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Trichloroethylene

February 16, 2024

"Trichlor" redirects here. For the reagent also known as "trichlor", see trichloroisocyanuric acid. For Tri-clor, see chloropicrin.

Trichloroethylene (TCE) is a halocarbon with the formula C2HCl3, commonly used as an industrial degreasing solvent. It is a clear, colourless, non-flammable, volatile liquid with a chloroform-like pleasant mild smell[3] and sweet taste.[9] Its IUPAC name is trichloroethene. Trichloroethylene has been sold under a variety of trade names. Industrial abbreviations include TCE, trichlor, Trike, Tricky and tri. Under the trade names Trimar and Trilene, it was used as a volatile anesthetic and as an inhaled obstetrical analgesic. It should not be confused with the similar 1,1,1-trichloroethane, which is commonly known as chlorothene.

Trichloroethylene

sample of Trichloroethylene
Names
Preferred IUPAC name
Trichloroethene
Other names
1-Chloro-2,2-Dichloroethylene; 1,1-Dichloro-2-Chloroethylene; Acetylene Trichloride; Anamenth; HCC-1120; TCE; Trethylene; Triclene; Tri; Trico; Trilene; Trimar
Identifiers
  • 79-01-6 Y
3D model (JSmol)
  • Interactive image
  • Interactive image
  • Interactive image
Abbreviations TCE
ChEBI
  • CHEBI:16602 N
ChEMBL
  • ChEMBL279816 Y
ChemSpider
  • 13837280 Y
ECHA InfoCard 100.001.062
EC Number
  • 201-167-4
KEGG
  • C06790 Y
  • 6575
RTECS number
  • KX4550000
UNII
  • 290YE8AR51 Y
UN number 1710
  • DTXSID0021383
  • InChI=1S/C2HCl3/c3-1-2(4)5/h1H Y
    Key: XSTXAVWGXDQKEL-UHFFFAOYSA-N Y
  • InChI=1/C2HCl3/c3-1-2(4)5/h1H
  • Cl\C=C(/Cl)Cl
  • Cl\C=C(/Cl)Cl
  • ClC=C(Cl)Cl
Properties
C2HCl3
Molar mass 131.38 g·mol−1
Appearance Colorless liquid
Odor pleasant, chloroform-like
Density 1.46 g/cm3 at 20 °C
Melting point −84.8 °C (−120.6 °F; 188.3 K)[5]
Boiling point 86.7 °C (188.1 °F; 359.8 K)[1]
1.280 g/L[1]
Solubility Ether, ethanol, chloroform
log P 2.26[2]
Vapor pressure 58 mmHg (0.076 atm) at 20 °C[3]
−65.8·10−6 cm3/mol
1.4777 at 19.8 °C
Viscosity 0.532 mPa·s[4]
Pharmacology
N01AB05 (WHO)
Hazards
Occupational safety and health (OHS/OSH):
Main hazards
 Acute exposure can cause dizziness and loss of consciousness, chronic exposure can increase cancer risk. Unstable in presence of light.
GHS labelling:
NFPA 704 (fire diamond)
Health 2: Intense or continued but not chronic exposure could cause temporary incapacitation or possible residual injury. E.g. chloroformFlammability 1: Must be pre-heated before ignition can occur. Flash point over 93 °C (200 °F). E.g. canola oilInstability 0: Normally stable, even under fire exposure conditions, and is not reactive with water. E.g. liquid nitrogenSpecial hazards (white): no code
2
1
0
420 °C (788 °F; 693 K)
Explosive limits 8-10.5%[3]
Lethal dose or concentration (LD, LC):
4920 mg/kg (oral, rat), 29000 mg/kg (dermal, rabbit)[6]
8450 ppm (mouse, 4 hr)
26300 (rat, 1 hr)[7]
2900 ppm (human)
37,200 ppm (guinea pig, 40 min)
5952 ppm (cat, 2 hr)
8000 ppm (rat, 4 hr)
11,000 (rabbit)[7]
NIOSH (US health exposure limits):
PEL (Permissible)
 TWA 100 ppm C 200 ppm 300 ppm (5-minute maximum peak in any 2 hours)[3]
REL (Recommended)
 Ca[3]
IDLH (Immediate danger)
 Ca [1000 ppm][3]
Safety data sheet (SDS) Mallinckrodt Baker
Legal status
  • BR: Class B1 (Psychoactive drugs)[8]
  • US: banned for medical use (1977)
Related compounds
Vinyl chloride
Tetrachloroethylene
Related compounds
 Chloroform
1,1,1-Trichloroethane
1,1,2-Trichloroethane
Supplementary data page
Trichloroethylene (data page)
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
N verify (what is YN ?)

TCE is classified as a volatile organic compound.[9]

History edit

The earliest record of trichloroethylene synthesis dates back to 1836. It was obtained from the action of potassium hydroxide on 1,1,2,2-tetrachloroethane and 1,1,1,2-tetrachloroethane by Auguste Laurent and notated as C4HCl3 (then the atomic weight of carbon was thought to be the half of it really was). Laurent did not investigate the compound further.[10][11]

Trichloroethylene's discovery is widely attributed to E. Fischer who made it in 1864 via the reduction of hexachloroethane with hydrogen. Fischer investigated TCE and noted its boiling point as between 87 and 90 degrees Celsius.[12][13][14] Commercial production began in Germany, in 1920 and in the US in 1925.[15]

Pioneered by Imperial Chemical Industries in Britain, under the trade name "Trilene" (from trichloroethylene) , its development was hailed as an anesthetic revolution. It was mostly known as "Trimar" in the United States. The –mar suffix indicates study and development at the University of Maryland, e.g., "Fluoromar" for fluroxene and "Vinamar" for ethyl vinyl ether".[16]

 
Cyprane handheld anaesthetic device for trichloroethylene, made in the UK, 1947. This device was designed for self-administration by the patient.

Originally thought to possess less hepatotoxicity than chloroform, and without the unpleasant pungency and flammability of ether, TCE use was nonetheless soon found to have several pitfalls. These included promotion of cardiac arrhythmias, low volatility and high solubility preventing quick anesthetic induction, reactions with soda lime used in carbon dioxide absorbing systems, prolonged neurologic dysfunction when used with soda lime, and evidence of hepatotoxicity as had been found with chloroform.

The introduction of halothane in 1956 greatly diminished the use of TCE as a general anesthetic. TCE was still used as an inhalation analgesic in childbirth given by self-administration. Fetal toxicity and concerns about the carcinogenic potential of TCE led to its abandonment in developed countries by the 1980s.

The use of trichloroethylene in the food and pharmaceutical industries has been banned in much of the world since the 1970s due to concerns about its toxicity. Legislation has forced the replacement of trichloroethylene in many processes in Europe as the chemical was classified as a carcinogen carrying an R45 risk phrase, May cause cancer. Many degreasing chemical alternatives are being promoted such as Ensolv and Leksol; however, each of these is based on n-propyl bromide which carries an R60 risk phrase of May impair fertility, and they would not be a legally acceptable substitute.

