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2,4-Dichlorophenoxyacetic acid

February 16, 2024


2,4-Dichlorophenoxyacetic acid is an organic compound with the chemical formula Cl2C6H3OCH2CO2H. It is usually referred to by its ISO common name 2,4-D.[4] It is a systemic herbicide that kills most broadleaf weeds by causing uncontrolled growth, but most grasses such as cereals, lawn turf, and grassland are relatively unaffected.

2,4-Dichlorophenoxyacetic acid
Names
Preferred IUPAC name
(2,4-Dichlorophenoxy)acetic acid
Other names
2,4-D
Identifiers
  • 94-75-7 Y
3D model (JSmol)
  • Interactive image
ChEBI
  • CHEBI:28854 Y
ChEMBL
  • ChEMBL367623 Y
ChemSpider
  • 1441 Y
ECHA InfoCard 100.002.147
KEGG
  • C03664 Y
  • 1486
UNII
  • 2577AQ9262 Y
  • DTXSID0020442
  • InChI=1S/C8H6Cl2O3/c9-5-1-2-7(6(10)3-5)13-4-8(11)12/h1-3H,4H2,(H,11,12) Y
    Key: OVSKIKFHRZPJSS-UHFFFAOYSA-N Y
  • InChI=1/C8H6Cl2O3/c9-5-1-2-7(6(10)3-5)13-4-8(11)12/h1-3H,4H2,(H,11,12)
    Key: OVSKIKFHRZPJSS-UHFFFAOYAM
  • Clc1cc(Cl)ccc1OCC(=O)O
Properties
C8H6Cl2O3
Molar mass 221.04 g/mol
Appearance white to yellow powder
Melting point 140.5 °C (284.9 °F; 413.6 K)
Boiling point 160 °C (320 °F; 433 K) 0.4 mm Hg
900 mg/L
Hazards
GHS labelling:[3]
H302, H317, H318, H335, H412
P261, P273, P280, P305+P351+P338
Flash point nonflammable[1]
Lethal dose or concentration (LD, LC):
500 mg/kg (oral, hamster)

100 mg/kg (oral, dog)
347 mg/kg (oral, mouse)
699 mg/kg (oral, rat)
[2]

NIOSH (US health exposure limits):
PEL (Permissible)
 TWA 10 mg/m3[1]
REL (Recommended)
 TWA 10 mg/m3[1]
IDLH (Immediate danger)
 100 mg/m3[1]
Safety data sheet (SDS) ICSC 0033
Related compounds
Related compounds
 2,4,5-T, Dichlorprop
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).

2,4-D is one of the oldest and most widely available herbicides and defoliants in the world, having been commercially available since 1945, and is now produced by many chemical companies since the patent on it has long since expired. It can be found in numerous commercial lawn herbicide mixtures, and is widely used as a weedkiller on cereal crops, pastures, and orchards. Over 1,500 herbicide products contain 2,4-D as an active ingredient.

History edit

See also: List of multiple discoveries

2,4-D was first reported in 1944 by Franklin D-Jones at the C. B. Dolge Company in Connectecut.[5] The biological activity of 2,4-D as well as the similar hormone herbicides 2,4,5-T, and MCPA were discovered during World War II, a case of multiple discovery by four groups working independently under wartime secrecy in the United Kingdom and the United States: William G. Templeman and associates at Imperial Chemical Industries (ICI) in the UK; Philip S. Nutman and associates at Rothamsted Research in the UK; Franklin D. Jones and associates at the American Chemical Paint Company; and Ezra Kraus, John W. Mitchell, and associates at the University of Chicago and the United States Department of Agriculture. All four groups were subject to wartime secrecy laws and did not follow the usual procedures of publication and patent disclosure. In December 1942, following a meeting at the Ministry of Agriculture the Rothamsted and ICI workers pooled resources and Nutman moved to Jealott's Hill to join the ICI effort.[6] The first scientific publication describing the 2,4-D structure and plant growth regulating activity was by Percy W. Zimmerman and Albert E. Hitchcock at the Boyce Thompson Institute,[7] who were not the original inventors. The precise sequence of early 2,4-D discovery events and publications has been discussed.[8]

William Templeman found that when indole-3-acetic acid (IAA), a naturally-occurring auxin, was used at high concentrations, it could stop plant growth. In 1940, he published his finding that IAA killed broadleaf plants within a cereal field.[9] MCPA was discovered at about that time by his ICI group.[6][10]: Sec 7.1 

In the USA, a similar search for an acid with a longer half life, i.e., a metabolically and environmentally more stable compound, led to 2,4-dichlorophenoxyacetic acid (2,4-D) and 2,4,5-trichlorophenoxyacetic acid (2,4,5-T), both phenoxy herbicides and analogs of IAA. Robert Pokorny, an industrial chemist for the C.B. Dolge Company in Westport, Connecticut, published their synthesis in 1941.[11]

2,4-D was not used as a chemical warfare agents during the war.[10]: Sec 7.1  Britain and the United States were looking for a chemical to starve Germany and Japan into submission by killing their potato and rice crops, but 2,4-D was found to be ineffective for that purpose, because both crops tolerate it. Within a year after the war ended, 2,4-D was commercially released as an herbicide to control broadleaf weeds in grain crops such as rice and wheat,[12] and in the 1950s it was registered in the United States to control size and enhance skin color in potatoes without affecting yields.[13]

The first publication of 2,4-D's use as a selective herbicide came in 1944.[14][15] The ability of 2,4-D to control broadleaf weeds in turf was documented soon thereafter, in 1944.[16] Starting in 1945, the American Chemical Paint Company brought 2,4-D to market as an herbicide called "Weedone". It revolutionized weed control, as it was the first compound that, at low doses, could selectively control dicotyledons (broadleaf plants), but not most monocotyledons — narrowleaf crops, such as wheat, maize (corn), rice, and similar cereal grass crops.[10] At a time when labor was scarce and the need for increased food production was large, it literally "replaced the hoe".[10]: Sec 7.1 

2,4-D is one of the ingredients in Agent Orange, an herbicide that was widely used during the Malayan Emergency and the Vietnam War.[17] However, 2,3,7,8-tetrachlorodibenzodioxin (TCDD), a contaminant in the production of another ingredient in Agent Orange, 2,4,5-T, was the cause of the adverse health effects associated with Agent Orange.[18][19]

