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Organosulfate

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(Redirected from Sulfate ester)
Generic structure of an organosulfate, where R is an organyl group

In organosulfur chemistry, organosulfates are a class of organic compounds sharing a common functional group with the structure R−O−SO3. The SO4 core is a sulfate group and the R group is any organic residue. All organosulfates are formally esters derived from alcohols and sulfuric acid (H2SO4) although many are not prepared in this way. Many sulfate esters are used in detergents, and some are useful reagents. Alkyl sulfates consist of a hydrophobic hydrocarbon chain, a polar sulfate group (containing an anion) and either a cation or amine to neutralize the sulfate group. Examples include: sodium lauryl sulfate (also known as sulfuric acid mono dodecyl ester sodium salt) and related potassium and ammonium salts.

Applications

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Alkyl sulfates are commonly used as anionic surfactants in liquid soaps and detergents used to clean wool, as surface cleaners, and as active ingredients in laundry detergents, shampoos and conditioners. They can also be found in household products such as toothpaste, antacids, cosmetics and foods. Generally they are found in consumer products at concentrations ranging from 3-20%. In 2003 approximately 118,000 t/a of alkyl sulfates were used in the US.[1]

Synthetic organosulfates

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A common example is sodium lauryl sulfate, with the formula CH3(CH2)11OSO3Na. Also common in consumer products are the sulfate esters of ethoxylated fatty alcohols such as those derived from lauryl alcohol. An example is sodium laureth sulfate, an ingredient in some cosmetics.[2]

Alkylsulfate can be produced from alcohols, which in turn are obtained by hydrogenation of animal or vegetable oils and fats or using the Ziegler process or through oxo synthesis. If produced from oleochemical feedstock or the Ziegler process, the hydrocarbon chain of the alcohol will be linear. If derived using the oxo process, a low level of branching will appear usually with a methyl or ethyl group at the C-2 position, containing even and odd amounts of alkyl chains.[3] These alcohols react with chlorosulfuric acid:

ClSO3H + RCH2OH → RCH2OSO3H + HCl

Alternatively, alcohols can be converted to the half sulfate esters using sulfur trioxide:[4]

SO3 + RCH2OH → RCH2OSO3H

Laboratory routes

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Specialized organosulfates can be prepared by the Elbs persulfate oxidation of phenols and the Boyland–Sims oxidation of anilines.

Dialkylsulfates

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Structure of a diorganosulfate.

A less common family of organosulfates have the formula RO-SO2-OR'. They are prepared from sulfuric acid and the alcohol. The main examples are diethyl sulfate and dimethyl sulfate, colourless liquids that are used as reagents in organic synthesis. These compounds are potentially dangerous alkylating agents. Dialkylsulfates do not occur in nature.[5]

Natural sulfate esters

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Heparin is a medication and naturally occurring organosulfate.

Several classes of sulfate esters exist in nature. Especially common are sugar derivatives such as keratan sulfate, chondroitin sulfate, and the anticoagulant heparin.[6] Post-translational modifications of some proteins entail sulfation, often at the phenol group of tyrosine residues.[7] A steroidal sulfate is estradiol sulfate, a latent precursor to the hormone estrogen.

A major portion of soil sulfur is in the form of sulfate esters.[8]

Metabolism

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Sulfate is an inert anion, so nature activates it by the formation of ester derivative of adenosine 5'-phosphosulfate (APS) and 3'-phosphoadenosine-5'-phosphosulfate (PAPS). Many organisms utilize these reactions for metabolic purposes or for the biosynthesis of sulfur compounds required for life.[9] The formation and hydrolysis of natural sulfate esters are catalyzed by sulfatases (aka sulfohydrolases).[5]

Safety

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Because they are widely used in commercial products, the safety aspects of organosulfates are heavily investigated.[10]

Human Health

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Alkyl sulfates if ingested are well-absorbed and are metabolized into a C3, C4 or C5 sulfate and an additional metabolite. The highest irritant of the alkyl sulfates is sodium laurylsulfate, with the threshold before irritation at a concentration of 20%. Surfactants in consumer products are typically mixed, reducing likelihood of irritation. According to OECD TG 406, alkyl sulfates in animal studies were not found to be skin sensitizers.[10][11]

Laboratory studies have not found alkyl sulfates to be genotoxic, mutagenic or carcinogenic. No long-term reproductive effects have been found.[12]

