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Bitartrate

Bitartrate, also known as hydrogen tartrate, is an anion formed by the partial deprotonation of tartaric acid (2,3-dihydroxybutanedioic acid), a dicarboxylic acid, resulting in the monovalent ion [C₄H₅O₆]⁻ with a molecular weight of 149.08 g/mol.^[1] This ion represents the conjugate base where only one of the two acidic hydrogen atoms from tartaric acid's carboxyl groups is replaced, distinguishing it from the fully deprotonated tartrate anion.^[2] Bitartrates are thus the acid salts or monoesters of tartaric acid, commonly encountered in chemical and industrial applications due to their acidic properties and solubility characteristics.^[3] The most notable bitartrate is potassium bitartrate (KC₄H₅O₆), a white crystalline powder also referred to as cream of tartar, which forms naturally as a sediment during the fermentation of grape juice in winemaking.^[4] As a byproduct of the wine industry, it occurs in grapes, the primary source of tartaric acid, and is extracted for commercial use.^[4] In food science, potassium bitartrate functions as a leavening agent in baking powders, stabilizes egg whites to increase volume and heat tolerance, and acts as an acidity regulator and humectant in confectionery and syrups.^[4] Beyond culinary roles, it serves as a laxative, buffering agent in analytical chemistry (such as NIST reference buffers), and stabilizer in wine production to prevent tartrate precipitation.^[5]^[6] Other bitartrates, such as sodium bitartrate, find applications in pharmaceuticals and as intermediates in organic synthesis, leveraging the ion's ability to form coordination complexes and regulate pH.^[7] These compounds are valued for their biocompatibility, optical activity derived from tartaric acid's chirality, and role in processes like crystallization control in the food and beverage sectors.^[8]

Chemistry

Definition and Nomenclature

Bitartrate, also known as the bitartrate ion, is the conjugate base of tartaric acid, formed by the deprotonation of one of the two carboxylic acid groups in the parent molecule, resulting in the monoanionic species with the molecular formula \ce{C4H5O6^-}.^[9] The preferred IUPAC name for this anion is 3-carboxy-2,3-dihydroxypropanoate.^[9] It is commonly referred to by other names such as hydrogen tartrate or acid tartrate, reflecting its role as the partially neutralized form of tartaric acid.^[3] Tartaric acid itself is a dibasic carboxylic acid, capable of donating two protons, with the fully deprotonated dianion known as the tartrate ion (\ce{C4H4O6^{2-}}).^[10] The nomenclature "bitartrate" historically denotes a salt or ester in which only one of the two acidic hydrogen atoms of tartaric acid is replaced by a metal ion or positive group, distinguishing it from the normal tartrate.^[11]

Molecular Structure

The bitartrate ion, with the chemical formula \ce{C4H5O6^-}, is the monoanionic conjugate base derived from tartaric acid.^[1] Its structural formula is \ce{HOOC-CH(OH)-CH(OH)-[COO](/page/COO)^-}, featuring a chain of four carbon atoms where the terminal groups consist of one protonated carboxylic acid (\ce{-COOH}) and one deprotonated carboxylate (\ce{-COO^-}), flanked by two adjacent hydroxyl-substituted chiral carbons.^[4] The molar mass of the ion is 149.08 g/mol.^[1] This structure includes two chiral centers at the 2- and 3-positions, enabling stereoisomerism analogous to that of its conjugate acid, tartaric acid. The naturally occurring form is the (2R,3R)-bitartrate, corresponding to the L-(+)-enantiomer prevalent in biological sources such as grapes. The enantiomer is the (2S,3S)-bitartrate, while the meso form, (2R,3S)-bitartrate, is achiral due to an internal plane of symmetry. These stereoisomers arise from the configurations at the hydroxyl-bearing carbons, influencing the ion's spatial arrangement and potential interactions.^[12] The bonding in the bitartrate ion is characterized by the polar carboxylic acid and carboxylate groups, which differ in their acidity and charge, along with the vicinal diol moiety formed by the two hydroxyl groups. These features confer significant hydrogen bonding potential, particularly through the \ce{-OH} and \ce{-COO^-} sites, facilitating intermolecular associations in salts and solutions.^[13]