In the 2000s, Dow AgroSciences developed a new choline salt version of 2,4-D (2,4-D choline) that Dow included in its "Enlist Duo" herbicide along with glyphosate and an agent that reduces drift; the choline salt form of 2,4-D is less volatile than 2,4-D.[20][21][22]

Manufacture edit

2,4-D is a member of the phenoxy family of herbicides.[18] It is manufactured from chloroacetic acid and 2,4-dichlorophenol, which is itself produced by chlorination of phenol. Alternatively, it is produced by the chlorination of phenoxyacetic acid. The production processes may create several contaminants including di-, tri-, and tetrachlorodibenzo-p-dioxin isomers and N-nitrosamines, as well as monochlorophenol.[23]

 
Containers of 2-4 D herbicide, ca. 1947

Mode of action edit

2,4-D is a synthetic auxin that induces uncontrolled growth and eventually death in susceptible plants.[24][25][26] It is absorbed through the leaves and is translocated to the meristems of the plant. Uncontrolled, unsustainable growth ensues, causing stem curl-over, leaf withering, and eventual plant death. 2,4-D is typically applied as an amine salt, but more potent ester versions exist, as well.[27]

 
Effect of 2-4-D foliar application on Lantana

Applications edit

2,4-D is primarily used as a selective herbicide that kills many terrestrial and aquatic broadleaf weeds, but not grasses. 2,4-D can be found in commercial lawn herbicide mixtures, which often contain other active ingredients including mecoprop and dicamba. Over 1,500 herbicide products contain 2,4-D as an active ingredient.[28]

 
Estimated use of 2,4-D in the USA to 2019

A variety of sectors use products containing 2,4-D to kill weeds and unwanted vegetation. In agriculture, it was the first herbicide for selective killing of weeds but not crops. It has been used since 1945[29] to control broad-leafed weeds in pastures, orchards, and cereal crops such as corn, oats, rice, and wheat.[30] Cereals, in particular, have excellent tolerance to 2,4-D when it is applied before planting. 2,4-D is the cheapest way for farmers to control winter annual weeds by spraying in the fall, often at the lowest recommended rate. This is particularly effective before planting beans, peas, lentils, and chickpeas.[31] The estimated use of 2,4-D in US agriculture is mapped by the US Geological Survey. In 2019, the latest date for which figures are available, this reached 45,000,000 pounds (20,000,000 kg) annually.[32]

In domestic lawn and garden maintenance, 2,4-D is commonly used. In forestry, it is used for stump treatment, trunk injection, and selective control of brush in conifer forests. Along roadways, railways, and power lines, it is used to control weeds and brush which might interfere with safe operation and damage equipment. Along waterways, it is used to control aquatic weeds that might interfere with boating, fishing, and swimming or clog irrigation and hydroelectric equipment. It is often used by government agencies to control the spread of invasive, noxious, and non-native weed species and prevent them from crowding out native species, and also to control many poisonous weeds such as poison ivy and poison oak.[33]: 35–36  [34]

A 2010 monitoring study conducted in the US and Canada found that "current exposures to 2,4-D are below applicable exposure guidance values."[35]

2,4-D has been used in laboratories for plant research as a supplement in plant cell culture media such as MS medium since at least 1962.[36] 2,4-D is used in plant cell cultures as a dedifferentiation (callus induction) hormone. It is classified as an auxin plant hormone derivative.[37]

Health effects edit

See also: Health effects of pesticides and Pesticide poisoning

Men who work with 2,4-D are at risk for abnormally shaped sperm and thus fertility problems; the risk depends on the amount and duration of exposure and other personal factors.[38]

Acute toxicity edit

According to the U.S. Environmental Protection Agency, "The toxicity of 2,4-D depends on its chemical forms, including salts, esters, and an acid form. 2,4-D generally has low toxicity for humans, except certain acid and salt forms can cause eye irritation. Swimming is restricted for 24 hours after application of certain 2,4-D products applied to control aquatic weeds to avoid eye irritation."[39] As of 2005 the median lethal dose or LD50 determined in acute toxicity rat studies was 639 mg/kg.[40]

Urinary alkalinisation has been used in acute poisoning, but evidence to support its use is poor.[41]

Cancer risk edit

The International Agency for Research on Cancer classifies 2,4-D as a possible carcinogen to humans while the United States Environmental Protection Agency does not.[42][43] The International Agency for Research on Cancer (IARC), said 2,4-D was classified as "possibly carcinogenic to humans (Group 2B), based on inadequate evidence in humans and limited evidence in experimental animals".[44]

In June 2015 the World Health Organization's International Agency for Research on Cancer confirmed its 1987 classification of 2,4-D as a possible carcinogen.[45][46]

On August 8, 2007, the EPA issued a ruling that existing data do not support a link between human cancer and 2,4-D exposure.[47]

A 1995 panel of 13 scientists reviewing studies on the carcinogenicity of 2,4-D had divided opinions. None of the scientists thought the weight of the evidence indicated that 2,4-D was a "known" or "probable" cause of human cancer. The predominant opinion indicated that it is possible that 2,4-D can cause cancer in humans, although not all of the panelists believed the possibility was equally likely: one thought the possibility was strong, leaning toward probable, and five thought the possibility was remote, leaning toward unlikely. Two panelists believed it unlikely that 2,4-D can cause cancer in humans.[48]

In a prior 1987 report the IARC classified some chlorphenoxy herbicides including 2,4-D, MCPA and 2,4,5-T as a group as class 2B carcinogens - "possibly carcinogenic to humans".[49]

2,4-D has been linked to lymphoma and bladder cancer in dogs.[50]

Contaminants edit

A July 2013 Four Corners investigation found elevated levels of dioxins in a generic version of 2,4-D, one of Australia's most widely used herbicides. Samples imported from China, had "one of the highest dioxin readings for 2,4-D in the last 10 to 20 years, and could pose potential health risks."[51]

Metabolism edit

When radioactively labeled 2,4-D was fed to livestock, 90% or more of the total radioactive residue (TRR) was shed in urine unchanged or as conjugated forms of 2,4-D. A relatively small portion of 2,4-D was metabolized into dichlorophenol, dichloroanisole, 4-chlorophenoxyacetic acid (6.9% of the TRR in milk), and 2,4-dichlorophenol (5% of the TRR in milk; 7.3% of the TRR in eggs and 4% of the TRR in chicken liver). Residue levels in kidney were the highest.[33]: 21 