Production edit

Today, most trichloroethylene is produced from ethylene. First, ethylene is chlorinated over a ferric chloride catalyst to produce 1,2-dichloroethane:

CH2=CH2 + Cl2 → ClCH2CH2Cl

When heated to around 400 °C with additional chlorine, 1,2-dichloroethane is converted to trichloroethylene:

ClCH2CH2Cl + 2 Cl2 → ClCH=CCl2 + 3 HCl

This reaction can be catalyzed by a variety of substances. The most commonly used catalyst is a mixture of potassium chloride and aluminum chloride. However, various forms of porous carbon can also be used. This reaction produces tetrachloroethylene as a byproduct and depending on the amount of chlorine fed to the reaction, tetrachloroethylene can even be the major product. Typically, trichloroethylene and tetrachloroethylene are collected together and then separated by distillation.

Prior to the early 1970s, however, most trichloroethylene was produced in a two-step process from acetylene. First, acetylene was treated with chlorine using a ferric chloride catalyst at 90 °C to produce 1,1,2,2-tetrachloroethane according to the chemical equation:

HC≡CH + 2 Cl2 → Cl2CHCHCl2

The 1,1,2,2-tetrachloroethane is then dehydrochlorinated to give trichloroethylene. This can be accomplished either with an aqueous solution of calcium hydroxide:

2 Cl2CHCHCl2 + Ca(OH)2 → 2 ClCH=CCl2 + CaCl2 + 2 H2O

or in the vapor phase by heating it to 300–500 °C on a barium chloride or calcium chloride catalyst:

Cl2CHCHCl2 → ClCH=CCl2 + HCl

Common impurities in reagent and technical grade TCE are methyl chloroform, carbon tetrachloride, ethylene dichloride, tetrachloroethanes, benzene and phenol. However, these compounds are present in very small amounts and do not possess any risk.[17]

Uses edit

Trichloroethylene is an effective solvent for a variety of organic materials. It is mainly used for cleaning. Trichloroethylene is an ingredient in various printing ink, varnishes and industrial paint formulations, as an active ingredient.[18][17] Other uses include dyeing and finishing operations, adhesive formulations, the rubber industry, adhesives, lacquers, and paint strippers. It is applied before plating, anodizing, and painting.[19]

When it was first widely produced in the 1920s, trichloroethylene's major use was to extract vegetable oils from plant materials such as soy, coconut, and palm. Other uses in the food industry included coffee decaffeination (removal of caffeine) and the preparation of flavoring extracts from hops and spices.[17] TCE was used a freezing point depressant in carbon tetrachloride fire extinguishers.[17]

Dehydrochlorination of trichloroethylene with potassium hydride gives dichloroacetylene.[20] Trichloroethylene is also a chain terminator for polyvinyl chloride.[17] Chlorination gives pentachloroethane.

Anaesthesia edit

 
Bottle of trichloroethylene for anesthesia by ICI
 
Inhaler used for Trilene, 1961-1970

Trichloroethylene is a good analgesic at 0.35 to 0.5% concentrations.[21] Trichloroethylene was used in the treatment of trigeminal neuralgia beginning in 1916.[17]

From the 1940s through the 1980s, both in Europe and North America, trichloroethylene was used as a volatile anesthetic almost invariably administered with nitrous oxide. Marketed in the UK by Imperial Chemical Industries under the trade name Trilene it was coloured blue (with a dye called waxoline blue in 1:200,000 concentration)[22] to avoid confusion with the similar-smelling chloroform. Trilene was stabilised with 0.01% thymol.[22]

TCE replaced earlier anesthetics chloroform and ether in the 1940s due to its lower toxicity than chloroform and being relatively non-flammable (unlike ether which is extremely flammable), but was itself replaced in the 1960s in developed countries with the introduction of halothane, which allowed much faster induction and recovery times and was considerably easier to administer. Trilene was also used as an inhaled analgesic, mainly during childbirth, often self-applied by the patient. Trichloroethylene was introduced for obstetrical anaesthesia in 1943, and used until the 1980s.[21] Its anaesthetic use was banned in the United States in 1977 but the anaesthetic use in the United Kingdom remained until the late 1980s.[17]

It was used with halothane in the tri-service field anaesthetic apparatus used by the UK armed forces under field conditions. As of 2000, however, TCE was still in use as an anesthetic in Africa.[23]

Trichloroethylene has been used in the production of halothane, another anaesthetic.[24]

Cleaning solvent edit

It has also been used as a dry cleaning solvent, although mostly replaced by tetrachloroethylene (also known as perchloroethylene), except for spot cleaning where it is still used under the trade name Picrin.[citation needed]

Perhaps the greatest use of TCE is as a degreaser for metal parts. It has been widely used in degreasing and cleaning since the 1920s because of its low cost, low flammability, low toxicity and high effectivity as a solvent. The demand for TCE as a degreaser began to decline in the 1950s in favor of the less toxic 1,1,1-trichloroethane. However, 1,1,1-trichloroethane production has been phased out in most of the world under the terms of the Montreal Protocol, and as a result, trichloroethylene has experienced some resurgence in use as a degreaser.[17]

Trichloroethylene is used to remove grease and lanolin from wool before weaving.[17]

TCE has also been used in the United States to clean kerosene-fueled rocket engines (TCE was not used to clean hydrogen-fueled engines such as the Space Shuttle Main Engine). During static firing, the RP-1 fuel would leave hydrocarbon deposits and vapors in the engine. These deposits had to be flushed from the engine to avoid the possibility of explosion during engine handling and future firing. TCE was used to flush the engine's fuel system immediately before and after each test firing. The flushing procedure involved pumping TCE through the engine's fuel system and letting the solvent overflow for a period ranging from several seconds to 30–35 minutes, depending upon the engine. For some engines, the engine's gas generator and liquid oxygen (LOX) dome were also flushed with TCE before test firing.[25][26] The F-1 rocket engine had its LOX dome, gas generator, and thrust chamber fuel jacket flushed with TCE during launch preparations.[26]

Refrigerants edit

TCE is also used in the manufacture of a range of fluorocarbon refrigerants[27] such as 1,1,1,2-tetrafluoroethane more commonly known as HFC 134a. TCE was also used in industrial refrigeration applications due to its high heat transfer capabilities and its low-temperature specification.

Safety edit

Chemical instability edit

Despite its widespread use as a metal degreaser, trichloroethylene itself is unstable in the presence of metal over prolonged exposure. As early as 1961 this phenomenon was recognized by the manufacturing industry when stabilizing additives were added to the commercial formulation. Since the reactive instability is accentuated by higher temperatures, the search for stabilizing additives was conducted by heating trichloroethylene to its boiling point under a reflux condenser and observing decomposition. Definitive documentation of 1,4-dioxane as a stabilizing agent for TCE is scant due to the lack of specificity in early patent literature describing TCE formulations.[28][29] Epichlorohydrin, butylene oxide, N-methylpyrrole and ethyl acetate are common stabilisers for TCE, with epichlorohydrin being the most persistent and effective.[30] Other chemical stabilizers include ketones such as methyl ethyl ketone.