Properties

Physical Properties

Bitartrate salts, such as potassium bitartrate (KHC₄H₅O₆), typically appear as colorless monoclinic crystals or a fine white powder.^[4] These salts exhibit moderate solubility in water, dissolving at approximately 0.57 g per 100 mL at 20 °C, while being practically insoluble in alcohol (1 g requires about 8820 mL).^[4] Potassium bitartrate has a density of 1.95 g/cm³ and decomposes upon heating at approximately 230 °C.^[14] Saturated aqueous solutions of bitartrate salts are acidic due to partial dissociation, with a pH of approximately 3.56 at 25 °C.^[15] For comparison, sodium bitartrate shows higher water solubility, around 30 g per 100 mL at 20 °C.^[16] These physical characteristics are closely related to those of tartaric acid, the parent compound.

Chemical Properties

The bitartrate ion (HC₄H₅O₆⁻), derived from the first deprotonation of tartaric acid (H₂C₄H₆O₆), functions as a weak acid in aqueous solutions. The acid dissociation constant for the first proton of tartaric acid is approximately pKₐ₁ = 2.98 at 25°C, facilitating the formation of the bitartrate ion under mildly acidic conditions.^[17] The bitartrate ion itself undergoes further dissociation according to the equilibrium:

\text{HC}_4\text{H}_5\text{O}_6^- \rightleftharpoons \text{H}^+ + \text{C}_4\text{H}_4\text{O}_6^{2-}

with a pKₐ₂ value of approximately 4.34 at 25°C, establishing it as a buffer component in systems near neutral pH.^[17] This stepwise dissociation behavior underscores the bitartrate ion's role in maintaining pH-dependent equilibria, where the position shifts based on solution acidity and ionic strength.^[18] Regarding stability, the bitartrate ion is susceptible to thermal decomposition at elevated temperatures, typically beginning above 220°C, where it breaks down into carbon dioxide, water, and organic fragments.^[14] This instability limits its use in high-heat processes, though it remains stable under ambient conditions. Additionally, bitartrate exhibits chelating properties toward metal ions, forming coordination complexes with divalent and trivalent metals like lead, cadmium, and iron due to its carboxylate and hydroxyl groups.^[19] These interactions enhance metal solubility and stability in solution, contributing to its utility in metal sequestration.^[8] The redox properties of the bitartrate ion are limited, with no strong inherent oxidizing or reducing capacity under standard conditions. However, in biological contexts, bitartrate-containing compounds, such as cysteamine bitartrate, participate in mild oxidation-reduction reactions that modulate oxidative stress by scavenging reactive oxygen species and influencing cellular redox balance.^[20] The chirality of the bitartrate ion, stemming from the two stereocenters in the tartaric acid backbone, enables its application in resolving racemic mixtures through selective diastereomer formation with chiral counterparts, allowing separation based on differential solubility or crystallization tendencies.^[21]

Occurrence and Production

Natural Occurrence

Bitartrate, the anion derived from tartaric acid (also known as 2,3-dihydroxysuccinic acid), occurs naturally as salts such as potassium bitartrate in various plant sources, primarily fruits where tartaric acid is a key organic acid.^[4] The most abundant natural source is grapes (Vitis vinifera), where tartaric acid constitutes a major component of the fruit's acidity, typically comprising 40-70% of total organic acids in mature berries.^[22] In grape metabolism, tartaric acid is biosynthesized from L-ascorbic acid (vitamin C) during early berry development, accumulating in vacuoles to maintain pH balance and contribute to fruit firmness and organoleptic properties.^[23] This acid plays a crucial role in photosynthesis and stress response in V. vinifera, aiding carbon fixation and protection against oxidative damage.^[24] During natural fermentation processes in winemaking, potassium ions from grape juice bind with bitartrate ions, leading to the precipitation of potassium bitartrate crystals, commonly called "wine diamonds," which form on barrel walls or in bottled wine under cold conditions.^[4] Beyond grapes, bitartrate appears in trace amounts in other fruits as part of their organic acid profile. Tamarinds (Tamarindus indica) contain significant tartaric acid, up to 10-15% of dry weight, often as potassium and calcium salts.^[10] Berries such as strawberries exhibit low levels of tartaric acid (around 400-500 μg/g fresh weight), contributing to their tart flavor alongside citric and malic acids.^[25] Pineapples and other fruits like bananas, apples, and cherries also harbor minor quantities of tartaric acid, typically less than 1% of total acids, supporting metabolic functions similar to those in grapes.^[17]