Environmental behavior edit

Owing to the longevity and extent of use, 2,4-D has been evaluated several times by regulators and review committees.[52][53][54]

2,4-D amine salts and esters are not persistent under most environmental conditions.[18] The degradation of 2,4-D is rapid (half life of 6.2 days) in aerobic mineral soils.[40]: 54  2,4-D is broken down by microbes in soil, in processes that involve hydroxylation, cleavage of the acid side-chain, decarboxylation, and ring opening. The ethyl hexyl form of the compound is rapidly hydrolyzed in soil and water to form the 2,4-D acid.[18] 2,4-D has a low binding affinity in mineral soils and sediment, and in those conditions is considered intermediately to highly mobile, and therefore likely to leach if not degraded.[18]

In aerobic aquatic environments, the half life is 15 days. In anaerobic aquatic environments 2,4-D is more persistent, with a half life of 41 to 333 days.[55] 2,4-D has been detected in streams and shallow groundwater at low concentrations, in both rural and urban areas. Breakdown is pH dependent.[18] Some ester forms are highly toxic to fish and other aquatic life.[17]

"The ester forms of 2,4-D can be highly toxic to fish and other aquatic life. 2,4-D generally has moderate toxicity to birds and mammals, is slightly toxic to fish and aquatic invertebrates, and is practically nontoxic to honeybees" per EPA.[39][date missing]

Microbial breakdown edit

A number of 2,4-D-degrading bacteria have been isolated and characterized from a variety of environmental habitats.[56][57] Metabolic pathways for the compound's degradation have been available for many years, and genes encoding 2,4-D catabolism have been identified for several organisms. As a result of the extensive metadata on environmental behavior, physiology, and genetics, 2,4-D was the first herbicide for which the bacteria actively responsible for in situ degradation were demonstrated.[58] This was accomplished using the technique of DNA-based stable isotope probing, which enables a microbial function (activity), such as degrading a chemical, to be linked with the organism's identity without the need to culture the organism involved.[59]

Regulation edit

Maximum residue limits were first set in the EU in 2002 and re-evaluated in 2011 by the European Food Safety Authority, which concluded that the codex maximum residue limits were "not expected to be of concern for European consumers".[33]: 26  The total chronic exposure represented less than 10% of the acceptable daily intake (ADI).[33]: 28  2,4-D is currently not approved for use on lawns and gardens in Denmark, Norway, Kuwait, and the Canadian provinces of Québec[60] and Ontario.[61][failed verification] 2,4-D use is severely restricted in the country of Belize. In 2008, Dow AgroScience, LLC, sued the Canadian government for allowing Quebec to ban 2,4-D, but settled in 2011.[62]

In 2012, EPA denied the petition filed November 6, 2008, by the Natural Resources Defense Council to revoke all tolerances and to cancel all registrations of 2,4-D. EPA stated that new study and EPA's comprehensive review confirmed EPA's previous finding that the 2,4-D tolerances are safe at anticipated exposure.[54][63][64] The estimated annual use of 2,4-D in US agriculture is mapped by the US Geological Service.[65]

In October 2014, the US EPA registered Enlist Duo, an herbicide containing the less volatile 2,4-D choline salt, glyphosate, and an antidrift agent, for use in six states: Illinois, Indiana, Iowa, Ohio, South Dakota, and Wisconsin.[20] In November 2015, the EPA attempted to withdraw its own approval of Enlist Duo, as a result of legal actions against both the agency and Dow by two U.S. groups. However, while it was implied that the approval was "gone" because of the action, in fact, Enlist Duo was still approved pending a decision by the courts. On January 25, 2016, the US Ninth Circuit Court of Appeals denied EPA's motion to vacate its Enlist Duo registration. Dow stated the product would be available in 15 US states and Canada for the 2016 crop season.[66][67]

On 21 August 2013, the Australian Pesticides and Veterinary Medicines Authority (APVMA) banned selected 2,4-D high volatile ester (HVE) products due to their environmental hazards. HVE 2,4-D products had already been banned in Europe and North America for 20 years; low volatile ester products continue to be available in Australia and worldwide.[68] In July 2013 APVMA published their report findings.[69]

Genetically modified crops edit

In 2010, Dow published that it had created genetically modified soybeans made resistant to 2,4-D by insertion of a bacterial aryloxyalkanoate dioxygenase gene, aad1.[70][71][72]: 1  Dow intended it to be used as an alternative or complement to Roundup Ready crops due to the increasing prevalence of glyphosate-resistant weeds.[73]

As of April 2014, genetically modified maize and soybeans resistant to 2,4-D and glyphosate have been approved in Canada.[21] In September 2014, the USDA also approved Dow's maize and soybeans, and in October, the EPA registered the "Enlist Duo" herbicide containing 2,4-D and glyphosate.[20][71][74]

See also edit

References edit

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External links and further reading edit

 
Wikimedia Commons has media related to 2,4-Dichlorophenoxyacetic acid.
  • CDC - NIOSH Pocket Guide to Chemical Hazards
  • Sierra Club Canada January, 2005
  • "Review of 2,4-dichlorophenoxyacetic acid (2,4-D) biomonitoring and epidemiology" Review of the literature by Dow scientists Crit Rev Toxicol. Oct 2012
  • PPDB Pesticides Properties database entry for 2,4-D
  • 2,4-D on Pubchem

