Tartaric acid is a white, crystalline organic acid that occurs naturally in many fruits, most notably in grapes but also in tamarinds, bananas, avocados, and citrus. However, chemical extraction and purification was developed in 1769 by the Swedish chemist Carl Wilhelm Scheele.
Tartaric acid played an important role in the discovery of chemical chirality. This property of tartaric acid was first observed in 1832 by Jean Baptiste Biot, who observed its ability to rotate polarized light. Louis Pasteur continued this research in 1847 by investigating the shapes of sodium ammonium tartrate crystals, which he found to be chiral. By manually sorting the differently shaped crystals, Pasteur was the first to produce a pure sample of levotartaric acid.
Stereochemistry
Naturally occurring form of the acid is dextro tartaric acid or <small>L</small>-(+)-tartaric acid (obsolete name d-tartaric acid). Because it is available naturally, it is cheaper than its enantiomer and the meso isomer. The dextro and levo prefixes are archaic terms. Modern textbooks refer to the natural form as (2R,3R)-tartaric acid (<small>L</small>-(+)-tartaric acid), and its enantiomer as (2S,3S)-tartaric acid (D-(−)-tartaric acid). The meso diastereomer is referred to as (2R,3S)-tartaric acid or (2S,3R)-tartaric acid.
- Dextro and levo form monoclinic sphenoidal crystals and orthorhombic crystals.
- Racemic tartaric acid (racemic acid) forms monoclinic and triclinic crystals (space group P).
- Anhydrous meso tartaric acid form two anhydrous polymorphs: triclinic and orthorhombic.
- Monohydrated meso tartaric acid crystallizes as monoclinic and triclinic polymorphys depending on the temperature at which crystallization from aqueous solution occurs.
Tartaric acid in Fehling's solution binds to copper(II) ions, preventing the formation of insoluble hydroxide salts.
{| class="wikitable" style="text-align:center;"
! colspan="2" | <small>DL</small>-tartaric acid (racemic acid) <small>(when in 1:1 ratio)</small>
! rowspan="2" | mesotartaric acid
|-
! dextrotartaric acid<br/><small>(L-(+)-tartaric acid)</small>
! levotartaric acid<br/><small>(D-(−)-tartaric acid)</small>
|-
| width="150" | 150px|class=skin-invert-image
| width="150" | 150px|class=skin-invert-image
| width="270" | 150 px|class=skin-invert-image
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{| class="wikitable"
|+ Forms of tartaric acid
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! Common name
! Tartaric acid
! Levotartaric acid
! Dextrotartaric acid
! Mesotartaric acid
! Racemic acid
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! Synonyms
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| style="vertical-align:top" | (2S,3S)-tartaric acid <br/> (S,S)-tartaric acid <br/> (−)-tartaric acid <br/> l-tartaric acid <small>(obsolete)</small> <br/> levotartaric acid <br/> -tartaric acid <br/> -threaric acid <br/>("unnatural isomer")
| style="vertical-align:top" | (2R,3R)-tartaric acid <br/> (R,R)-tartaric acid <br/> (+)-tartaric acid <br/> d-tartaric acid <small>(obsolete)</small> <br/> -tartaric acid <br/> -threaric acid <br/>("natural isomer")
| style="vertical-align:top" | (2R,3S)-tartaric acid <br/> meso-tartaric acid <br/> erythraric acid
| style="vertical-align:top" | rac-(2R,3S)-tartaric acid <br/> (2RS,3SR)-tartaric acid <br/> (±)-tartaric acid <br/> -tartaric acid <br/> dl-tartaric acid <small>(obsolete)</small> <br/> paratartaric acid <br/> uvic acid
|-
! PubChem
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! EINECS number
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! CAS number
| 526-83-0
| 147-71-7
| 87-69-4
| 147-73-9
| 133-37-9
|}
Production
<small>L</small>-(+)-Tartaric acid
The <small>L</small>-(+)-tartaric acid isomer of tartaric acid is industrially produced in the largest amounts. It is obtained from lees, a solid byproduct of fermentations. The former byproducts mostly consist of potassium bitartrate (). This potassium salt is converted to calcium tartrate () upon treatment with calcium hydroxide ():
:
In practice, higher yields of calcium tartrate are obtained with the addition of calcium sulfate. Calcium tartrate is then converted to tartaric acid by treating the salt with aqueous sulfuric acid:
:
Racemic tartaric acid
Racemic tartaric acid can be prepared in a multistep reaction from maleic acid. In the first step, the maleic acid is epoxidized by hydrogen peroxide using as a catalyst.
