric acid can be used in shampoo to wash out wax and coloring from the hair Illustrative of its chelating abilities citric acid was the first successful eluant used for total ion exchange separation of the lanthanides during the Manhattan Project in the 1940s 34 In the 1950s it was replaced by the far more efficient 35 EDTA In industry it is used to dissolve rust from steel and to passivate stainless steels 36 Cosmetics pharmaceuticals dietary supplements and foods edit Citric acid is used as an acidulant in creams gels and liquids Used in foods and dietary supplements it may be classified as a processing aid if it was added for a technical or functional effect e g acidulent chelator viscosifier etc If it is still present in insignificant amounts and the technical or functional effect is no longer present it may be exempt from labeling lt 21 CFR 101 100 c gt Citric acid is an alpha hydroxy acid and is an active ingredient in chemical skin peels 37 Citric acid is commonly used as a buffer to increase the solubility of brown heroin 38 Citric acid is used as one of the active ingredients in the production of facial tissues with antiviral properties 39 Other uses edit The buffering properties of citrates are used to control pH in household cleaners and pharmaceuticals Citric acid is used as an odorless alternative to white vinegar for fabric dyeing with acid dyes Sodium citrate is a component of Benedict s reagent used for both qualitative and quantitative identification of reducing sugars 40 Citric acid can be used as an alternative to nitric acid in passivation of stainless steel 41 Citric acid can be used as a lower odor stop bath as part of the process for developing photographic film Photographic developers are alkaline so a mild acid is used to neutralize and stop their action quickly but commonly used acetic acid leaves a strong vinegar odor in the darkroom 42 Citric acid potassium sodium citrate can be used as a blood acid regulator The citric acid is included to improve palatability 43 Citric acid is an excellent soldering flux 44 either dry or as a concentrated solution in water It should be removed after soldering especially with fine wires as it is mildly corrosive It dissolves and rinses quickly in hot water Alkali citrate can be used as an inhibitor of kidney stones by increasing urine citrate levels useful for prevention of calcium stones and increasing urine pH useful for preventing uric acid and cystine stones 45 Synthesis of other organic compounds editCitric acid is a versatile precursor to many other organic compounds Dehydration routes give itaconic acid and its anhydride 46 Citraconic acid can be produced via thermal isomerization of itaconic acid anhydride 47 The required itaconic acid anhydride is obtained by dry distillation of citric acid Aconitic acid can be synthesized by dehydration of citric acid using sulfuric acid 48 HO2CCH2 2C OH CO2H HO2CCH C CO2H CH2CO2H H2OAcetonedicarboxylic acid can also be prepared by decarboxylation of citric acid in fuming sulfuric acid 49 Safety editAlthough a weak acid exposure to pure citric acid can cause adverse effects Inhalation may cause cough shortness of breath or sore throat Over ingestion may cause abdominal pain and sore throat Exposure of concentrated solutions to skin and eyes can cause redness and pain 50 Long term or repeated consumption may cause erosion of tooth enamel 50 51 52 Compendial status editBritish Pharmacopoeia 53 Japanese Pharmacopoeia 54 See also editThe closely related acids isocitric acid aconitic acid and propane 1 2 3 tricarboxylic acid tricarballylic acid carballylic acid Acids in wineExplanatory notes edit This still does not make the lemon particularly strongly acidic This is because as a weak acid most of the acid molecules are not dissociated so not contributing to acidity inside the lemon or its juice References edit a b International Union of Pure and Applied Chemistry 2014 Nomenclature of Organic Chemistry IUPAC Recommendations and Preferred Names 2013 The Royal Society of Chemistry p 747 doi 10 1039 9781849733069 ISBN 978 0 85404 182 4 CID 22230 from PubChem a b c d e f g citric acid chemister ru Archived from the original on November 29 2014 Retrieved June 1 2014 a b c d e f CID 311 from PubChem a b c d e f Fisher Scientific