Environment

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The primary disposal of alkyl sulfate from used commercial products is wastewater. The concentration of alkylsulfates in effluent from waste water treatment plants (WWTP) has been measured at 10 micrograms per litre (5.8×10−9 oz/cu in) and lower. Alkyl sulfates biodegrade easily, even starting likely before reaching the WWTP. Once at the treatment plant, they are rapidly removed by biodegradation. Invertebrates were found to be the most-sensitive trophic group to alkyl sulfates. Sodium laurylsulfate tested on Uronema parduczi, a protozoan, was found to have the lowest effect value with the 20 h-EC5 being 0.75 milligrams per litre (2.7×10−8 lb/cu in). Chronic exposure tests with C12 to C18 with the invertebrate Ceriodaphnia dubia found the highest toxicity is with C14 (NOEC was 0.045 mg/L).

In terms of thermal stability, alkyl sulfates degrade well before reaching their boiling point due to low vapor pressure (for C8-18 from 10-11 to 10-15 hPa). Soil sorption is proportional to carbon chain length, with a length of 14 and more having the highest sorption rate. Soil concentrations have been found to vary from 0.0035 to 0.21 milligrams per kilogram (5.6×10−8 to 3.4×10−6 oz/lb) dw.

References

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  1. ^ CEH (October 2004). "Surfactants, household detergents and their raw materials". CEH Marketing Research Report.
  2. ^ Eduard Smulders, Wolfgang von Rybinski, Eric Sung, Wilfried Rähse, Josef Steber, Frederike Wiebel, Anette Nordskog "Laundry Detergents" in Ullmann's Encyclopedia of Industrial Chemistry 2007, Wiley-VCH, Weinheim. doi:10.1002/14356007.a08_315.pub2.
  3. ^ Klaus Noweck, Wolfgang Grafahrend, "Fatty Alcohols" in Ullmann’s Encyclopedia of Industrial Chemistry 2006, Wiley-VCH, Weinheim. doi:10.1002/14356007.a10_277.pub2
  4. ^ Holmberg, Krister (2019). "Surfactants". Ullmann's Encyclopedia of Industrial Chemistry. pp. 1–56. doi:10.1002/14356007.a25_747.pub2. ISBN 978-3-527-30673-2.
  5. ^ a b Cleland, W. Wallace; Hengge, Alvan C. (2006). "Enzymatic Mechanisms of Phosphate and Sulfate Transfer". Chemical Reviews. 106 (8): 3252–3278. doi:10.1021/cr050287o. PMID 16895327.
  6. ^ J. W. Fitzgerald (1976). "Sulfate ester formation and hydrolysis: a potentially important yet often ignored aspect of the sulfur cycle of aerobic soils". Bacteriological Reviews. 40 (3): 698–721. doi:10.1128/br.40.3.698-721.1976. PMC 413977. PMID 791238.
  7. ^ Moore, Kevin L. (2003). "The Biology and Enzymology of Protein Tyrosine O-Sulfation". Journal of Biological Chemistry. 278 (27): 24243–24246. doi:10.1074/jbc.R300008200. PMID 12730193.
  8. ^ Scherer, H.W. (2001). "Sulphur in crop production — invited paper". European Journal of Agronomy. 14 (2): 81–111. doi:10.1016/S1161-0301(00)00082-4.
  9. ^ M. T. Madigan, J. M. Martinko, J. Parker "Brock Biology of Microorganisms" Prentice Hall, 1997. ISBN 0-13-520875-0.
  10. ^ a b SDA/Alkylsulfate Consortium (2007). "SIDS Initial Assessment Profile. SIAM 25: Alkyl Sulfates, Alkane Sulfonates, and α-Olefin sulfonates" (PDF). OECD SIDS. Helsinki. Archived from the original (PDF) on 2016-03-03. Retrieved 2011-10-14.
  11. ^ DE/ICCA (2009). "SIDS Initial Assessment Profile SIAM 25: Alkyl Sulfates, Alkane Sulfonates, and α-Olefin sulfonates". OECD.
  12. ^ Wibbertmann, A; Mangelsdorf, I.; Gamon, K.; Sedlak, R. (2011). "Toxicological properties and risk assessment of the anionic surfactants category: Alkyl sulfates, primary alkane sulfonates, and α-Olefin sulfonate". Ecotoxicology and Environmental Safety. 74 (5): 1089–1106. doi:10.1016/j.ecoenv.2011.02.007. PMID 21463896.