Chemistry:Bicarbonate

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Short description: Polyatomic anion

| ImageFile1 = Bicarbonate-resonance.png | ImageFile1_Ref = | ImageSize1 = 121 | ImageName1 = Skeletal formula of bicarbonate with the explicit hydrogen added | ImageFile2 = Bicarbonate-ion-3D-balls.png | ImageFile2_Ref = | ImageSize2 = 121 | ImageName2 = Ball and stick model of bicarbonate | SystematicName = Hydroxidodioxidocarbonate(1−)[1]

| OtherNames =

  • Hydrogencarbonate[1]
  • Hydrocarbonate

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3D model (JSmol)

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| 3903504 |- | ChEBI

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| 49249 |-

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|- | Section2 = ! colspan=2 style="background: #f8eaba; text-align: center;" |Properties

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| HCO3

|- | Molar mass

| 61.0168 g mol−1

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| log P | −0.82 |-


| Acidity (pKa) | 10.3 |- | Basicity (pKb) | 7.7 |- | Conjugate acid | Carbonic acid |- | Conjugate base | Carbonate |- }}

In inorganic chemistry, bicarbonate (IUPAC-recommended nomenclature: hydrogencarbonate[2]) is an intermediate form in the deprotonation of carbonic acid. It is a polyatomic anion with the chemical formula HCO3.

Bicarbonate serves a crucial biochemical role in the physiological pH buffering system.[3]

The term "bicarbonate" was coined in 1814 by the English chemist William Hyde Wollaston.[4][5] The name lives on as a trivial name.

Chemical properties

The bicarbonate ion (hydrogencarbonate ion) is an anion with the empirical formula HCO3 and a molecular mass of 61.01 daltons; it consists of one central carbon atom surrounded by three oxygen atoms in a trigonal planar arrangement, with a hydrogen atom attached to one of the oxygens. It is isoelectronic with nitric acid HNO3. The bicarbonate ion carries a negative one formal charge and is an amphiprotic species which has both acidic and basic properties. It is both the conjugate base of carbonic acid H2CO3; and the conjugate acid of CO2−3, the carbonate ion, as shown by these equilibrium reactions:

CO2−3 + 2 H2O ⇌ HCO3 + H2O + OH ⇌ H2CO3 + 2 OH
H2CO3 + 2 H2O ⇌ HCO3 + H3O+ + H2O ⇌ CO2−3 + 2 H3O+.

A bicarbonate salt forms when a positively charged ion attaches to the negatively charged oxygen atoms of the ion, forming an ionic compound. Many bicarbonates are soluble in water at standard temperature and pressure; in particular, sodium bicarbonate contributes to total dissolved solids, a common parameter for assessing water quality.[6]

Physiological role

CO2 produced as a waste product of the oxidation of sugars in the mitochondria reacts with water in a reaction catalyzed by carbonic anhydrase to form H2CO3, which is in equilibrium with the cation H+ and anion HCO3. It is then carried to the lung, where the reverse reaction occurs and CO2 gas is released. In the kidney (left), cells (green) lining the proximal tubule conserve bicarbonate by transporting it from the glomerular filtrate in the lumen (yellow) of the nephron back into the blood (red). The exact stoichiometry in the kidney is omitted for simplicity.

Bicarbonate (HCO3) is a vital component of the pH buffering system[3] of the human body (maintaining acid–base homeostasis). 70%–75% of CO2 in the body is converted into carbonic acid (H2CO3), which is the conjugate acid of HCO3 and can quickly turn into it.

With carbonic acid as the central intermediate species, bicarbonate – in conjunction with water, hydrogen ions, and carbon dioxide – forms this buffering system, which is maintained at the volatile equilibrium[3] required to provide prompt resistance to pH changes in both the acidic and basic directions. This is especially important for protecting tissues of the central nervous system, where pH changes too far outside of the normal range in either direction could prove disastrous (see acidosis or alkalosis). Recently it has been also demonstrated that cellular bicarbonate metabolism can be regulated by mTORC1 signaling.[7]

Additionally, bicarbonate plays a key role in the digestive system. It raises the internal pH of the stomach, after highly acidic digestive juices have finished in their digestion of food. Bicarbonate also acts to regulate pH in the small intestine. It is released from the pancreas in response to the hormone secretin to neutralize the acidic chyme entering the duodenum from the stomach.[8]

Bicarbonate in the environment

Bicarbonate is the dominant form of dissolved inorganic carbon in sea water,[9] and in most fresh waters. As such it is an important sink in the carbon cycle.