Citric acid Retrieved on 2014 06 02 Data for Biochemical Research ZirChrom Separations Inc Retrieved January 11 2012 Ionization Constants of Organic Acids Michigan State University Retrieved January 11 2012 a b c Citric acid in Linstrom Peter J Mallard William G eds NIST Chemistry WebBook NIST Standard Reference Database Number 69 National Institute of Standards and Technology Gaithersburg MD retrieved 2014 06 02 a b c Citric acid C6H8O7 PubChem Archived from the original on January 19 2022 Retrieved December 19 2021 Apleblat Alexander 2014 Citric acid Springer ISBN 978 3 319 11232 9 Penniston KL Nakada SY Holmes RP Assimos DG 2008 Quantitative Assessment of Citric Acid in Lemon Juice Lime Juice and Commercially Available Fruit Juice Products Journal of Endourology 22 3 567 570 doi 10 1089 end 2007 0304 PMC 2637791 PMID 18290732 Scheele Carl Wilhelm 1784 Anmarkning om Citron saft samt satt at crystallisera densamma Note about lemon juice as well as ways to crystallize it Kungliga Vetenskaps Academiens Nya Handlingar New Proceedings of the Royal Academy of Science 2nd series in Swedish 5 105 109 Graham Thomas 1842 Elements of chemistry including the applications of the science in the arts Hippolyte Bailliere foreign bookseller to the Royal College of Surgeons and to the Royal Society 219 Regent Street p 944 Retrieved June 4 2010 a b c d Verhoff Frank H Bauweleers Hugo 2014 Citric Acid Ullmann s Encyclopedia of Industrial Chemistry Weinheim Wiley VCH doi 10 1002 14356007 a07 103 pub3 ISBN 978 3527306732 H Benninga June 30 1990 A History of Lactic Acid Making A Chapter in the History of Biotechnology Springer Science amp Business Media pp 140 5 ISBN 978 0 7923 0625 2 Currie James 1917 The Journal of Biological Chemistry American Society for Biochemistry and Molecular Biology pp 15 27 Lotfy Walid A Ghanem Khaled M El Helow Ehab R 2007 Citric acid production by a novel Aspergillus niger isolate II Optimization of process parameters through statistical experimental designs Bioresource Technology 98 18 3470 3477 doi 10 1016 j biortech 2006 11 032 PMID 17317159 US 4056567 V Lamberti and E Gutierrez Global Citric Acid Markets Report 2011 2018 amp 2019 2024 prnewswire com March 19 2019 Retrieved October 28 2019 Goldberg Robert N Kishore Nand Lennen Rebecca M 2002 Thermodynamic Quantities for the Ionization Reactions of Buffers J Phys Chem Ref Data 31 1 231 370 Bibcode 2002JPCRD 31 231G doi 10 1063 1 1416902 S2CID 94614267 Silva Andre M N Kong Xiaole Hider Robert C 2009 Determination of the pKa value of the hydroxyl group in the a hydroxycarboxylates citrate malate and lactate by 13C NMR implications for metal coordination in biological systems Biometals 22 5 771 778 doi 10 1007 s10534 009 9224 5 PMID 19288211 S2CID 11615864 SSC OpenWetWare Maniatis T Fritsch E F Sambrook J 1982 Molecular Cloning A Laboratory Manual Cold Spring Harbor Laboratory Cold Spring Harbor NY Gomori G 1955 16 Preparation of buffers for use in enzyme studies Methods in Enzymology Volume 1 Vol 1 pp 138 146 doi 10 1016 0076 6879 55 01020 3 ISBN 9780121818012 Matzapetakis M Raptopoulou C P Tsohos A Papaefthymiou V Moon S N Salifoglou A 1998 Synthesis Spectroscopic and Structural Characterization of the First Mononuclear Water Soluble Iron Citrate Complex NH4 5Fe C6H4O7 2 2H2O J Am Chem Soc 120 50 13266 13267 doi 10 1021 ja9807035 Bergeron Raymond J Xin Meiguo Smith Richard E Wollenweber Markus McManis James S Ludin Christian Abboud Khalil A 1997 Total synthesis of rhizoferrin an iron chelator Tetrahedron 53 2 427 434 doi 10 1016 S0040 4020 96 01061 7 Powell Alvin February 14 2014 59 000 generations of bacteria plus freezer yield startling results phys org Retrieved April 13 2017 Blount Z D Borland C Z Lenski R E June 4 2008 Historical contingency and the evolution of a key innovation in an experimental population of Escherichia coli Proceedings of the National Academy of Sciences 105 23 7899 7906 Bibcode 2008PNAS 105 7899B doi 10 1073 pnas 0803151105 PMC 2430337 PMID 18524956 Stryer Lubert Berg Jeremy Tymoczko John 2003 Section 16 2 The Glycolytic Pathway Is Tightly Controlled Biochemistry 5 ed international ed 3 printing ed New York Freeman ISBN 978 0716746843 Hu Y Y Rawal A Schmidt Rohr K December 2010 Strongly bound citrate stabilizes the apatite nanocrystals