 
 
Two advertisements for trichloroethylene in two different uses, metal degreasing (1947) and anaesthesia (1952)

Physiological effects edit

When inhaled, trichloroethylene produces central nervous system depression resulting in general anesthesia. These effects may be mediated by trichloroethylene acting as a positive allosteric modulator of inhibitory GABAA and glycine receptors.[31][32] Its high blood solubility results in a less desirable slower induction of anesthesia. At low concentrations, it is relatively non-irritating to the respiratory tract. Higher concentrations result in tachypnea. Many types of cardiac arrhythmias can occur and are exacerbated by epinephrine (adrenaline). It was noted in the 1940s that TCE reacted with carbon dioxide (CO2) absorbing systems (soda lime) to produce dichloroacetylene by dehydrochlorination and phosgene.[33] Cranial nerve dysfunction (especially the fifth cranial nerve) was common when TCE anesthesia was given using CO2 absorbing systems. ] Muscle relaxation with TCE anesthesia sufficient for surgery was poor. For these reasons as well as problems with hepatotoxicity, TCE lost popularity in North America and Europe to more potent anesthetics such as halothane by the 1960s.[34]

The symptoms of acute non-medical exposure are similar to those of alcohol intoxication, beginning with headache, dizziness, and confusion and progressing with increasing exposure to unconsciousness.[35] Much of what is known about the chronic human health effects of trichloroethylene is based on occupational exposures. Besides the effects to the central nervous system, workplace exposure to trichloroethylene has been associated with toxic effects in the liver and kidney.[35] A history of long-term exposure to high concentrations of trichloroethylene is a suspected environmental risk of Parkinson’s disease.[36]

Metabolism edit

Trichloroethylene is metabolised to trichloroepoxyethane (TCE oxide) which rapidly isomerises to trichloroacetaldehyde (chloral).[37] Chloral hydrates to chloral hydrate in the body. Chloral hydrate is either reduced to 2,2,2-trichloroethanol or oxidised to trichloroacetic acid. Monochloroacetic acid,[38] dichloroacetic acid[39] and trichloromethane[38][40][41] were also detected as minor metabolites of TCE.

Exposure and regulations edit

Main article: List of trichloroethylene-related incidents

With a specific gravity greater than 1 (denser than water), trichloroethylene can be present as a dense non-aqueous phase liquid (DNAPL) if sufficient quantities are spilt in the environment.

The first known report of TCE in groundwater was given in 1949 by two English public chemists who described two separate instances of well contamination by industrial releases of TCE.[42] Based on available federal and state surveys, between 9% and 34% of the drinking water supply sources tested in the US may have some TCE contamination, though EPA has reported that most water supplies comply with the maximum contaminant level (MCL) of 5 ppb.[43]

Generally, atmospheric levels of TCE are highest in areas of concentrated industry and population. Atmospheric levels tend to be lowest in rural and remote regions. Average TCE concentrations measured in air across the United States are generally between 0.01 ppb and 0.3 ppb, although mean levels as high as 3.4 ppb have been reported.[44] TCE levels in the low parts per billion range have been measured in food; however, levels as high as 140 ppb were measured in a few samples of food.[44] TCE levels above background have been found in homes undergoing renovation.[45]

Existing regulations in the United States and European Union edit

Until recent years[when?], the US Agency for Toxic Substances and Disease Registry (ATSDR) contended that trichloroethylene had little-to-no carcinogenic potential and was probably a co-carcinogen—that is, it acted in concert with other substances to promote the formation of tumors.[citation needed]

State, federal, and international agencies classify trichloroethylene as a known or probable carcinogen. In 2014, the International Agency for Research on Cancer updated its classification of trichloroethylene to Group 1, indicating that sufficient evidence exists that it causes cancer of the kidney in humans as well as some evidence of cancer of the liver and non-Hodgkin's lymphoma.[46]

In the European Union, the Scientific Committee on Occupational Exposure Limit Values (SCOEL) recommends an exposure limit for workers exposed to trichloroethylene of 10 ppm (54.7 mg/m3) for 8-hour TWA and of 30 ppm (164.1 mg/m3) for STEL (15 minutes).[47]

Existing EU legislation aimed at protection of workers against risks to their health (including Chemical Agents Directive 98/24/EC[48] and Carcinogens Directive 2004/37/EC[49]) currently do not impose binding minimum requirements for controlling risks to workers' health during the use phase or throughout the life cycle of trichloroethylene.

In 2023, the United States EPA determined that trichloroethylene presents an unreasonable risk of injury to human health under 52 out of 54 conditions of use, including during manufacturing, processing, mixing, recycling, vapor degreasing, as a lubricant, adhesive, sealant, cleaning product, and spray. It is dangerous from both inhalation and dermal exposure and was most strongly associated with immunosuppressive effects for acute exposure, as well as autoimmune effects for chronic exposures.[50] As of June 1, 2023, two U.S. states (Minnesota and New York) have acted on the EPA's findings and banned trichloroethylene in all cases but research and development.[51][52] According to the US EPA, in October 2023 it “proposed to ban the manufacture (including import), processing, and distribution in commerce of TCE for all uses, with longer compliance time frames and workplace controls (including an exposure limit) for some processing and industrial and commercial uses until the prohibitions come into effect”[needs update] to protect everyone including bystanders from the harmful health effects of TCE.[53]

Remediation edit

Recent research has focused on the in-place remediation of trichloroethylene in soil and groundwater using potassium permanganate instead of removal for off-site treatment and disposal. Naturally occurring bacteria have been identified with the ability to degrade TCE. Dehalococcoides sp. degrade trichloroethylene by reductive dechlorination under anaerobic conditions. Under aerobic conditions, Pseudomonas fluorescens can co-metabolize TCE. Soil and groundwater contamination by TCE has also been successfully remediated by chemical treatment and extraction. The bacteria Nitrosomonas europaea can degrade a variety of halogenated compounds including trichloroethylene.[54] Toluene dioxygenase has been reported to be involved in TCE degradation by Pseudomonas putida.[55] In some cases, Xanthobacter autotrophicus can convert up to 51% of TCE to CO and CO2.[55]

Society and culture edit

Groundwater and drinking water contamination from industrial discharge including trichloroethylene is a major concern for human health and has precipitated numerous incidents and lawsuits in the United States.

The 1995 non-fiction book A Civil Action was written about a lawsuit (Anderson v. Cryovac) against following the increase in cancer cases after trichloroethylene pollution incidents and it was adapted to cinema in 1998.