February 16, 2024
dichlorophenoxyacetic, acid, organic, compound, with, chemical, formula, cl2c6h3och2co2h, usually, referred, common, name, systemic, herbicide, that, kills, most, broadleaf, weeds, causing, uncontrolled, growth, most, grasses, such, cereals, lawn, turf, grassl. 2 4 Dichlorophenoxyacetic acid is an organic compound with the chemical formula Cl2C6H3OCH2CO2H It is usually referred to by its ISO common name 2 4 D 4 It is a systemic herbicide that kills most broadleaf weeds by causing uncontrolled growth but most grasses such as cereals lawn turf and grassland are relatively unaffected 2 4 Dichlorophenoxyacetic acid NamesPreferred IUPAC name 2 4 Dichlorophenoxy acetic acidOther names 2 4 DIdentifiersCAS Number 94 75 7 Y3D model JSmol Interactive imageChEBI CHEBI 28854 YChEMBL ChEMBL367623 YChemSpider 1441 YECHA InfoCard 100 002 147KEGG C03664 YPubChem CID 1486UNII 2577AQ9262 YCompTox Dashboard EPA DTXSID0020442InChI InChI 1S C8H6Cl2O3 c9 5 1 2 7 6 10 3 5 13 4 8 11 12 h1 3H 4H2 H 11 12 YKey OVSKIKFHRZPJSS UHFFFAOYSA N YInChI 1 C8H6Cl2O3 c9 5 1 2 7 6 10 3 5 13 4 8 11 12 h1 3H 4H2 H 11 12 Key OVSKIKFHRZPJSS UHFFFAOYAMSMILES Clc1cc Cl ccc1OCC O OPropertiesChemical formula C 8H 6Cl 2O 3Molar mass 221 04 g molAppearance white to yellow powderMelting point 140 5 C 284 9 F 413 6 K Boiling point 160 C 320 F 433 K 0 4 mm HgSolubility in water 900 mg LHazardsGHS labelling 3 PictogramsHazard statements H302 H317 H318 H335 H412Precautionary statements P261 P273 P280 P305 P351 P338Flash point nonflammable 1 Lethal dose or concentration LD LC LD50 median dose 500 mg kg oral hamster 100 mg kg oral dog 347 mg kg oral mouse 699 mg kg oral rat 2 NIOSH US health exposure limits PEL Permissible TWA 10 mg m3 1 REL Recommended TWA 10 mg m3 1 IDLH Immediate danger 100 mg m3 1 Safety data sheet SDS ICSC 0033Related compoundsRelated compounds 2 4 5 T DichlorpropExcept where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa Infobox references 2 4 D is one of the oldest and most widely available herbicides and defoliants in the world having been commercially available since 1945 and is now produced by many chemical companies since the patent on it has long since expired It can be found in numerous commercial lawn herbicide mixtures and is widely used as a weedkiller on cereal crops pastures and orchards Over 1 500 herbicide products contain 2 4 D as an active ingredient Contents 1 History 2 Manufacture 3 Mode of action 4 Applications 5 Health effects 5 1 Acute toxicity 5 2 Cancer risk 5 3 Contaminants 6 Metabolism 7 Environmental behavior 7 1 Microbial breakdown 8 Regulation 9 Genetically modified crops 10 See also 11 References 12 External links and further readingHistory editSee also List of multiple discoveries 2 4 D was first reported in 1944 by Franklin D Jones at the C B Dolge Company in Connectecut 5 The biological activity of 2 4 D as well as the similar hormone herbicides 2 4 5 T and MCPA were discovered during World War II a case of multiple discovery by four groups working independently under wartime secrecy in the United Kingdom and the United States William G Templeman and associates at Imperial Chemical Industries ICI in the UK Philip S Nutman and associates at Rothamsted Research in the UK Franklin D Jones and associates at the American Chemical Paint Company and Ezra Kraus John W Mitchell and associates at the University of Chicago and the United States Department of Agriculture All four groups were subject to wartime secrecy laws and did not follow the usual procedures of publication and patent disclosure In December 1942 following a meeting at the Ministry of Agriculture the Rothamsted and ICI workers pooled resources and Nutman moved to Jealott s Hill to join the ICI effort 6 The first scientific publication describing the 2 4 D structure and plant growth regulating activity was by Percy W Zimmerman and Albert E Hitchcock at the Boyce Thompson Institute 7 who were not the original inventors The precise sequence of early 2 4 D discovery events and publications has been discussed 8 William Templeman found that when indole 3 acetic acid IAA a naturally occurring auxin was used at high concentrations it could stop plant growth In 1940 he published his finding that IAA killed broadleaf plants within a cereal field 9 MCPA was discovered at about that time by his ICI group 6 10 Sec 7 1 In the USA a similar search for an acid with a longer half life i e a metabolically and environmentally more stable compound led to 2 4 dichlorophenoxyacetic acid 2 4 D and 2 4 5 trichlorophenoxyacetic acid 2 4 5 T both phenoxy herbicides and analogs of IAA Robert Pokorny an industrial chemist for the C B Dolge Company in Westport Connecticut published their synthesis in 1941 11 2 4 D was not used as a chemical warfare agents during the war 10 Sec 7 1 Britain and the United States were looking for a chemical to starve Germany and Japan into submission by killing their potato and rice crops but 2 4 D was found to be ineffective for that purpose because both crops tolerate it Within a year after the war ended 2 4 D was commercially released as an herbicide to control broadleaf weeds in grain crops such as rice and wheat 12 and in the 1950s it was registered in the United States to control size and enhance skin color in potatoes without affecting yields 13 The first publication of 2 4 D s use as a selective herbicide came in 1944 14 15 The ability of 2 4 D to control broadleaf weeds in turf was documented soon thereafter in 1944 16 Starting in 1945 the American Chemical Paint Company brought 2 4 D to market as an herbicide called Weedone It revolutionized weed control as it was the first compound that at low doses could selectively control dicotyledons broadleaf plants but not most monocotyledons narrowleaf crops such as wheat maize corn rice and similar cereal grass crops 10 At a time when labor was scarce and the need for increased food production was large it literally replaced the hoe 10 Sec 7 1 2 4 D is one of the ingredients in Agent Orange an herbicide that was widely used during the Malayan Emergency and the Vietnam War 17 However 2 3 7 8 tetrachlorodibenzodioxin TCDD a contaminant in the production of another ingredient in Agent Orange 2 4 5 T was the cause of the adverse