Acrolein (systematic name: propenal) is the simplest
unsaturated aldehyde. It is a colorless liquid with a foul and acrid aroma. The smell of burnt fat (as when
cooking oil is heated to its
smoke point) is caused by
glycerol in the burning fat breaking down into acrolein. It is produced industrially from
propene and mainly used as a
biocide and a building block to other chemical compounds, such as the
amino acidmethionine.
History
Acrolein was first named and characterized as an aldehyde by the Swedish chemist
Jöns Jacob Berzelius in 1839. He had been working with it as a thermal degradation product of
glycerol, a material used in the manufacture of soap. The name is a contraction of 'acrid' (referring to its pungent smell) and 'oleum' (referring to its oil-like consistency). In the 20th century, acrolein became an important intermediate for the industrial production of
acrylic acid and acrylic plastics.[4]
About 500,000 tons of acrolein are produced in this way annually in North America, Europe, and Japan. Additionally, all
acrylic acid is produced via the transient formation of acrolein.
Propane represents a promising but challenging feedstock for the synthesis of acrolein (and acrylic acid).The main challenge is in fact the overoxidation to this acid.
When
glycerol (also called glycerin) is heated to 280 °C, it decomposes into acrolein:
(CH2OH)2CHOH → CH2=CHCHO + 2 H2O
This route is attractive when glycerol is co-generated in the production of biodiesel from vegetable oils or animal fats. The dehydration of glycerol has been demonstrated but has not proven competitive with the route from
petrochemicals.[6][7]
Niche or laboratory methods
The original industrial route to acrolein, developed by Degussa, involves condensation of
formaldehyde and
acetaldehyde:
HCHO + CH3CHO → CH2=CHCHO + H2O
Acrolein may also be produced on lab scale by the action of
potassium bisulfate on glycerol (glycerine).[8]
Acrolein was used in warfare due to its irritant and blistering properties. The French used the chemical in their hand grenades and artillery shells[9] during
World War I under the name "Papite".[10]
Biocide
Acrolein is mainly used as a contact herbicide to control submersed and floating weeds, as well as algae, in irrigation canals. It is used at a level of 10 ppm in irrigation and recirculating waters. In the oil and gas industry, it is used as a biocide in drilling waters, as well as a scavenger for hydrogen sulfide and
mercaptans.[5]
Acrolein will polymerize in the presence of oxygen and in water at concentrations above 22%. The color and texture of the polymer depends on the conditions. The polymer is a clear, yellow solid. In water, it will form a hard, porous plastic.[citation needed]
Acrolein has been used as a fixative in preparation of biological specimens for
electron microscopy.[12]
Health risks
Acrolein is toxic and is a strong irritant for the skin, eyes, and nasal passages.[5] The main metabolic pathway for acrolein is the
alkylation of
glutathione. The
WHO suggests a "tolerable oral acrolein intake" of 7.5 μg per day per kg of body weight. Although acrolein occurs in
French fries (and other fried foods), the levels are only a few μg per kg.[13] In response to occupational exposures to acrolein, the US
Occupational Safety and Health Administration has set a
permissible exposure limit at 0.1 ppm (0.25 mg/m3) at an eight-hour time-weighted average.[14] Acrolein acts in an immunosuppressive manner and may promote regulatory cells,[15] thereby preventing the generation of allergies on the one hand, but also increasing the risk of cancer.
In terms of the "noncarcinogenic health quotient"[jargon] for components in cigarette smoke, acrolein dominates, contributing 40 times more than the next component,
hydrogen cyanide.[20] The acrolein content in cigarette smoke depends on the type of cigarette and added
glycerin, making up to 220 μg acrolein per cigarette.[21][22] Importantly, while the concentration of the constituents in mainstream smoke can be reduced by filters, this has no significant effect on the composition of the side-stream smoke where acrolein usually resides, and which is inhaled by
passive smoking.[23][24]E-cigarettes, used normally, only generate "negligible" levels of acrolein (less than 10 μg "per puff").[25][26]
Chemotherapy metabolite
Cyclophosphamide and
ifosfamide treatment results in the production of acrolein.[27] Acrolein produced during cyclophosphamide treatment collects in the urinary bladder and if untreated can cause hemorrhagic cystitis.
Endogenous production
Acrolein is a component of
reuterin.[28] Reuterin can be produced by gut microbes when glycerol is present. Microbe-produced reuterin is a potential resource of acrolein.[29]
Analytical methods
The "acrolein test" is for the presence of
glycerin or
fats. A sample is heated with
potassium bisulfate, and acrolein is released if the test is positive. When a fat is heated strongly in the presence of a dehydrating agent such as potassium bisulfate (KHSO 4), the glycerol portion of the molecule is dehydrated to form the unsaturated
aldehyde, acrolein (CH2=CH–CHO), which has the odor peculiar to burnt cooking grease. More modern methods exist.[13]
In the US, EPA methods 603 and 624.1 are designed to measure acrolein in industrial and municipal
wastewater streams.[30][31]
^Jan F. Stevens and Claudia S. Maier, "Acrolein: Sources, metabolism, and biomolecular interactions relevant to human health and disease", Mol Nutr Food Res. 2008 Jan; 52(1): 7–25.
^Martin, Andreas; Armbruster, Udo; Atia, Hanan (2012). "Recent developments in dehydration of glycerol toward acrolein over heteropolyacids". European Journal of Lipid Science and Technology. 114 (1): 10–23.
doi:
10.1002/ejlt.201100047.
^Cunningham FH, Fiebelkorn S, Johnson M, Meredith C. A novel application of the Margin of Exposure approach: segregation of tobacco smoke toxicants. Food Chem Toxicol. 2011 Nov;49(11):2921-33. doi: 10.1016/j.fct.2011.07.019. Epub 2011 Jul 23.
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^Li L, Jiang L, Geng C, Cao J, Zhong L. The role of oxidative stress in acrolein-induced DNA damage in HepG2 cells. Free Radic Res. 2008 Apr;42(4):354-61. doi: 10.1080/10715760802008114
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^Haussmann, Hans-Juergen (2012). "Use of Hazard Indices for a Theoretical Evaluation of Cigarette Smoke Composition". Chem. Res. Toxicol. 25 (4): 794–810.
doi:
10.1021/tx200536w.
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^Paci, A; Rieutord, A; Guillaume, D; et al. (March 2000). "Quantitative high-performance liquid chromatography chromatographic determination of acrolein in plasma after derivatization with Luminarin 3". Journal of Chromatography B. 739 (2): 239–246.
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