TCE has been used as a recreational drug.[56] Common methods of taking trichloroethylene recreationally include inhalation from a rag (similar to taking an inhalational anaesthetic) and drinking.[57] Most TCE abusers were young people and workers who use the chemical in their workplace. The main reason for abuse is TCE's euphoriant and slight hallucinogenic effect.[57] Some workers had become addicted to TCE.[58]

References edit

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  48. ^ "Council Directive 98/24/EC" (PDF). Eur-lex.europa.eu. Retrieved 21 February 2015.
  49. ^ "Directive 2004/37/EC" (PDF). Eur-lex.europa.eu. Retrieved 21 February 2015.
  50. ^ US EPA, OCSPP (2020-02-12). "Final Risk Evaluation for Trichloroethylene" (PDF). www.epa.gov. Retrieved 2023-06-03.
  51. ^ "How Minnesota passed the country's first ban on trichloroethylene". www.pca.state.mn.us/news-and-stories. Minnesota Pollution Control Agency. 28 August 2023. from the original on 6 September 2023. Retrieved 6 September 2023.
  52. ^ "Minnesota Statutes". Environmental Protection, Chapter 116, Section 116.385, act No. 116.38 (also known as "White Bear Area Neighborhood Concerned Citizens Group Ban TCE Act") of 2022. Minnesota Legislature. from the original on 6 September 2023.
  53. ^ "Risk Management for Trichloroethylene (TCE)". US EPA. 21 Nov 2023. Retrieved 23 Nov 2023.
  54. ^ . Genome.jgi-psf.org. 2015-02-05. Archived from the original on 2009-07-03. Retrieved 2015-02-21.
  55. ^ a b Robert L. Irvine; Subhas K. Sikdar (1998). Bioremediation Technologies: Principles and Practice. CRC Press. pp. 142, 144. ISBN 978-1566765619. Retrieved 21 February 2015.
  56. ^ Trichloroethylene in Neurology in Clinical Practice, Daroff, R. B., Fenichel, G. M., Jankovic, J., Mazziotta, J. C. (2012).
  57. ^ a b Chapter 50: Trichloroethylene Medical Toxicology of Drug Abuse: Synthesized Chemicals and Psychoactive Plants.Barceloux, D. G. (2012).
  58. ^ Trichlorethylene Addiction and its Effects (1972) Boleslaw Alapin M.D., M.R.C. Psych. British Journal of Addiction to Alcohol & Other DrugsVolume 68, Issue 4 p. 331-335 DOI

Further reading edit

  • Agency for Toxic Substances and Disease Registry (ATSDR). 1997.
  • Doherty, Richard E. (2000). "A History of the Production and Use of Carbon Tetrachloride, Tetrachloroethylene, Trichloroethylene and 1,1,1-Trichloroethane in the United States: Part 2 – Trichloroethylene and 1,1,1-Trichloroethane". Environmental Forensics. 1 (2): 83–93. Bibcode:2000EnvFo...1...83D. doi:10.1006/enfo.2000.0011. S2CID 97370778.
  • Lipworth, Loren; Tarone, Robert E.; McLaughlin, Joseph K. (2006). "The Epidemiology of Renal Cell Carcinoma". The Journal of Urology. 176 (6): 2353–2358. doi:10.1016/j.juro.2006.07.130. PMID 17085101.
  • Matei, Adrienne (7 Apr 2021). "Rates of Parkinson's disease are exploding. A common chemical may be to blame". The Guardian.
  • US Environmental Protection Agency (USEPA). 2011. Toxicological Review for Trichloroethylene
  • US National Academy of Sciences (NAS). 2006. Assessing Human Health Risks of Trichloroethylene – Key Scientific Issues. Committee on Human Health Risks of Trichloroethylene, National Research Council.
  • US National Toxicology Program (NTP). 2021. Trichloroethylene, in the 15th Annual Report of Carcinogens.

External links edit

 
Wikimedia Commons has media related to Trichloroethylene.