in bone Proceedings of the National Academy of Sciences 107 52 22425 22429 Bibcode 2010PNAS 10722425H doi 10 1073 pnas 1009219107 PMC 3012505 PMID 21127269 Greenfield Heather Southgate D A T 2003 Food Composition Data Production Management and Use Rome FAO p 146 ISBN 9789251049495 Xiang Hao Yongge Wei Shiwei Zhang 2001 Synthesis crystal structure and magnetic property of a binuclear iron III citrate complex Transition Metal Chemistry volume 26 issue 4 pages 384 387 doi 10 1023 A 1011055306645 Shweky Itzhak Bino Avi Goldberg David P Lippard Stephen J 1994 Syntheses Structures and Magnetic Properties of Two Dinuclear Iron III Citrate Complexes Inorganic Chemistry 33 23 5161 5162 doi 10 1021 ic00101a001 JOHNSON WARREN C QUILL LAURENCE L DANIELS FARRINGTON September 1 1947 Rare Earths Separation Developed on Manhattan Project Chemical amp Engineering News Archive 25 35 2494 doi 10 1021 cen v025n035 p2494 ISSN 0009 2347 Saleem Muhammad Hamzah Ali Shafaqat Rehman Muzammal Rizwan Muhammad Kamran Muhammad Mohamed Ibrahim A A Khan Zaid Bamagoos Atif A Alharby Hesham F Hakeem Khalid Rehman Liu Lijun August 1 2020 Individual and combined application of EDTA and citric acid assisted phytoextraction of copper using jute Corchorus capsularis L seedlings Environmental Technology amp Innovation 19 100895 doi 10 1016 j eti 2020 100895 ISSN 2352 1864 S2CID 219432688 ASTM A967 A967M 17 Standard Specification for Chemical Passivation Treatments for Stainless Steel Parts www astm org Tang Sheau Chung Yang Jen Hung April 10 2018 Dual Effects of Alpha Hydroxy Acids on the Skin Molecules 23 4 863 doi 10 3390 molecules23040863 ISSN 1420 3049 PMC 6017965 PMID 29642579 Strang J Keaney F Butterworth G Noble A Best D April 2001 Different forms of heroin and their relationship to cook up techniques data on and explanation of use of lemon juice and other acids Subst Use Misuse 36 5 573 88 doi 10 1081 ja 100103561 PMID 11419488 S2CID 8516420 Tissues that fight germs CNN July 14 2004 Retrieved May 8 2008 Chen Wei Abramowitz Matthew K February 2014 Treatment of Metabolic Acidosis in Patients With CKD American Journal of Kidney Diseases 63 2 311 317 doi 10 1053 j ajkd 2013 06 017 ISSN 0272 6386 PMC 3946919 PMID 23932089 Pickling and Passivating Stainless Steel PDF Euro inox org Archived from the original PDF on September 12 2012 Retrieved 2013 01 01 Anchell Steve The Darkroom Cookbook 3rd Edition Paperback Focal Press Retrieved January 1 2013 PubChem Sodium citrate pubchem ncbi nlm nih gov Retrieved August 2 2021 An Investigation of the Chemistry of Citric Acid in Military Soldering Applications PDF June 19 1995 Archived PDF from the original on March 15 2020 Berg C Larsson L Tiselius H G 1992 The effects of a single evening dose of alkaline citrate on urine composition and calcium stone formation The Journal of Urology 148 3 Pt 2 979 985 doi 10 1016 s0022 5347 17 36795 2 ISSN 0022 5347 PMID 1507355 R L Shriner S G Ford l J Roll 1931 Itaconic anhydride and itaconic acid Org Synth 11 70 doi 10 15227 orgsyn 011 0070 R L Shriner S G Ford l J Roll 1931 Citraconic Anhydride and Citraconic Acid Org Synth 28 28 doi 10 15227 orgsyn 011 0028 Bruce W F 1937 Aconitic Acid Organic Syntheses 17 1 doi 10 15227 orgsyn 017 0001 Roger Adams H M Chiles C F Rassweiler 1925 Acetonedicarboxylic Acid Organic Syntheses 5 5 doi 10 15227 orgsyn 005 0005 a b Citric acid International Chemical Safety Cards NIOSH September 18 2018 Archived from the original on July 12 2018 Retrieved September 9 2017 J Zheng F Xiao L M Qian Z R Zhou December 2009 Erosion behavior of human tooth enamel in citric acid solution Tribology International 42 11 12 1558 1564 doi 10 1016 j triboint 2008 12 008 Effect of Citric Acid on Tooth Enamel British Pharmacopoeia Commission Secretariat 2009 Index BP 2009 PDF Archived from the original PDF on April 11 2009 Retrieved February 4 2010 Japanese Pharmacopoeia Fifteenth Edition PDF 2006 Archived from the original PDF on July 22 2011 Retrieved 4 February 2010 External links edit nbsp Wikimedia Commons has media related to Citric acid nbsp Wikisource has the text of the 1911 Encyclopaedia Britannica article Citric Acid Retrieved from https en wikipedia org w index php title Citric acid amp oldid 1205226701, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.