health effects associated with Agent Orange 18 19 In the 2000s Dow AgroSciences developed a new choline salt version of 2 4 D 2 4 D choline that Dow included in its Enlist Duo herbicide along with glyphosate and an agent that reduces drift the choline salt form of 2 4 D is less volatile than 2 4 D 20 21 22 Manufacture edit2 4 D is a member of the phenoxy family of herbicides 18 It is manufactured from chloroacetic acid and 2 4 dichlorophenol which is itself produced by chlorination of phenol Alternatively it is produced by the chlorination of phenoxyacetic acid The production processes may create several contaminants including di tri and tetrachlorodibenzo p dioxin isomers and N nitrosamines as well as monochlorophenol 23 nbsp Containers of 2 4 D herbicide ca 1947Mode of action edit2 4 D is a synthetic auxin that induces uncontrolled growth and eventually death in susceptible plants 24 25 26 It is absorbed through the leaves and is translocated to the meristems of the plant Uncontrolled unsustainable growth ensues causing stem curl over leaf withering and eventual plant death 2 4 D is typically applied as an amine salt but more potent ester versions exist as well 27 nbsp Effect of 2 4 D foliar application on LantanaApplications edit2 4 D is primarily used as a selective herbicide that kills many terrestrial and aquatic broadleaf weeds but not grasses 2 4 D can be found in commercial lawn herbicide mixtures which often contain other active ingredients including mecoprop and dicamba Over 1 500 herbicide products contain 2 4 D as an active ingredient 28 nbsp Estimated use of 2 4 D in the USA to 2019A variety of sectors use products containing 2 4 D to kill weeds and unwanted vegetation In agriculture it was the first herbicide for selective killing of weeds but not crops It has been used since 1945 29 to control broad leafed weeds in pastures orchards and cereal crops such as corn oats rice and wheat 30 Cereals in particular have excellent tolerance to 2 4 D when it is applied before planting 2 4 D is the cheapest way for farmers to control winter annual weeds by spraying in the fall often at the lowest recommended rate This is particularly effective before planting beans peas lentils and chickpeas 31 The estimated use of 2 4 D in US agriculture is mapped by the US Geological Survey In 2019 the latest date for which figures are available this reached 45 000 000 pounds 20 000 000 kg annually 32 In domestic lawn and garden maintenance 2 4 D is commonly used In forestry it is used for stump treatment trunk injection and selective control of brush in conifer forests Along roadways railways and power lines it is used to control weeds and brush which might interfere with safe operation and damage equipment Along waterways it is used to control aquatic weeds that might interfere with boating fishing and swimming or clog irrigation and hydroelectric equipment It is often used by government agencies to control the spread of invasive noxious and non native weed species and prevent them from crowding out native species and also to control many poisonous weeds such as poison ivy and poison oak 33 35 36 34 A 2010 monitoring study conducted in the US and Canada found that current exposures to 2 4 D are below applicable exposure guidance values 35 2 4 D has been used in laboratories for plant research as a supplement in plant cell culture media such as MS medium since at least 1962 36 2 4 D is used in plant cell cultures as a dedifferentiation callus induction hormone It is classified as an auxin plant hormone derivative 37 Health effects editSee also Health effects of pesticides and Pesticide poisoning Men who work with 2 4 D are at risk for abnormally shaped sperm and thus fertility problems the risk depends on the amount and duration of exposure and other personal factors 38 Acute toxicity edit According to the U S Environmental Protection Agency The toxicity of 2 4 D depends on its chemical forms including salts esters and an acid form 2 4 D generally has low toxicity for humans except certain acid and salt forms can cause eye irritation Swimming is restricted for 24 hours after application of certain 2 4 D products applied to control aquatic weeds to avoid eye irritation 39 As of 2005 update the median lethal dose or LD50 determined in acute toxicity rat studies was 639 mg kg 40 Urinary alkalinisation has been used in acute poisoning but evidence to support its use is poor 41 Cancer risk edit The International Agency for Research on Cancer classifies 2 4 D as a possible carcinogen to humans while the United States Environmental Protection Agency does not 42 43 The International Agency for Research on Cancer IARC said 2 4 D was classified as possibly carcinogenic to humans Group 2B based on inadequate evidence in humans and limited evidence in experimental animals 44 In June 2015 the World Health Organization s International Agency for Research on Cancer confirmed its 1987 classification of 2 4 D as a possible carcinogen 45 46 On August 8 2007 the EPA issued a ruling that existing data do not support a link between human cancer and 2 4 D exposure 47 A 1995 panel of 13 scientists reviewing studies on the carcinogenicity of 2 4 D had divided opinions None of the scientists thought the weight of the evidence indicated that 2 4 D was a known or probable cause of human cancer The predominant opinion indicated that it is possible that 2 4 D can cause cancer in humans although not all of the panelists believed the possibility was equally likely one thought the possibility was strong leaning toward probable and five thought the possibility was remote leaning toward unlikely Two panelists believed it unlikely that 2 4 D can cause cancer in humans 48 In a prior 1987 report the IARC classified some chlorphenoxy herbicides including 2 4 D MCPA and 2 4 5 T as a group as class 2B carcinogens possibly carcinogenic to humans 49 2 4 D has been linked to lymphoma and bladder cancer in dogs 50 Contaminants edit A July 2013 Four Corners investigation found elevated levels of dioxins in a generic version of 2 4 D one of Australia s most widely used herbicides Samples imported from China had one of the highest dioxin readings for 2 4 D in the last 10 to 20 years and could pose potential health