February 16, 2024
trichloroethylene, trichlor, redirects, here, reagent, also, known, trichlor, trichloroisocyanuric, acid, clor, chloropicrin, this, article, needs, additional, citations, verification, please, help, improve, this, article, adding, citations, reliable, sources,. Trichlor redirects here For the reagent also known as trichlor see trichloroisocyanuric acid For Tri clor see chloropicrin This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Trichloroethylene news newspapers books scholar JSTOR January 2021 Learn how and when to remove this template message Trichloroethylene TCE is a halocarbon with the formula C2HCl3 commonly used as an industrial degreasing solvent It is a clear colourless non flammable volatile liquid with a chloroform like pleasant mild smell 3 and sweet taste 9 Its IUPAC name is trichloroethene Trichloroethylene has been sold under a variety of trade names Industrial abbreviations include TCE trichlor Trike Tricky and tri Under the trade names Trimar and Trilene it was used as a volatile anesthetic and as an inhaled obstetrical analgesic It should not be confused with the similar 1 1 1 trichloroethane which is commonly known as chlorothene Trichloroethylene sample of TrichloroethyleneNamesPreferred IUPAC name TrichloroetheneOther names 1 Chloro 2 2 Dichloroethylene 1 1 Dichloro 2 Chloroethylene Acetylene Trichloride Anamenth HCC 1120 TCE Trethylene Triclene Tri Trico Trilene TrimarIdentifiersCAS Number 79 01 6 Y3D model JSmol Interactive imageInteractive imageInteractive imageAbbreviations TCEChEBI CHEBI 16602 NChEMBL ChEMBL279816 YChemSpider 13837280 YECHA InfoCard 100 001 062EC Number 201 167 4KEGG C06790 YPubChem CID 6575RTECS number KX4550000UNII 290YE8AR51 YUN number 1710CompTox Dashboard EPA DTXSID0021383InChI InChI 1S C2HCl3 c3 1 2 4 5 h1H YKey XSTXAVWGXDQKEL UHFFFAOYSA N YInChI 1 C2HCl3 c3 1 2 4 5 h1HSMILES Cl C C Cl ClCl C C Cl ClClC C Cl ClPropertiesChemical formula C 2H Cl 3Molar mass 131 38 g mol 1Appearance Colorless liquidOdor pleasant chloroform likeDensity 1 46 g cm3 at 20 CMelting point 84 8 C 120 6 F 188 3 K 5 Boiling point 86 7 C 188 1 F 359 8 K 1 Solubility in water 1 280 g L 1 Solubility Ether ethanol chloroformlog P 2 26 2 Vapor pressure 58 mmHg 0 076 atm at 20 C 3 Magnetic susceptibility x 65 8 10 6 cm3 molRefractive index nD 1 4777 at 19 8 CViscosity 0 532 mPa s 4 PharmacologyATC code N01AB05 WHO HazardsOccupational safety and health OHS OSH Main hazards Acute exposure can cause dizziness and loss of consciousness chronic exposure can increase cancer risk Unstable in presence of light GHS labelling PictogramsNFPA 704 fire diamond 210Autoignitiontemperature 420 C 788 F 693 K Explosive limits 8 10 5 3 Lethal dose or concentration LD LC LD50 median dose 4920 mg kg oral rat 29000 mg kg dermal rabbit 6 LC50 median concentration 8450 ppm mouse 4 hr 26300 rat 1 hr 7 LCLo lowest published 2900 ppm human 37 200 ppm guinea pig 40 min 5952 ppm cat 2 hr 8000 ppm rat 4 hr 11 000 rabbit 7 NIOSH US health exposure limits PEL Permissible TWA 100 ppm C 200 ppm 300 ppm 5 minute maximum peak in any 2 hours 3 REL Recommended Ca 3 IDLH Immediate danger Ca 1000 ppm 3 Safety data sheet SDS Mallinckrodt BakerLegal status BR Class B1 Psychoactive drugs 8 US banned for medical use 1977 Related compoundsRelated vinyl halides Vinyl chlorideTetrachloroethyleneRelated compounds Chloroform1 1 1 Trichloroethane1 1 2 TrichloroethaneSupplementary data pageTrichloroethylene data page Except where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa N verify what is Y N Infobox references TCE is classified as a volatile organic compound 9 Contents 1 History 2 Production 3 Uses 3 1 Anaesthesia 3 2 Cleaning solvent 3 3 Refrigerants 4 Safety 4 1 Chemical instability 4 2 Physiological effects 4 2 1 Metabolism 4 3 Exposure and regulations 4 3 1 Existing regulations in the United States and European Union 5 Remediation 6 Society and culture 7 References 8 Further reading 9 External linksHistory editThe earliest record of trichloroethylene synthesis dates back to 1836 It was obtained from the action of potassium hydroxide on 1 1 2 2 tetrachloroethane and 1 1 1 2 tetrachloroethane by Auguste Laurent and notated as C4HCl3 then the atomic weight of carbon was thought to be the half of it really was Laurent did not investigate the compound further 10 11 Trichloroethylene s discovery is widely attributed to E Fischer who made it in 1864 via the reduction of hexachloroethane with hydrogen Fischer investigated TCE and noted its boiling point as between 87 and 90 degrees Celsius 12 13 14 Commercial production began in Germany in 1920 and in the US in 1925 15 Pioneered by Imperial Chemical Industries in Britain under the trade name Trilene from trichloroethylene its development was hailed as an anesthetic revolution It was mostly known as Trimar in the United States The mar suffix indicates study and development at the University of Maryland e g Fluoromar for fluroxene and Vinamar for ethyl vinyl ether 16 nbsp Cyprane handheld anaesthetic device for trichloroethylene made in the UK 1947 This device was designed for self administration by the patient Originally thought to possess less hepatotoxicity than chloroform and without the unpleasant pungency and flammability of ether TCE use was nonetheless soon found to have several pitfalls These included promotion of cardiac arrhythmias low volatility and high solubility preventing quick anesthetic induction reactions with soda lime used in carbon dioxide absorbing systems prolonged neurologic dysfunction when used with soda lime and evidence of hepatotoxicity as had been found with chloroform The introduction of halothane in 1956 greatly diminished the use of TCE as a general anesthetic TCE was still used as an inhalation analgesic in childbirth given by self administration Fetal toxicity and concerns about the carcinogenic potential of TCE led to its abandonment in developed countries by the 1980s The use of trichloroethylene in the food and pharmaceutical industries has been banned in much of the world since the 1970s due to concerns about its toxicity Legislation has forced the replacement of trichloroethylene in many processes in Europe as the chemical was classified as a carcinogen carrying an R45 risk phrase May cause cancer Many degreasing chemical alternatives are being promoted such as Ensolv and Leksol however each of these is based on n propyl bromide which carries an R60 risk phrase of May impair fertility and they would not be a legally acceptable substitute Production editToday most trichloroethylene is produced from ethylene First ethylene is chlorinated over a ferric chloride catalyst to produce 1 2 dichloroethane CH2 CH2 Cl2 ClCH2CH2ClWhen heated to around 400 C with additional chlorine 1 2 dichloroethane is converted to trichloroethylene ClCH2CH2Cl 2 Cl2 ClCH CCl2 3 HClThis reaction can be catalyzed by a variety of substances The most commonly used catalyst is a mixture of potassium chloride and aluminum chloride However various forms of porous carbon can also be used This reaction produces tetrachloroethylene as a byproduct and depending on the amount of chlorine fed to the reaction tetrachloroethylene can even be the major product Typically trichloroethylene and tetrachloroethylene are collected together and then separated by distillation Prior to the early 1970s however most trichloroethylene was produced in a two step process from acetylene First acetylene was treated with chlorine using a ferric chloride catalyst at 90 C to produce 1 1 2 2 tetrachloroethane according to the chemical equation HC CH 2 Cl2 Cl2CHCHCl2The 1 1 2 2 tetrachloroethane is then dehydrochlorinated to give trichloroethylene This can be accomplished either with an aqueous solution of calcium hydroxide 2 Cl2CHCHCl2 Ca OH 2 2 ClCH CCl2 CaCl2 2 H2Oor in the vapor phase by heating it to 300 500 C on a barium chloride or calcium