حمض الليمون
نائل الشافعي ، مها المصري ساهم بشكل رئيسي في تحرير هذا المقال
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الأسماء | |||
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اسم أيوپاك
2-hydroxypropane-1,2,3-tricarboxylic acid
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اسم أيوپاك المفضل
2-Hydroxypropane-1,2,3-tricarboxylic acid[1] | |||
أسماء أخرى
3-hydroxypentanedioic acid-3-carboxylic acid
Hydrogen citrate | |||
المُعرِّفات | |||
رقم CAS | |||
3D model (JSmol)
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ChEBI | |||
ChEMBL | |||
ChemSpider | |||
DrugBank | |||
ECHA InfoCard | 100.000.973 | ||
رقم EC |
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E number | E330 (antioxidants, ...) | ||
KEGG | |||
PubChem CID
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رقم RTECS |
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UNII | |||
CompTox Dashboard (EPA)
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الخصائص | |||
الصيغة الجزيئية | C6H8O7 | ||
كتلة مولية | 192.09 g mol-1 | ||
المظهر | white solid | ||
الرائحة | Odorless | ||
الكثافة | 1.665 g/cm3 (anhydrous) 1.542 g/cm3 (18 °C, monohydrate) | ||
نقطة الانصهار | |||
نقطة الغليان | |||
قابلية الذوبان في الماء | 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)[3] | ||
قابلية الذوبان | Soluble in acetone, alcohol, ether, ethyl acetate, DMSO Insoluble in C 6H 6, CHCl3, CS2, toluene[4] | ||
قابلية الذوبان في ethanol | 62 g/100 g (25 °C)[4] | ||
قابلية الذوبان في amyl acetate | 4.41 g/100 g (25 °C)[4] | ||
قابلية الذوبان في diethyl ether | 1.05 g/100 g (25 °C)[4] | ||
قابلية الذوبان في 1,4-Dioxane | 35.9 g/100 g (25 °C)[4] | ||
log P | −1.64 | ||
الحموضة (pKa) | pKa1 = 3.13[5] pKa2 = 4.76[5] pKa3 = 6.39,[6] 6.40[7] | ||
معامل الانكسار (nD) | 1.493–1.509 (20 °C)[3] 1.46 (150 °C)[4] | ||
اللزوجة | 6.5 cP (50% aq. sol.)[3] | ||
البنية | |||
البنية البلورية | Monoclinic | ||
الكيمياء الحرارية | |||
الإنتالپية المعيارية للتشكل ΔfH |
−1543.8 kJ/mol[3] | ||
Standard molar entropy S |
252.1 J/(mol·K)[8] | ||
سعة الحرارة النوعية، C | 226.51 J/(mol·K) (26.85 °C)[8] | ||
علم الأدوية | |||
A09AB04 (WHO) | |||
المخاطر | |||
خطر رئيسي | Skin and eye corrosion | ||
صفحة بيانات السلامة | HMDB | ||
ن.م.ع. مخطط تصويري | [5] | ||
ن.م.ع. كلمة الاشارة | Danger | ||
H319[5] | |||
P305+P351+P338[5] | |||
NFPA 704 (معيـَّن النار) | |||
نقطة الوميض | 155 °C (311 °F; 428 K) | ||
345 °C (653 °F; 618 K) | |||
حدود الانفجار | 8%[5] | ||
الجرعة أو التركيز القاتل (LD, LC): | |||
LD50 (الجرعة الوسطى)
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3000 mg/kg (rats, oral) | ||
ما لم يُذكر غير ذلك، البيانات المعطاة للمواد في حالاتهم العيارية (عند 25 °س [77 °ف]، 100 kPa). | |||
verify (what is ?) | |||
مراجع الجدول | |||
حمض الليمون أو ملح الليمون أو حمض الستريك إنگليزية: Citric acid هو حمض عضوي ضعيف يوجد في الموالح. وهو مادة حافظة طبيعية. ويستخدم لإضافة مذاق حمضي للأطعمة والمشروبات. في الكيمياء الحيوية هو وسيط مهم في دورة حمض الستريك وبالتالي فهو يتكون في كل التمثيل الغذائي لكل شيء حي تقريباً. ويخدم أيضاً كعامل منظف للبيئة ويعمل كمضاد للأكسدة.