risks 51 Metabolism editWhen radioactively labeled 2 4 D was fed to livestock 90 or more of the total radioactive residue TRR was shed in urine unchanged or as conjugated forms of 2 4 D A relatively small portion of 2 4 D was metabolized into dichlorophenol dichloroanisole 4 chlorophenoxyacetic acid 6 9 of the TRR in milk and 2 4 dichlorophenol 5 of the TRR in milk 7 3 of the TRR in eggs and 4 of the TRR in chicken liver Residue levels in kidney were the highest 33 21 Environmental behavior editOwing to the longevity and extent of use 2 4 D has been evaluated several times by regulators and review committees 52 53 54 2 4 D amine salts and esters are not persistent under most environmental conditions 18 The degradation of 2 4 D is rapid half life of 6 2 days in aerobic mineral soils 40 54 2 4 D is broken down by microbes in soil in processes that involve hydroxylation cleavage of the acid side chain decarboxylation and ring opening The ethyl hexyl form of the compound is rapidly hydrolyzed in soil and water to form the 2 4 D acid 18 2 4 D has a low binding affinity in mineral soils and sediment and in those conditions is considered intermediately to highly mobile and therefore likely to leach if not degraded 18 In aerobic aquatic environments the half life is 15 days In anaerobic aquatic environments 2 4 D is more persistent with a half life of 41 to 333 days 55 2 4 D has been detected in streams and shallow groundwater at low concentrations in both rural and urban areas Breakdown is pH dependent 18 Some ester forms are highly toxic to fish and other aquatic life 17 The ester forms of 2 4 D can be highly toxic to fish and other aquatic life 2 4 D generally has moderate toxicity to birds and mammals is slightly toxic to fish and aquatic invertebrates and is practically nontoxic to honeybees per EPA 39 date missing Microbial breakdown edit A number of 2 4 D degrading bacteria have been isolated and characterized from a variety of environmental habitats 56 57 Metabolic pathways for the compound s degradation have been available for many years and genes encoding 2 4 D catabolism have been identified for several organisms As a result of the extensive metadata on environmental behavior physiology and genetics 2 4 D was the first herbicide for which the bacteria actively responsible for in situdegradation were demonstrated 58 This was accomplished using the technique of DNA based stable isotope probing which enables a microbial function activity such as degrading a chemical to be linked with the organism s identity without the need to culture the organism involved 59 Regulation editMaximum residue limits were first set in the EU in 2002 and re evaluated in 2011 by the European Food Safety Authority which concluded that the codex maximum residue limits were not expected to be of concern for European consumers 33 26 The total chronic exposure represented less than 10 of the acceptable daily intake ADI 33 28 2 4 D is currently not approved for use on lawns and gardens in Denmark Norway Kuwait and the Canadian provinces of Quebec 60 and Ontario 61 failed verification 2 4 D use is severely restricted in the country of Belize In 2008 Dow AgroScience LLC sued the Canadian government for allowing Quebec to ban 2 4 D but settled in 2011 62 In 2012 EPA denied the petition filed November 6 2008 by the Natural Resources Defense Council to revoke all tolerances and to cancel all registrations of 2 4 D EPA stated that new study and EPA s comprehensive review confirmed EPA s previous finding that the 2 4 D tolerances are safe at anticipated exposure 54 63 64 The estimated annual use of 2 4 D in US agriculture is mapped by the US Geological Service 65 In October 2014 the US EPA registered Enlist Duo an herbicide containing the less volatile 2 4 D choline salt glyphosate and an antidrift agent for use in six states Illinois Indiana Iowa Ohio South Dakota and Wisconsin 20 In November 2015 the EPA attempted to withdraw its own approval of Enlist Duo as a result of legal actions against both the agency and Dow by two U S groups However while it was implied that the approval was gone because of the action in fact Enlist Duo was still approved pending a decision by the courts On January 25 2016 the US Ninth Circuit Court of Appeals denied EPA s motion to vacate its Enlist Duo registration Dow stated the product would be available in 15 US states and Canada for the 2016 crop season 66 67 On 21 August 2013 the Australian Pesticides and Veterinary Medicines Authority APVMA banned selected 2 4 D high volatile ester HVE products due to their environmental hazards HVE 2 4 D products had already been banned in Europe and North America for 20 years low volatile ester products continue to be available in Australia and worldwide 68 In July 2013 APVMA published their report findings 69 Genetically modified crops editIn 2010 Dow published that it had created genetically modified soybeans made resistant to 2 4 D by insertion of a bacterial aryloxyalkanoate dioxygenase gene aad1 70 71 72 1 Dow intended it to be used as an alternative or complement to Roundup Ready crops due to the increasing prevalence of glyphosate resistant weeds 73 As of April 2014 genetically modified maize and soybeans resistant to 2 4 D and glyphosate have been approved in Canada 21 In September 2014 the USDA also approved Dow s maize and soybeans and in October the EPA registered the Enlist Duo herbicide containing 2 4 D and glyphosate 20 71 74 See also editGenetically modified crops Herbicide resistance Genetic pollutionReferences edit a b c d NIOSH Pocket Guide to Chemical Hazards 0173 National Institute for Occupational Safety and Health NIOSH 2 4 D National Institute for Occupational Safety and Health 4 December 2014 Retrieved 26 February 2015 Sigma Aldrich Co 2 4 D Retrieved on 2022 03 17 Compendium of Pesticide Common Names Pokorny R 1941 New Compounds Some Chlorophenoxyacetic Acids Journal of the American Chemical Society 63 6 1768 doi 10 1021 ja01851a601 a b Allen H et al 1978 Chapter 5 Selective herbicides In Peacock F ed Jealott s Hill Fifty years of Agricultural Research 1928 1978 Imperial Chemical Industries Ltd pp 35 41 ISBN 0901747017 Zimmerman PW Hitchcock AE 1942 Substituted phenoxy and benzoic acid growth substances