chloride catalyst Cl2CHCHCl2 ClCH CCl2 HClCommon impurities in reagent and technical grade TCE are methyl chloroform carbon tetrachloride ethylene dichloride tetrachloroethanes benzene and phenol However these compounds are present in very small amounts and do not possess any risk 17 Uses editTrichloroethylene is an effective solvent for a variety of organic materials It is mainly used for cleaning Trichloroethylene is an ingredient in various printing ink varnishes and industrial paint formulations as an active ingredient 18 17 Other uses include dyeing and finishing operations adhesive formulations the rubber industry adhesives lacquers and paint strippers It is applied before plating anodizing and painting 19 When it was first widely produced in the 1920s trichloroethylene s major use was to extract vegetable oils from plant materials such as soy coconut and palm Other uses in the food industry included coffee decaffeination removal of caffeine and the preparation of flavoring extracts from hops and spices 17 TCE was used a freezing point depressant in carbon tetrachloride fire extinguishers 17 Dehydrochlorination of trichloroethylene with potassium hydride gives dichloroacetylene 20 Trichloroethylene is also a chain terminator for polyvinyl chloride 17 Chlorination gives pentachloroethane Anaesthesia edit nbsp Bottle of trichloroethylene for anesthesia by ICI nbsp Inhaler used for Trilene 1961 1970Trichloroethylene is a good analgesic at 0 35 to 0 5 concentrations 21 Trichloroethylene was used in the treatment of trigeminal neuralgia beginning in 1916 17 From the 1940s through the 1980s both in Europe and North America trichloroethylene was used as a volatile anesthetic almost invariably administered with nitrous oxide Marketed in the UK by Imperial Chemical Industries under the trade name Trilene it was coloured blue with a dye called waxoline blue in 1 200 000 concentration 22 to avoid confusion with the similar smelling chloroform Trilene was stabilised with 0 01 thymol 22 TCE replaced earlier anesthetics chloroform and ether in the 1940s due to its lower toxicity than chloroform and being relatively non flammable unlike ether which is extremely flammable but was itself replaced in the 1960s in developed countries with the introduction of halothane which allowed much faster induction and recovery times and was considerably easier to administer Trilene was also used as an inhaled analgesic mainly during childbirth often self applied by the patient Trichloroethylene was introduced for obstetrical anaesthesia in 1943 and used until the 1980s 21 Its anaesthetic use was banned in the United States in 1977 but the anaesthetic use in the United Kingdom remained until the late 1980s 17 It was used with halothane in the tri service field anaesthetic apparatus used by the UK armed forces under field conditions As of 2000 however TCE was still in use as an anesthetic in Africa 23 Trichloroethylene has been used in the production of halothane another anaesthetic 24 Cleaning solvent edit It has also been used as a dry cleaning solvent although mostly replaced by tetrachloroethylene also known as perchloroethylene except for spot cleaning where it is still used under the trade name Picrin citation needed Perhaps the greatest use of TCE is as a degreaser for metal parts It has been widely used in degreasing and cleaning since the 1920s because of its low cost low flammability low toxicity and high effectivity as a solvent The demand for TCE as a degreaser began to decline in the 1950s in favor of the less toxic 1 1 1 trichloroethane However 1 1 1 trichloroethane production has been phased out in most of the world under the terms of the Montreal Protocol and as a result trichloroethylene has experienced some resurgence in use as a degreaser 17 Trichloroethylene is used to remove grease and lanolin from wool before weaving 17 TCE has also been used in the United States to clean kerosene fueled rocket engines TCE was not used to clean hydrogen fueled engines such as the Space Shuttle Main Engine During static firing the RP 1 fuel would leave hydrocarbon deposits and vapors in the engine These deposits had to be flushed from the engine to avoid the possibility of explosion during engine handling and future firing TCE was used to flush the engine s fuel system immediately before and after each test firing The flushing procedure involved pumping TCE through the engine s fuel system and letting the solvent overflow for a period ranging from several seconds to 30 35 minutes depending upon the engine For some engines the engine s gas generator and liquid oxygen LOX dome were also flushed with TCE before test firing 25 26 The F 1 rocket engine had its LOX dome gas generator and thrust chamber fuel jacket flushed with TCE during launch preparations 26 Refrigerants edit TCE is also used in the manufacture of a range of fluorocarbon refrigerants 27 such as 1 1 1 2 tetrafluoroethane more commonly known as HFC 134a TCE was also used in industrial refrigeration applications due to its high heat transfer capabilities and its low temperature specification Safety editChemical instability edit Despite its widespread use as a metal degreaser trichloroethylene itself is unstable in the presence of metal over prolonged exposure As early as 1961 this phenomenon was recognized by the manufacturing industry when stabilizing additives were added to the commercial formulation Since the reactive instability is accentuated by higher temperatures the search for stabilizing additives was conducted by heating trichloroethylene to its boiling point under a reflux condenser and observing decomposition Definitive documentation of 1 4 dioxane as a stabilizing agent for TCE is scant due to the lack of specificity in early patent literature describing TCE formulations 28 29 Epichlorohydrin butylene oxide N methylpyrrole and ethyl acetate are common stabilisers for TCE with epichlorohydrin being the most persistent and effective 30 Other chemical stabilizers include ketones such as methyl ethyl ketone nbsp nbsp Two advertisements for trichloroethylene in two different uses metal degreasing 1947 and anaesthesia 1952 Physiological effects edit When inhaled trichloroethylene produces central nervous system depression resulting in general anesthesia These effects may be mediated by trichloroethylene acting as a positive allosteric modulator of inhibitory GABAA and glycine receptors 31 32 Its high blood solubility results in a less desirable slower induction of anesthesia At low concentrations it is relatively non irritating to the respiratory tract Higher concentrations result in tachypnea Many types of cardiac arrhythmias can occur and are exacerbated by epinephrine adrenaline It was noted in the 1940s that TCE reacted with carbon dioxide CO2 absorbing systems soda lime to produce dichloroacetylene by dehydrochlorination and phosgene 33 Cranial nerve dysfunction especially the fifth cranial nerve was common when TCE anesthesia was given using CO2 absorbing systems Muscle relaxation with TCE anesthesia sufficient for surgery was poor For these reasons as well as problems with hepatotoxicity TCE lost popularity in North America and Europe to more potent anesthetics such as halothane by the 1960s 34 The symptoms of acute non medical exposure are similar to those of alcohol intoxication beginning with headache dizziness and confusion and progressing with increasing exposure to unconsciousness 35 Much of what is known about the chronic human health effects of trichloroethylene is based on occupational exposures Besides the effects to the central nervous system workplace exposure to trichloroethylene has been associated with toxic effects in the liver and kidney 35 A history of long term exposure to high concentrations of trichloroethylene is a suspected environmental risk of Parkinson s disease 36 Metabolism edit Trichloroethylene