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.[9]
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.
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التواجد الطبيعي والانتاج الصناعي
Citric acid exists 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[10]).[أ] 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 in which the fruit was grown.
Citric acid was first isolated in 1784 by the chemist Carl Wilhelm Scheele, who crystallized it from lemon juice.[11][12]
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.[13] In 1893, C. Wehmer discovered Penicillium mold could produce citric acid from sugar. 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 certain strains of the mold Aspergillus niger could be efficient citric acid producers, 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 A. 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, sugary solution.[14] After the mold is filtered out of the resulting solution, 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/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.[15]
Global production was in excess of 2,000,000 tons in 2018.[16] 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.[13]
الخصائص والوصف العام
بلورات عديمة اللون أو شفافة،أو على شكل حبيبات بيضاء لمسحوق بلوري ناعم، تتزهر في الهواء الجاف، شديدة الانحلال بالماء، تنحل بحرية في الكحول[17].
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.[18] The pKa of the hydroxyl group has been found, by means of 13C NMR spectroscopy, to be 14.4.[19] 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.[20] Tables compiled for biochemical studies[21] are available.
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.[22]
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.[23]
الكيمياء الحيوية
دورة حمض الليمون
Citrate is an intermediate in the TCA cycle (aka TriCarboxylic Acid cycle, or Krebs cycle, Szent-Györgyi), 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 thousand 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[24][25] 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.
الأدوار الحيوية الأخرى
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.[26]
Citrate is a vital component of bone, helping to regulate the size of apatite crystals.[27]
التنافرات
يكون حمض الليمون غير متوافق مع طرطرات البوتاسيوم ومع القلويات وكربونات وبيكربونات عناصر الفصيلة الأولى، والأسيتات و مركبات الكبريت، تشمل التنافرات أيضاً العوامل المؤكسدة و الأسس و العوامل المخففة و النترات، من الممكن أن تنفجر عند مزجها مع نترات معدنية.[28]
القياس
يستخدم حمض الليمون كمادة مضافة للمشروبات الغازية والجعة والصودا ومتواجد بشكل طبيعي في عديد من العصائر. يشكل هذا صعوبة في القياس لأن الطريقة المعيارية في قياس السكاكر هي قرينة الانكسار. حيث إن قرينة الانكسار للسكر وحمض الليمون متطابقة تقريباً. لذا فإن طريقة القياس الفضلى لحلاوة المشروبات الغازية وعصير البرتقال هي النسبة (سكر/حمض). أما حديثاً فقد سمح استخدام حساسات الأشعة تحت الحمراء بقياس كل من الـ Brix (محنوى السكر) والحموضة عبر تحري السكاكر وحمض الليمون عبر اهتزازاتها الجزيئية النوعية؛ إن هذا يعطي دقة في القياس لحلاوة المشروب.
تاريخ
The discovery of citric acid has been credited to the 8th century alchemist جابر بن حيان (Geber). Medieval scholars in Europe were aware of the acidic nature of lemon and lime juices; such knowledge is recorded in the 13th century encyclopedia Speculum Majus (The Great Mirror), compiled by Vincent of Beauvais. Citric acid was first isolated in 1784 by the Swedish chemist Carl Wilhelm Scheele, who crystallized it from lemon juice. Industrial-scale citric acid production began in 1860, based on the Italian citrus fruit industry.
دورة كريبس
حمض الليمون هو واحد من سلسلة من المركبات التي تدخل في الأكسدة الفيزيولوجية للدسم والبروتينات والسكريات إلى ثاني أكسيد الكربون والماء. وإن سلسلة التفاعلات الكيميائية تلك أساسية لكافة التفاعلات الاستقلابية (الأيضية) تقريباً، وهي المصدر لثلثي الطاقة الآتية من الطعام لدى أكثر الكائنات الحية.