Synthetic Production

Potassium bitartrate, a common bitartrate compound with the formula \ce{KC4H5O6}, is primarily produced industrially as a byproduct of winemaking through the crystallization of tartaric acid salts from wine lees or argol deposits. Wine lees, consisting of sediment from fermentation including dead yeast and grape residues, are extracted with hot water to dissolve the potassium bitartrate, followed by filtration to remove solids and cooling to 15°C, which induces precipitation of the crystals. This process yields high-purity cream of tartar (>99.5%) without the use of additional reagents, leveraging the natural presence of tartaric acid in grapes as the starting material. On an industrial scale, this method dominates production, recovering significant quantities from wine industry waste and providing an economical source for commercial applications. Synthetic production of bitartrate compounds begins with the chemical synthesis of tartaric acid, followed by partial neutralization to form the acid salt. One established route involves the oxidation of maleic acid or its anhydride using hydrogen peroxide in the presence of a catalyst like sodium tungstate, producing DL-tartaric acid through epoxidation and subsequent hydrolysis. The resulting tartaric acid (\ce{C4H6O6}) is then partially neutralized with a base such as potassium hydroxide or potassium carbonate to yield potassium bitartrate; for instance, adding one equivalent of KOH neutralizes only one acidic hydrogen, forming \ce{KC4H5O6} and water via the reaction \ce{C4H6O6 + KOH -> KC4H5O6 + H2O}. This laboratory method controls pH to approximately 2-3 to ensure the monobasic salt precipitates upon cooling. Purification of synthetic or recovered bitartrate typically involves filtration of the precipitate to separate it from the mother liquor, followed by recrystallization from hot water to enhance purity and remove impurities like excess base or unreacted tartaric acid. Drying under vacuum or mild heat completes the process, yielding stable, white crystalline product suitable for further use. While synthetic routes from maleic acid derivatives enable production independent of natural sources, the wine byproduct method remains predominant due to cost efficiency and sustainability.

Applications

Food and Beverage Uses

Potassium bitartrate, commonly known as cream of tartar, serves as a key ingredient in various food and beverage applications due to its acidic properties and ability to act as a stabilizer and leavening agent. In baking, it stabilizes whipped egg whites by lowering the pH, which helps maintain structure and volume in items like meringues and angel food cakes.^[26] This stabilization prevents the collapse of foams during cooking, ensuring a light texture. Additionally, in confectionery, cream of tartar inhibits sugar crystallization in syrups, candies, and caramels by promoting the inversion of sucrose into glucose and fructose, resulting in smoother textures.^[27] As a leavening agent, potassium bitartrate reacts with baking soda (sodium bicarbonate) in the presence of moisture and heat to produce carbon dioxide gas, which causes baked goods to rise and become tender.^[28] This acid-base reaction is fundamental to single-acting baking powders, where cream of tartar provides the necessary acidity to neutralize the soda and release the gas efficiently. Historically, its use in baking dates back to the 19th century, when it was combined with baking soda to create early forms of baking powder, revolutionizing home baking by simplifying the leavening process.^[29] In beverages, potassium bitartrate adjusts acidity levels to enhance flavor balance and tartness, particularly in wines and soft drinks.^[4]^[30] In winemaking, it is employed to prevent the precipitation of tartrate crystals in bottled wines through cold stabilization processes, where excess bitartrate is induced to form and then removed, avoiding unsightly deposits during storage.^[31] Derived as a byproduct from wine fermentation, this application recycles natural tartaric acid residues into a functional additive. Potassium bitartrate holds regulatory approval as a Generally Recognized as Safe (GRAS) substance by the U.S. Food and Drug Administration under 21 CFR 184.1077, and it is designated as food additive E336 in the European Union, authorized in specific food categories for acidity regulation and stabilization as of 2024 per Commission Regulation (EU) 2024/1451.^[32]^[33]