is metabolised to trichloroepoxyethane TCE oxide which rapidly isomerises to trichloroacetaldehyde chloral 37 Chloral hydrates to chloral hydrate in the body Chloral hydrate is either reduced to 2 2 2 trichloroethanol or oxidised to trichloroacetic acid Monochloroacetic acid 38 dichloroacetic acid 39 and trichloromethane 38 40 41 were also detected as minor metabolites of TCE Exposure and regulations edit Main article List of trichloroethylene related incidents With a specific gravity greater than 1 denser than water trichloroethylene can be present as a dense non aqueous phase liquid DNAPL if sufficient quantities are spilt in the environment The first known report of TCE in groundwater was given in 1949 by two English public chemists who described two separate instances of well contamination by industrial releases of TCE 42 Based on available federal and state surveys between 9 and 34 of the drinking water supply sources tested in the US may have some TCE contamination though EPA has reported that most water supplies comply with the maximum contaminant level MCL of 5 ppb 43 Generally atmospheric levels of TCE are highest in areas of concentrated industry and population Atmospheric levels tend to be lowest in rural and remote regions Average TCE concentrations measured in air across the United States are generally between 0 01 ppb and 0 3 ppb although mean levels as high as 3 4 ppb have been reported 44 TCE levels in the low parts per billion range have been measured in food however levels as high as 140 ppb were measured in a few samples of food 44 TCE levels above background have been found in homes undergoing renovation 45 Existing regulations in the United States and European Union edit Until recent years when the US Agency for Toxic Substances and Disease Registry ATSDR contended that trichloroethylene had little to no carcinogenic potential and was probably a co carcinogen that is it acted in concert with other substances to promote the formation of tumors citation needed State federal and international agencies classify trichloroethylene as a known or probable carcinogen In 2014 the International Agency for Research on Cancer updated its classification of trichloroethylene to Group 1 indicating that sufficient evidence exists that it causes cancer of the kidney in humans as well as some evidence of cancer of the liver and non Hodgkin s lymphoma 46 In the European Union the Scientific Committee on Occupational Exposure Limit Values SCOEL recommends an exposure limit for workers exposed to trichloroethylene of 10 ppm 54 7 mg m3 for 8 hour TWA and of 30 ppm 164 1 mg m3 for STEL 15 minutes 47 Existing EU legislation aimed at protection of workers against risks to their health including Chemical Agents Directive 98 24 EC 48 and Carcinogens Directive 2004 37 EC 49 currently do not impose binding minimum requirements for controlling risks to workers health during the use phase or throughout the life cycle of trichloroethylene In 2023 the United States EPA determined that trichloroethylene presents an unreasonable risk of injury to human health under 52 out of 54 conditions of use including during manufacturing processing mixing recycling vapor degreasing as a lubricant adhesive sealant cleaning product and spray It is dangerous from both inhalation and dermal exposure and was most strongly associated with immunosuppressive effects for acute exposure as well as autoimmune effects for chronic exposures 50 As of June 1 2023 two U S states Minnesota and New York have acted on the EPA s findings and banned trichloroethylene in all cases but research and development 51 52 According to the US EPA in October 2023 it proposed to ban the manufacture including import processing and distribution in commerce of TCE for all uses with longer compliance time frames and workplace controls including an exposure limit for some processing and industrial and commercial uses until the prohibitions come into effect needs update to protect everyone including bystanders from the harmful health effects of TCE 53 Remediation editRecent research has focused on the in place remediation of trichloroethylene in soil and groundwater using potassium permanganate instead of removal for off site treatment and disposal Naturally occurring bacteria have been identified with the ability to degrade TCE Dehalococcoides sp degrade trichloroethylene by reductive dechlorination under anaerobic conditions Under aerobic conditions Pseudomonas fluorescens can co metabolize TCE Soil and groundwater contamination by TCE has also been successfully remediated by chemical treatment and extraction The bacteria Nitrosomonas europaea can degrade a variety of halogenated compounds including trichloroethylene 54 Toluene dioxygenase has been reported to be involved in TCE degradation by Pseudomonas putida 55 In some cases Xanthobacter autotrophicus can convert up to 51 of TCE to CO and CO2 55 Society and culture editGroundwater and drinking water contamination from industrial discharge including trichloroethylene is a major concern for human health and has precipitated numerous incidents and lawsuits in the United States The 1995 non fiction book A Civil Action was written about a lawsuit Anderson v Cryovac against following the increase in cancer cases after trichloroethylene pollution incidents and it was adapted to cinema in 1998 TCE has been used as a recreational drug 56 Common methods of taking trichloroethylene recreationally include inhalation from a rag similar to taking an inhalational anaesthetic and drinking 57 Most TCE abusers were young people and workers who use the chemical in their workplace The main reason for abuse is TCE s euphoriant and slight hallucinogenic effect 57 Some workers had become addicted to TCE 58 References edit a b Trichloroethylene Sigmaaldrich com Retrieved 20 October 2014 Trichloroethylene www chemsrc com a b c d e f NIOSH Pocket Guide to Chemical Hazards 0629 National Institute for Occupational Safety and Health NIOSH Venkatesulu D Venkatesu P Rao M V Prabhakara 1997 Viscosities and Densities of Trichloroethylene or Tetrachloroethylene with 2 Alkoxyethanols at 303 15 K and 313 15 K Journal of Chemical amp Engineering Data 42 2 365 367 doi 10 1021 je960316f ISSN 0021 9568 Safety Data Sheet Retrieved 23 February 2022 FischerSci Trichloroethylene SDS a b Trichloroethylene Immediately Dangerous to Life or Health Concentrations IDLH National Institute for Occupational Safety and Health NIOSH Anvisa 2023 03 31 RDC Nº 784 Listas de Substancias Entorpecentes Psicotropicas Precursoras e Outras sob Controle Especial Collegiate Board Resolution No 784 Lists of Narcotic Psychotropic Precursor and Other Substances under Special Control in Brazilian Portuguese Diario Oficial da Uniao published 2023 04 04 Archived from the original on 2023 08 03 Retrieved 2023 08 16 a b Trichloroethylene TCE on ATSDR Essai sur l Action du Chlore sur la Liqueur des Hollandais et sur quelques Ethers in Annal de Chimie LXIII 1836 page 379 The so called Perchloride of Formyl Gmelin L translated in 1855 Hand book of Chemistry Organic chemistry UK Cavendish Society pages 200 201 Ueber die Einwirkung von Wasserstoff auf Einfach Chlorkohlenstoff Fischer E 1864 in Zeitschrift fur Chemie page 268 Waters EM Gerstner HB Huff JE Trichloroethylene I An overview J Toxicol Environ Health 1977 Jan 2 3 671 707 doi 10 1080 15287397709529469 PMID 403297 Hardie DWF 1964 Chlorocarbons and chlorohydrocarbons 1 1 2 2 Tetrachloroethane In Encyclopedia of Chemical Technology Kirk RE Othmer DF editors New York John Wiley amp Sons pp 159 164 Mertens JA 1993 Chlorocarbons and chlorohydrocarbons In Kirk Othmer Encyclopedia of Chemical Technology 4th Ed Kroschwitz JI Howe Grant M editors New York John Wiley amp Sons pp 40 50 A Portrait of Medical History and Current Medical Problem 1962 p 130 a b c d e f g h i Chapter 4 Trichloroethylene Morrison