and the relation of structure to physiological activity Contrib Boyce Thompson Institute 12 321 343 Troyer J 2001 In the beginning the multiple discovery of the first hormone herbicides Weed Science 49 2 290 297 doi 10 1614 0043 1745 2001 049 0290 ITBTMD 2 0 CO 2 S2CID 85637273 Templeman WG Marmoy CJ November 1940 The effect upon the growth of plants of watering with solutions of plant growth substances and of seed dressings containing these materials Annals of Applied Biology 27 4 453 471 doi 10 1111 j 1744 7348 1940 tb07517 x a b c d Andrew H Cobb John P H Reade Herbicides and Plant Physiology Wiley Blackwell 2nd edition October 25 2010 ISBN 978 1405129350 Pokorny R June 1941 New Compounds Some Chlorophenoxyacetic Acids Journal of the American Chemical Society 63 6 1768 doi 10 1021 ja01851a601 The weed crop connection University of California at Davis Archived from the original on 2011 12 07 Retrieved 2015 11 23 Waterer D 1 September 2010 Influence of growth regulators on skin colour and scab diseases of red skinned potatoes Canadian Journal of Plant Science 90 5 745 753 doi 10 4141 CJPS10055 Quastel JH 1950 2 4 Dichlorophenoxyacetic Acid 2 4 D as a Selective Herbicide Agricultural Control Chemicals Advances in Chemistry Vol 1 pp 244 249 doi 10 1021 ba 1950 0001 ch045 ISBN 978 0 8412 2442 1 Hamner CL Tukey HB 1944 The Herbicidal Action of 2 4 Dichlorophenoxyacetic and 2 4 5 Trichlorophenoxyacetic Acid on Bindweed Science 100 2590 154 155 Bibcode 1944Sci 100 154H doi 10 1126 science 100 2590 154 PMID 17778584 Mitchell JW Davis FF and Marth PC 1944 Turf and weed control with plant growth regulators Golfdom 18 34 38 a b 2 4 D General Fact Sheet National Pesticide Information Center Retrieved 7 October 2015 a b c d e f National Pesticide Information Center NPIC 2 4 D Technical Fact Sheet Ingredients Used in Pesticide Products 2 4 D United States Environmental Protection Agency EPA 2014 09 22 Archived from the original on 2022 04 26 Retrieved 24 October 2015 a b c EPA Press Release October 15 2014 EPA Announces Final Decision to Register Enlist Duo Herbicide Containing 2 4 D and Glyphosate Risk assessment ensures protection of human health including infants children EPA Documents Registration of Enlist Duo Archived 2017 08 04 at the Wayback Machine a b Fleury D April 2014 Enlist weed control system in Canada A new tool for managing hard to control and resistant weeds AG Annex Archived from the original on May 3 2014 Retrieved May 3 2014 Josh Flint for Prairie Farmer August 31 2011 Dow AgroSciences Names Its Newest Herbicide Offering Enlist Duo Archived 2014 05 04 at the Wayback Machine International Programme on Chemical Safety 1984 2 4 Dichlorophenoxyacetic Acid 2 4 D UNEP WHO ILO Retrieved 2020 02 02 Synthetic Auxins MSU Extension Montana State University www montana edu Montana State University Extension Retrieved 29 December 2023 Song Y 2014 Insight into the mode of action of 2 4 dichlorophenoxyacetic acid 2 4 D as an herbicide Journal of Integrative Plant Biology 56 2 106 113 doi 10 1111 jipb 12131 PMID 24237670 Weed Control Methods Handbook 2 4 D PDF invasive org University of Georgia Center for Invasive Species and Ecosystem Health April 2001 Retrieved 2015 11 01 Song Y February 2014 Insight into the mode of action of 2 4 dichlorophenoxyacetic acid 2 4 D as an herbicide Journal of Integrative Plant Biology 56 2 106 13 doi 10 1111 jipb 12131 PMID 24237670 EPA Last revised March 30 2007 EPA Chemical Summary 2 4 Dichlorophenoxyacetic Acid 2 4 D Archived September 10 2015 at the Wayback Machine Ganzel B Herbicides 2 4 D amp Its Cousins Wessels Living History Farm Retrieved 2015 11 12 Harvey W Robblns W February 1947 2 4 D as a Weed Killer University of California at Berkeley Retrieved 2015 11 12 Fall Weed Control FAQs PDF Saskatchewan Ministry of Agriculture September 2008 Retrieved 2015 11 12 US Geological Survey 2021 10 12 Estimated Agricultural Use for 2 4 D 2019 Retrieved 2021 12 27 a b c d European Food Safety Authority November 2011 Review of the existing maximum residue levels MRLs for 2 4 D according to Article 12 of Regulation EC No 396 2005 EFSA Journal 9 11 2431 doi 10 2903 j efsa 2011 2431 2 4 D Benefits The Industry Task Force II on 2 4 D Research Data 2015 Archived from the original on 2015 11 02 Retrieved 2015 11 06 Aylward LL Morgan MK Arbuckle TE Barr DB Burns CJ Alexander BH Hays SM February 2010 Biomonitoring data for 2 4 dichlorophenoxyacetic acid in the United States and Canada interpretation in a public health risk assessment context using Biomonitoring Equivalents Environmental Health Perspectives 118 2 177 81 doi 10 1289 ehp 0900970 PMC 2831914 PMID 20123603 Murashige T and F Skoog A revised medium for rapid growth and bioassays with tobaccotissue cultures Physiol Plantarum 1962 15 473 97 in Sharp WR Gunckel JE July 1969 Physiological Comparisons of Pith Callus With Crown Gall and Genetic Tumors of Nicotiana glauca N langsdorffii and N glauca langsdorffii Grown in Vitro II Nutritional Physiology Plant Physiology 44 7 1073 9 doi 10 1104 pp 44 7 1073 PMC 396217 PMID 16657160 Endreb R 1994 Plant Cell Biotechnology Germany Springer pp 17 18 ISBN 978 0 387 56947 5 NIOSH Updated June 2014 The Effects of Workplace Hazards on Male Reproductive Health a b Ingredients Used in Pesticide Products 2 4 D www2 epa gov EPA 2014 09 22 Archived from the original on 2022 04 26 Retrieved November 6 2014 a b US EPA 2 4 D Reregistration Eligibility Decision 2005 Associated RED Fact sheet Archived 2008 05 17 at the Wayback Machine EPA Roberts DM Buckley NA 2007 Roberts DM ed Urinary alkalinisation for acute chlorophenoxy herbicide poisoning Cochrane Database Syst Rev 1 CD005488 doi 10 1002 14651858 CD005488 pub2 PMID 17253558 Pubchem 2 4 Dichlorophenoxyacetic acid pubchem ncbi nlm nih gov Loomis D June 22 2015 Carcinogenicity of lindane DDT and 2 4 dichlorophenoxyacetic acid The Lancet Oncology 16 8 891 892 doi 10 1016 s1470 2045 15 00081 9 PMID 26111929 IARC Monographs evaluate DDT lindane and 2 4 D PDF 23 June 2015 Retrieved 14 February 2016 Loomis D Guyton K Grosse Y El Ghissasi F Bouvard V Benbrahim Tallaa L Guha N Mattock H Straif K August 2015 Carcinogenicity of lindane DDT and 2 4 dichlorophenoxyacetic acid The Lancet Oncology 16 8 891 892 doi 10 1016 