:
meso-Tartaric acid can be separated from residual racemic acid by crystallization, the racemate being less soluble.
Reactivity
L-(+)-tartaric acid, can participate in several reactions. As shown the reaction scheme below, dihydroxymalonic acid is produced upon treatment of L-(+)-tartaric acid with hydrogen peroxide in the presence of a ferrous salt.
:HO<sub>2</sub>CCH(OH)CH(OH)CO<sub>2</sub>H + H<sub>2</sub>O<sub>2</sub> → HO<sub>2</sub>CC(OH)C(OH)CO<sub>2</sub>H + 2 H<sub>2</sub>O
Dihydroxymaleic acid can then be oxidized to tartronic acid with nitric acid.
==Derivatives==<!-- This section is linked from Napoleon I of France -->
thumb|Tartar emetic
thumb|Commercially produced tartaric acid
Important derivatives of tartaric acid include:
- Sodium ammonium tartrate, the first material separated into its enantiomers
- cream of tartar (potassium bitartrate), used in cooking
- Rochelle salt (potassium sodium tartrate), which has unusual piezoelectric properties
- tartar emetic (antimony potassium tartrate), a resolving agent. Diisopropyl tartrate is used as a co-catalyst in asymmetric synthesis.
Tartaric acid is a muscle toxin, which works by inhibiting the production of malic acid, and in high doses causes paralysis and death. The median lethal dose (LD<sub>50</sub>) is about 7.5 grams/kg for a human, 5.3 grams/kg for rabbits, and 4.4 grams/kg for mice. Given this figure, it would take over to kill a person weighing with 50% probability, so it may be safely included in many foods, especially sour-tasting sweets. As a food additive, tartaric acid is used as an antioxidant with E number E334; tartrates are other additives serving as antioxidants or emulsifiers.
When cream of tartar is added to water, a suspension results which serves to clean copper coins very well, as the tartrate solution can dissolve the layer of copper(II) oxide present on the surface of the coin. The resulting copper(II)-tartrate complex is easily soluble in water.
Tartaric acid in wine
thumb|Unpurified potassium bitartrate can take on the color of the grape juice from which it was separated.
Tartaric acid may be most immediately recognizable to wine drinkers as the source of "wine diamonds", the small potassium bitartrate crystals that sometimes form spontaneously on the cork or bottom of the bottle. These "tartrates" are harmless, despite sometimes being mistaken for broken glass, and are prevented in many wines through cold stabilization (which is not always preferred since it can change the wine's profile). The tartrates remaining on the inside of aging barrels were at one time a major industrial source of potassium bitartrate.
Tartaric acid plays an important role chemically, lowering the pH of fermenting "must" to a level where many undesirable spoilage bacteria cannot live, and acting as a preservative after fermentation. In the mouth, tartaric acid provides some of the tartness in the wine, although citric and malic acids also play a role.
Tartaric acid in fruits
Grapes and tamarinds have the highest levels of tartaric acid concentration. Other fruits with tartaric acid are bananas, avocados, prickly pear fruit, apples, cherries, papayas, peaches, pears, pineapples, strawberries, mangoes and citrus fruits.
Trace amounts of tartaric acid have been found in cranberries and other berries.
Tartaric acid is also present in the leaves and pods of Pelargonium plants and beans.
Applications
Tartaric acid and its derivatives have a plethora of uses in the field of pharmaceuticals. For example, it has been used in the production of effervescent salts, in combination with citric acid, to improve the taste of oral medications.
A 2022 article expands on the letter with detailed reports of the 2 aforementioned cases of cream of tartar ingestion and 4 new cases of tamarind ingestion. Again, clinical findings were similar. Tamarind is known to contain 8%–18% tartaric acid, much more than the up to 2% (typically 0.35%–1.1%) found in grapes. The authors believe that the assignment of tartaric acid as the culprit also explains the relative lack of incidents from dogs consuming commercial grape juice, jam, and wine, as these go through a process to remove tartrates.
A 2023 study observed tartaric acid toxicity in kidney cells of dogs, but not in human kidney cells.
A 2024 review identified a relationship between grape ingestion and illness in dogs, though the specific type or quantity of grapes that cause toxicity remains unclear. Grape ingestion commonly leads to gastrointestinal and/or renal issues, with treatment depending on the symptoms; outcomes can vary.
References
External links
- PDB file for MSE