R D Murphy B L 2015 Chlorinated Solvents A Forensic Evaluation Royal Society of Chemistry Subramanian Indu 20 Nov 2023 Is Most Parkinson s Disease Man Made Medscape Retrieved 29 Nov 2023 Caudle W Michael Guillot Thomas S Lazo Carlos R Miller Gary W 2012 Industrial toxicants and Parkinson s disease NeuroToxicology Elsevier BV 33 2 178 188 doi 10 1016 j neuro 2012 01 010 ISSN 0161 813X PMC 3299826 PMID 22309908 Denis Jean Noel Moyano Albert Greene Andrew E 1987 Practical synthesis of dichloroacetylene The Journal of Organic Chemistry 52 15 3461 3462 doi 10 1021 jo00391a059 a b Textbook of Obstetric Anaesthesia 2002 UK Greenwich Medical Media Pages 64 65 a b Current Researches in Anesthesia amp Analgesia 1951 USA International Anesthesia Research Society p 278 P Fenton 2000 Volatile Anaesthetic Agents Archived from the original on 2012 01 07 Retrieved 2012 02 11 Suckling et al PROCESS FOR THE PREPARATION OF 1 1 1 TRIFLUORO 2 BROMO 2 CHLOROETHANE US patent 2921098 granted January 1960 assigned to Imperial Chemical Industries Santa Susana Field Laboratory The Use of Trichloroethylene at NASA s SSFL Sites PDF Ssfl msfc nasa gov Archived from the original PDF on 14 November 2013 Retrieved 22 February 2015 a b F 1 Rocket Engine Operating Instructions Ntrs nasa gov Retrieved 20 October 2014 Production of R 134a PDF Nd edu Archived from the original PDF on 11 July 2009 Retrieved 21 February 2015 Murphy Brian L Morrison Robert D 2015 9 Source Identification and Age Dating of Chlorinated Solvents Introduction to environmental forensics 3rd ed Academic Press sec 9 2 2 1 1 4 Dioxane ISBN 978 0124047075 Mohr Thomas K G 2010 Historical Use of Chlorinated Solvents and Their Stabilizing Compounds Environmental investigation and remediation 1 4 dioxane and other solvent stabilizers CRC Press p 53 Was 1 4 Dioxane a Stabilizer for Trichloroethylene ISBN 978 1566706629 Morrison R D Murphy B L 2013 Chlorinated Solvents A Forensic Evaluation UK Royal Society of Chemistry M J Beckstead J L Weiner E I 2nd Eger D H Gong amp S J Mihic 2000 Glycine and gamma aminobutyric acid A receptor function is enhanced by inhaled drugs of abuse Molecular Pharmacology 57 6 1199 1205 PMID 10825391 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link CS1 maint numeric names authors list link M D Krasowski amp N L Harrison 2000 The actions of ether alcohol and alkane general anaesthetics on GABAA and glycine receptors and the effects of TM2 and TM3 mutations British Journal of Pharmacology 129 4 731 743 doi 10 1038 sj bjp 0703087 PMC 1571881 PMID 10683198 Orkin F K 1986 Anesthesia Systems Chapter 5 In R D Miller Ed Anesthesia second edition New York NY Churchill Livingstone page needed Stevens W C and Kingston H G G 1989 Inhalation Anesthesia Chapter 11 In P G Barash et al Eds Clinical Anesthesia Philadelphia PA Lippincott page needed a b Trichloroethylene Technology Transfer Network Air Toxics Web site US EPA Epa gov Retrieved 2013 10 05 Dorsey ER Zafar M Lettenberger SE et al 2023 Trichloroethylene An Invisible Cause of Parkinson s Disease J Parkinsons Dis 13 2 203 218 doi 10 3233 JPD 225047 PMC 10041423 PMID 36938742 Fishbein L 1977 Potential Industrial Carcinogens and Mutagens Environmental Protection Agency Office of Toxic Substances a b 21 4 25 Trichloroethylene in Biological Monitoring An Introduction 1993 UK Wiley Biologically Based Methods for Cancer Risk Assessment 2013 Springer US Toxicological Profile for Trichloroethylene Draft 1995 U S Department of Health and Human Services Mutagenesis 1978 page 268 Lyne FA McLachlan T 1949 Contamination of water by trichloroethylene p 513 in Lilliman B Houlihan J E Lyne F A McLachlan T 1949 Notes The Analyst 74 882 510 513 Bibcode 1949Ana 74 510L doi 10 1039 AN9497400510 Consumer Factsheet on Trichloroethylene PDF Epa gov Retrieved 22 February 2015 a b Trichloroethylene Toxicity Where is Trichloroethylene Found Environmental Medicine ATSDR www atsdr cdc gov 2022 09 09 Retrieved 2023 03 02 nbsp This article incorporates text from this source which is in the public domain Trichloroethylene tce TEACH Chemical Summary epa nepis Trichloroethylene IARC Summary amp Evaluation Volume 106 2014 PDF iarc fr Retrieved 2016 03 08 Recommendation from the Scientific Committee on Occupational Exposure Limits for Trichloroethylene SCOEL SUM 142 PDF April 2009 Council Directive 98 24 EC PDF Eur lex europa eu Retrieved 21 February 2015 Directive 2004 37 EC PDF Eur lex europa eu Retrieved 21 February 2015 US EPA OCSPP 2020 02 12 Final Risk Evaluation for Trichloroethylene PDF www epa gov Retrieved 2023 06 03 How Minnesota passed the country s first ban on trichloroethylene www pca state mn us news and stories Minnesota Pollution Control Agency 28 August 2023 Archived from the original on 6 September 2023 Retrieved 6 September 2023 Minnesota Statutes Environmental Protection Chapter 116 Section 116 385 act No 116 38 also known as White Bear Area Neighborhood Concerned Citizens Group Ban TCE Act of 2022 Minnesota Legislature Archived from the original on 6 September 2023 Risk Management for Trichloroethylene TCE US EPA 21 Nov 2023 Retrieved 23 Nov 2023 Nitrosomonas europaea Genome jgi psf org 2015 02 05 Archived from the original on 2009 07 03 Retrieved 2015 02 21 a b Robert L Irvine Subhas K Sikdar 1998 Bioremediation Technologies Principles and Practice CRC Press pp 142 144 ISBN 978 1566765619 Retrieved 21 February 2015 Trichloroethylene in Neurology in Clinical Practice Daroff R B Fenichel G M Jankovic J Mazziotta J C 2012 a b Chapter 50 Trichloroethylene Medical Toxicology of Drug Abuse Synthesized Chemicals and Psychoactive Plants Barceloux D G 2012 Trichlorethylene Addiction and its Effects 1972 Boleslaw Alapin M D M R C Psych British Journal of Addiction to Alcohol amp Other DrugsVolume 68 Issue 4 p 331 335 DOIFurther reading editAgency for Toxic Substances and Disease Registry ATSDR 1997 Toxicological Profile for Trichloroethylene Doherty Richard E 2000 A History of the Production and Use of Carbon Tetrachloride Tetrachloroethylene Trichloroethylene and 1 1 1 Trichloroethane in the United States Part 2 Trichloroethylene and 1 1 1 Trichloroethane Environmental Forensics 1 2 83 93 Bibcode 2000EnvFo 1 83D doi 10 1006 enfo 2000 0011 S2CID 97370778 Lipworth Loren Tarone Robert E McLaughlin Joseph K 2006 The Epidemiology of Renal Cell Carcinoma The Journal of Urology 176 6 2353 2358 doi 10 1016 j juro 2006 07 130 PMID 17085101 Matei Adrienne 7 Apr 2021 Rates of Parkinson s disease are exploding A common chemical may be to blame The Guardian US Environmental Protection Agency USEPA 2011 Toxicological Review for Trichloroethylene US National Academy of Sciences NAS 2006 Assessing Human Health Risks of Trichloroethylene Key Scientific Issues Committee on Human Health Risks of Trichloroethylene National Research Council US National Toxicology Program NTP 2021 Trichloroethylene in the 15th Annual Report of Carcinogens External links edit nbsp Wikimedia Commons has media related to Trichloroethylene US EPA Trichloroethylene TCE information website US Environmental Protection Agency EPA chlorinated solvents eu Sustainable uses and industry recommendations European Chlorinated Solvents Association Case Studies in Environmental Medicine Trichloroethylene Toxicity Agency for Toxic Substances and Disease Registry ATSDR of the US Department of Health and Human Services public domain Assessing Human Health Risks of Trichloroethylene Key Scientific Issues US National Academy of Sciences NAS US NIH Fifteenth Report on Carcinogens Trichloroethylene Monograph US National Institutes of Health NIH Workplace Safety and Health Topics Trichloroethylene TCE US National Institute for Occupational Safety and Health NIOSH Retrieved from https en wikipedia org w index php title Trichloroethylene amp oldid 1206301025, wikipedia, wiki, book, books, library,

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