S1470 2045 15 00081 9 PMID 26111929 Carey Gillam for Reuters June 22 2015 WHO unit finds 2 4 D herbicide possibly causes cancer in humans Archived 2015 06 23 at the Wayback Machine EPA Federal Register 2 4 D 2 4 DP and 2 4 DB Decision Not to Initiate Special Review Epa gov August 8 2007 Retrieved 2014 05 03 Ibrahim MA Bond GG Burke TA Cole P Dost FN Enterline PE et al 1991 Weight of the evidence on the human carcinogenicity of 2 4 D Environ Health Perspect 96 213 22 doi 10 1289 ehp 9196213 PMC 1568222 PMID 1820267 Chlorphenoxy Herbicides Group 2B in IARC monographs on the evaluation of carcinogenic risks to humans An updating of IARC Monographs volumes 1 to 42 Supplement 7 WHO Lyon France 1987 Harveston K 13 March 2019 Canine Cancers Linked to Lawn Care Chemicals Four Corners By Janine Cohen 22 July 2013 Four Corners investigation finds dangerous dioxins in widely used herbicide 2 4 D Abc net au Retrieved 2014 05 03 Islam F Wang J Farooq MA Khan MS Xu L Zhu J Zhao M Munos S Li QX Zhou W 2018 Potential impact of the herbicide 2 4 dichlorophenoxyacetic acid on human and ecosystems Environment International 111 332 351 doi 10 1016 j envint 2017 10 020 PMID 29203058 von Stackelberg K A 2013 Systematic Review of Carcinogenic Outcomes and Potential Mechanisms from Exposure to 2 4 D and MCPA in the Environment J Toxicol 2013 371610 doi 10 1155 2013 371610 PMC 3600329 PMID 23533401 a b Andrew Pollack for the New York Times April 9 2012 E P A Denies an Environmental Group s Request to Ban a Widely Used Weed Killer Quote The E P A has reviewed the safety of 2 4 D several times particularly with regard to an increased risk of cancer Ju Z Liu S Xu Y Li K 2019 Combined Toxicity of 2 4 Dichlorophenoxyacetic Acid and Its Metabolites 2 4 Dichlorophenol 2 4 DCP on Two Nontarget Organisms ACS Omega 4 1 1669 1677 doi 10 1021 acsomega 8b02282 PMC 6648169 PMID 31459423 Cavalca L A Hartmann N Rouard and G Soulas 1999 Diversity of tfdC genes distribution and polymorphism among 2 4 dichlorophenoxyacetic acid degrading soil bacteria FEMS Microbiology Ecology 29 45 58 Suwa Y Wright A D Fukimori F Nummy K A Hausinger R P Holben W E Forney L J 1996 Characterization of a chromosomally encoded 2 4 dichlorophenoxyacetic acid alpha ketoglutafate dioxygenase from Burkholderia sp strain RASC Applied and Environmental Microbiology 62 7 2464 2469 Bibcode 1996ApEnM 62 2464S doi 10 1128 AEM 62 7 2464 2469 1996 PMC 168028 PMID 8779585 Cupples A M Sims G K 2007 Identification of In Situ 2 4 Dichlorophenoxyacetic Acid Degrading Soil Microorganisms using DNA Stable Isotope Probing Soil Biology and Biochemistry 39 232 238 doi 10 1016 j soilbio 2006 07 011 Radajewski S Ineson P Parekh N R Murrell J C 2000 Stable isotope probing as a tool in microbial ecology Nature 403 6770 646 649 Bibcode 2000Natur 403 646R doi 10 1038 35001054 PMID 10688198 S2CID 4395764 The Pesticides Management Code Protecting the environment and health in our green spaces Mddep gouv qc ca 2005 04 03 Retrieved 2014 05 03 Ministry of the Environment Ontario ca Ene gov on ca Retrieved 2014 05 03 McKenna B May 27 2011 Deal confirms government s right to ban cosmetic pesticides minister says The Globe and Mail Retrieved 26 June 2015 Petition to Revoke All Tolerances and Cancel All Registrations for the Pesticide 2 4 Dichlorophenoxyacetic Acid 2 4 D Notice of Availability Docket Folder Summary Docket ID EPA HQ OPP 2008 0877 Agency EPA United States Environmental Protection Agency April 7 2012 Retrieved September 12 2012 2 4 D Order Denying NRDC s Petition To Revoke Tolerances Order Federal Register 77 75 Wednesday April 18 2012 23135 23158 April 18 2012 Retrieved September 12 2012 Petitions to Revoke Tolerances Denials Natural Resources Defense Council 2 4 dichlorophenoxyacetic acid 2 4D Document ID EPA HQ OPP 2008 0877 0446 Document Type Rule Docket ID EPA HQ OPP 2008 0877 US Geological Survey Estimated Agricultural Use for 2 4 D in the USA 2016 Retrieved 2020 02 15 Vogt W January 26 2016 Ninth Circuit Court denies move by EPA to vacate herbicide label Farm Futures Retrieved 2016 02 05 U S court upholds Enlist Duo registration AGCanada com January 29 2016 Retrieved 2016 02 05 APVMA 2 4 D Review webpage APVMA Archived from the original on 2014 06 06 Retrieved 2014 06 06 Annex to the APVMA s Preliminary Review Findings Environment Part 1 2 4 D Esters Volume 1 Review Summary April 2006 PDF APVMA July 2013 Archived from the original PDF on 6 June 2014 Retrieved 25 August 2016 Wright TR Shan G Walsh TA Lira JM Cui C Song P Zhuang M Arnold NL Lin G Yau K Russell SM Cicchillo RM Peterson MA Simpson DM Zhou N Ponsamuel J Zhang Z 23 November 2010 Robust crop resistance to broadleaf and grass herbicides provided by aryloxyalkanoate dioxygenase transgenes Proceedings of the National Academy of Sciences of the United States of America 107 47 20240 5 Bibcode 2010PNAS 10720240W doi 10 1073 pnas 1013154107 PMC 2996712 PMID 21059954 a b ISAAA GM Approval Database GM Approval Database Genes List Gene aad1 International Service for the Acquisition of Agri biotech Applications ISAAA n d accessed February 27 2015 Mark A Peterson Guomin Shan Terence A Walsh and Terry R Wright Utility of Aryloxyalkanoate Dioxygenase Transgenes for Development of New Herbicide Resistant Crop Technologies ISB News Report 3 pages May 2011 Research amp Development Dow AgroSciences Indianapolis Pollack A April 25 2012 Dow Weed Killer Nearing Approval Runs Into Opposition The New York Times Retrieved April 25 2012 Keim B 25 September 2014 New Generation of GM Crops Puts Agriculture in a Crisis Situation Wired Conde Nast Retrieved 13 April 2015 External links and further reading edit nbsp Wikimedia Commons has media related to 2 4 Dichlorophenoxyacetic acid CDC NIOSH Pocket Guide to Chemical Hazards Overview of the toxic effects of 2 4 D Sierra Club Canada January 2005 Review of 2 4 dichlorophenoxyacetic acid 2 4 D biomonitoring and epidemiology Review of the literature by Dow scientists Crit Rev Toxicol Oct 2012 PPDB Pesticides Properties database entry for 2 4 D 2 4 D on Pubchem Retrieved from https en wikipedia org w index php title 2 4 Dichlorophenoxyacetic acid amp oldid 1197414373, wikipedia, wiki, book, books, library,

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