تم اكتشاف حلقة كريبس من قبل السيد هانز أدولف كريبس Hans Adolf Krebs . وتلقى في العام 1953 جائزة نوبل للفيزيولوجيا أو للطب على هذا الاكتشاف. كما تعرف سلسلة التفاعلات تلك بعدة أسماء، تتضمن حلقة حمض الليمون citric acid cycle وحلقة كريبس Krebs cycle وحلقة الحمض ثلاثي الزمرة الكربوكسيلية TCA cycle
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الاستخدامات
الطعام والشراب
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.[13] 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.[29] 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.[بحاجة لمصدر]
عامل تنظيف وتبييض
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.[13] 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.[32] In the 1950s, it was replaced by the far more efficient[33] EDTA.
In industry, it is used to dissolve rust from steel and passivate stainless steels.[34]
مستحضرات التجميل، الصيدلة، المضافات الغذائية والأطعمة
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.[35]
Citric acid is commonly used as a buffer to increase the solubility of brown heroin.[36]
Citric acid is used as one of the active ingredients in the production of facial tissues with antiviral properties.[37]
مضاف غذائي
إن استخدامه كمضاف غذائي يكون على شكل مادة منكهة ومادة حافظة في الأطعمة والأشربة وخصوصاً المشروبات الغازية. يشار لحمض الليمون من خلال E number بالرمز: E330. يستخدم كذلك بشكل أملاح السترات لمعادن مختلفة لإيتاء هذه المعادن ضمن شكل متوافر حيوياً في كثير من المتممات الغذائية. تستغل خواص القدرة الدارئة للسترات لضبط درجة الباهاء المنظفات المنزلية والمواد الصيدلانية. تحدد في الولايات المتحدة متطلبات النقاء لحمض الليمون كمضاف غذائي بواسطة FCC Food Chemical Codex والتي تنشر بواسطة دستور الأدوية الأمريكي USP.
استخدامات أخرى
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 identification both qualitatively and quantitatively of reducing sugars.[38]
Citric acid can be used as an alternative to nitric acid in passivation of stainless steel.[39]
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.[40]
Citric acid/potassium-sodium citrate can be used as a blood acid regulator.[41]
Citric acid is an excellent soldering flux,[42] 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.
حالة الخلاصة
انظر أيضاً
- Citric acid intolerance
- Citric acid cycle
- The closely related acids isocitric acid, aconitic acid, and propane-1,2,3-tricarboxylic acid (tricarballylic acid, carballylic acid)
المصادر
- ^ خطأ استشهاد: وسم
<ref>
غير صحيح؛ لا نص تم توفيره للمراجع المسماةIUPAC2014
- ^ CID 22230 from PubChem
- ^ أ ب ت ث CID 311 from PubChem
- ^ أ ب ت ث ج ح خطأ استشهاد: وسم
<ref>
غير صحيح؛ لا نص تم توفيره للمراجع المسماةchemister
- ^ أ ب ت ث ج ح 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.
- ^ أ ب خطأ استشهاد: وسم
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غير صحيح؛ لا نص تم توفيره للمراجع المسماةnist
- ^ 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). "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 السويدية). 5: 105–109.
- ^ 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.
- ^ أ ب ت ث Verhoff, Frank H.; Bauweleers, Hugo (2014). "Citric Acid". Ullmann's Encyclopedia of Industrial Chemistry. Weinheim: Wiley-VCH. doi:10.1002/14356007.a07_103.pub3.
{{cite encyclopedia}}
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(help) - ^ 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
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- ^ united states Pharmacopiea
- ^ 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 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.
- ^ 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. Methods in Enzymology. 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.
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وصلات خارجية
| Citric acid
]].- CID 311 from PubChem
- Citric acid analysis - free spreadsheet for titration of acids and pH calculation
- Applications of Citric Acid
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- منظمات حموضة الطعام
- Tricarboxylic acids
- Alpha hydroxy acids
- Beta hydroxy acids
- Chelating agents
- Household chemicals
- Photographic chemicals
- مضافات غذائية بأرقام أوروپية
- Citrus
- Citrates
- مواد مضافة غذائية
- سواغات
- نكهات