Industrial and Pharmaceutical Uses

In pharmaceuticals, bitartrate serves as a counterion in the formation of soluble salts for various active ingredients, enhancing their bioavailability and stability in formulations. For instance, hydrocodone bitartrate is a key component in opioid analgesics, where the bitartrate anion aids in achieving the desired solubility and pH compatibility in syrups and tablets.^[34] Potassium bitartrate itself acts as a buffering agent and stabilizer in some pharmaceutical preparations, including laxatives and diuretics, helping to maintain formulation integrity.^[5] In analytical chemistry, bitartrate functions as a chiral resolving agent for the separation of enantiomers through the formation of diastereomeric salts, leveraging the inherent chirality of the tartrate backbone. This method involves reacting a racemic mixture of chiral bases with tartaric acid or its bitartrate salts to produce separable diastereomers based on differences in solubility or melting points, a technique widely applied in the purification of pharmaceutical intermediates.^[35] For example, L-tartaric acid derivatives, including bitartrates, have been employed to resolve racemic amines like pregabalin precursors, enabling enantioselective crystallization.^[36] Industrially, bitartrate compounds are employed as buffering agents in electroplating baths to stabilize pH and improve deposit quality. Bitartrate salts act as complexing agents in non-cyanide copper and nickel plating solutions, preventing metal precipitation and enhancing adhesion on substrates like electronics components.^[37] In cosmetics, potassium bitartrate serves as a pH buffer and emulsion stabilizer, contributing to product shelf life and texture in formulations like lotions and bath products.^[38] Additionally, it functions as a color modifier and stabilizer in natural dye processes, shifting hues in textile and mordant applications by adjusting acidity.^[39] In veterinary medicine, potassium bitartrate has historical applications as a laxative and cathartic, administered in suppository form for gastrointestinal relief in animals.^[40] Regarding safety, bitartrate exhibits low acute toxicity, with oral LD50 values exceeding 22 g/kg in rats, but concentrated forms may cause mild eye and skin irritation upon direct contact.^[41] Inhalation of dust can lead to respiratory discomfort, though systemic effects are minimal under normal handling conditions.^[42]