Some plants like Chara utilize carbonate and produce calcium carbonate (CaCO3) as result of biological metabolism.[10]

In freshwater ecology, strong photosynthetic activity by freshwater plants in daylight releases gaseous oxygen into the water and at the same time produces bicarbonate ions. These shift the pH upward until in certain circumstances the degree of alkalinity can become toxic to some organisms or can make other chemical constituents such as ammonia toxic. In darkness, when no photosynthesis occurs, respiration processes release carbon dioxide, and no new bicarbonate ions are produced, resulting in a rapid fall in pH.

The flow of bicarbonate ions from rocks weathered by the carbonic acid in rainwater is an important part of the carbon cycle.

Other uses

The most common salt of the bicarbonate ion is sodium bicarbonate, NaHCO3, which is commonly known as baking soda. When heated or exposed to an acid such as acetic acid (vinegar), sodium bicarbonate releases carbon dioxide. This is used as a leavening agent in baking.

Ammonium bicarbonate is used in digestive biscuit manufacture.

Diagnostics

In diagnostic medicine, the blood value of bicarbonate is one of several indicators of the state of acid–base physiology in the body. It is measured, along with chloride, potassium, and sodium, to assess electrolyte levels in an electrolyte panel test (which has Current Procedural Terminology, CPT, code 80051).

The parameter standard bicarbonate concentration (SBCe) is the bicarbonate concentration in the blood at a PaCO2 of 40 mmHg (5.33 kPa), full oxygen saturation and 36 °C.[11]

Reference ranges for blood tests, comparing blood content of bicarbonate (shown in blue at right) with other constituents.

Bicarbonate compounds

See also

References

  1. 1.0 1.1 "hydrogencarbonate (CHEBI:17544)". Chemical Entities of Biological Interest (ChEBI). UK: European Institute of Bioinformatics. IUPAC Names. https://www.ebi.ac.uk/chebi/searchId.do?chebiId=17544. 
  2. Nomenclature of Inorganic Chemistry IUPAC Recommendations 2005, IUPAC, p. 137, https://iupac.org/wp-content/uploads/2016/07/Red_Book_2005.pdf 
  3. 3.0 3.1 3.2 "Clinical correlates of pH levels: bicarbonate as a buffer". Biology.arizona.edu. October 2006. http://www.biology.arizona.edu/biochemistry/problem_sets/medph/intro.html. 
  4. William Hyde Wollaston (1814) "A synoptic scale of chemical equivalents", Philosophical Transactions of the Royal Society, 104: 1-22. On page 11, Wollaston coins the term "bicarbonate": "The next question that occurs relates to the composition of this crystallized carbonate of potash, which I am induced to call bi-carbonate of potash, for the purpose of marking more decidedly the distinction between this salt and that which is commonly called a subcarbonate, and in order to refer at once to the double dose of carbonic acid contained in it."
  5. "Baking Soda". Argonne National Laboratory. http://www.newton.dep.anl.gov/askasci/chem99/chem99492.htm. 
  6. Geor, Raymond J.; Coenen, Manfred; Harris, Pat (31 January 2013) (in en). Equine Applied and Clinical Nutrition: Health, Welfare and Performance. Elsevier Health Sciences. p. 90. ISBN 978-0-7020-5418-1. "The most common indicator of water quality is the concentration of total dissolved solids (TDS)" 
  7. "The mTORC1-SLC4A7 axis stimulates bicarbonate import to enhance de novo nucleotide synthesis". Molecular Cell 82 (1): 3284–3298.e7. June 2022. doi:10.1016/j.molcel.2022.06.008. PMID 35772404. 
  8. Berne & Levy, Principles of Physiology
  9. "The chemistry of ocean acidification : OCB-OA" (in en-NZ). Woods Hole Oceanographic Institution. 24 September 2012. http://www.whoi.edu/OCB-OA/page.do?pid=112136. 
  10. Pełechaty, Mariusz; Pukacz, Andrzej; Apolinarska, Karina; Pełechata, Aleksandra; Siepak, Marcin (June 2013). Porta, Giovanna Della. ed. "The significance of Chara vegetation in the precipitation of lacustrine calcium carbonate" (in en). Sedimentology 60 (4): 1017–1035. doi:10.1111/sed.12020. Bibcode2013Sedim..60.1017P. https://onlinelibrary.wiley.com/doi/10.1111/sed.12020. 
  11. Acid Base Balance (page 3)

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