References

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3-Carboxy-2,3-dihydroxypropanoate | C4H5O6 - PubChem - NIH
3-carboxy-2,3-dihydroxypropanoate, also known as bitartrate, is a tartaric acid anion with formula C4H5O6- and a molecular weight of 149.08 g/mol.
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The meaning of BITARTRATE is an acid tartrate.Missing: chemistry | Show results with:chemistry
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BITARTRATE definition in American English - Collins Dictionary
(not in technical usage) a salt or ester of tartaric acid containing the monovalent group -HC4H4O6 or the ion HC4H4O6–. Also called: hydrogen tartrate.<|control11|><|separator|>
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Potassium bitartrate is an organic potassium salt of L-tartaric acid. It is a by-product of winemaking and occurs naturally in grapes, the major fruit used ...
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Dec 3, 2015 · Potassium bitartate, also referred to as potassium acid tartrate or cream of tartar, is the potassium acid salt of l-( + )-tartaric acid. It is ...
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May 24, 2018 · Potassium bitartrate, also known as potassium hydrogen tartrate, is a compound once found in many kitchens under the guise of cream of tartar.
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Potassium Hydrogen Tartrate - an overview | ScienceDirect Topics
Potassium hydrogen tartrate is a by-product of the wine-making industry, commonly found as a deposit during the fermentation of grape juice, and is used in the ...
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Potassium Bitartrate - an overview | ScienceDirect Topics
This natural fatty acid, usually supplied as a potassium salt, is food safe and frequently used in the nutrition industry. It is often added to enhance ...
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- **IUPAC Name**: 3-Carboxy-2,3-dihydroxypropanoate
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Tartaric acid is defined as a naturally occurring dicarboxylic acid with two stereocenters, existing as a pair of enantiomers and an achiral meso compound, ...
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Bitartrate definition: a tartrate in which only one of the two acidic hydrogen atoms of tartaric acid is replaced by a metal or positive group; ...
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Butanedioic acid, 2,3-dihydroxy- (2R,3R)-, monosodium salt: Does not have an individual approval but may be used as a component in a product covered by a group ...
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98% Acid potassium tartrate Butanedioic acid, 2,3-dihydroxy- (2R,3R)-, monopotassium salt Butanedioic acid, 2,3-dihydroxy- (θ-(θ,θ))-, monopotassium salt
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Solubility in water: 1g/162 mL. Specific Gravity/Density: 1.950g/cm3. Molecular Formula: C4H5O6K. Page 3. Molecular Weight: 188.18. Section 10 - Stability and ...
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### Summary of Physical and Chemical Properties (Section 9)
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Potassium hydrogen tartrate is only moderately soluble ill water, and its saturated solution (about. 0.034 molar at 25° C) is a convenient standa,rd with. pH ...<|separator|>
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2.1). It is a diprotic acid, whose pKa (at 25°C) are reported to be 2.98 and 4.34, respectively, for the dissociation of the first and the second acidic ...
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... in water. Its solubility equilibrium in water is: KHC4H4O6 (s) K+ (aq) + HC4H4O6- (aq). The HC4H4O6- (aq) ion contains one acidic hydrogen, so that the ...
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This study aimed to determine the percentage of reduction of lead and cadmium by chelating agents (potassium tartrate and potassium citrate)
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[22]
https://www.pnas.org/doi/10.1073/pnas.0510864103
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L-tartrate, the isomer present in grapes, can be used for carbon fixation by Agrobacterium vitis; a bacterium that harbors genes for TA-metabolizing enzymes and ...
[25]
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Dec 9, 2009 · TA is a commercially important product in the wine industry and due to its acidifying effect on crushed juice it can influence the organoleptic ...
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Compositional Variation in Sugars and Organic Acids at Different ...
Jan 27, 2012 · The strawberry, sweet cherry and mulberry mainly contained tartaric, citric and ascorbic acids in the range of 16–55, 70–1934 and 11–132 mg/100 ...
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Feb 27, 2023 · Cream of tartar is an added safeguard; it gives more stability to whipped egg whites, therefore setting up your meringue for success.
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Cream of Tarter stabilizes whipped egg whites in meringues and cakes, prevent sugar crystallization in candies and caramel, and much more.
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The mixing of sodium bicarbonate and cream of tartar marked the introduction of baking powder. The action of the two chemicals—initially marketed in twin ...
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Tartrate stabilization is conducted to prevent the precipitation of potassium bitartrate (KHT) and (less commonly) calcium tartrate (CaT) from precipitating ...
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The affirmation of this ingredient as generally recognized as safe (GRAS) as a direct human food ingredient is based upon the following current good ...Missing: E336 | Show results with:E336
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Rating 5.0 (7) Cream of Tartar is a higher-grade of Potassium Bitartrate designed for cosmetic use. This product can be used to harden your bubble cakes, bubble scoops and ...
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Monopotassium tartrate has several uses in natural dyeing. ... A colour modifier, shifting the colours with some natural dyes. For example, cochineal will shift ...
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potassium bitartrate Veterinary Use | Indications/Contra | FAERs-F | FAERs-M | Orange Bk | BioActivity | · Description: · Drug dosage: · ADMET properties:.Missing: animal feed<|control11|><|separator|>
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TOXICITY. IRRITATION. Oral (rat) LDLo: 22000 mg/kg. Nil Reported ! Asthma-like symptoms may continue for months or even years after exposure to the material ...
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