Azoxystrobin

Last updated
Azoxystrobin
Azoxystrobin colour.svg
Azoxystrobin-from-xtal-3D-balls.png
Names
Preferred IUPAC name
Methyl (2E)-2-(2-{[6-(2-cyanophenoxy)pyrimidin-4-yl]oxy}phenyl)-3-methoxyprop-2-enoate
Other names
Azoxystrobine, ICIA5504
Identifiers
3D model (JSmol)
8350244
ChEBI
ChEMBL
ChemSpider
DrugBank
ECHA InfoCard 100.127.964 OOjs UI icon edit-ltr-progressive.svg
EC Number
  • 603-524-3
KEGG
PubChem CID
UNII
  • InChI=1S/C22H17N3O5/c1-27-13-17(22(26)28-2)16-8-4-6-10-19(16)30-21-11-20(24-14-25-21)29-18-9-5-3-7-15(18)12-23/h3-11,13-14H,1-2H3/b17-13+ Yes check.svgY
    Key: WFDXOXNFNRHQEC-GHRIWEEISA-N Yes check.svgY
  • InChI=1/C22H17N3O5/c1-27-13-17(22(26)28-2)16-8-4-6-10-19(16)30-21-11-20(24-14-25-21)29-18-9-5-3-7-15(18)12-23/h3-11,13-14H,1-2H3/b17-13+
    Key: WFDXOXNFNRHQEC-GHRIWEEIBD
  • O=C(OC)\C(=C\OC)c3ccccc3Oc2ncnc(Oc1c(C#N)cccc1)c2
Properties [1]
C22H17N3O5
Molar mass 403.388
AppearanceWhite crystalline solid
Density 1.34 g/cm3
Melting point 116°C
6.7 mg/L (20 °C)
log P 2.5
Hazards
GHS labelling: [2]
GHS-pictogram-exclam.svg GHS-pictogram-pollu.svg
Danger
H331, H410
P261, P271, P273, P304+P340, P311, P321, P391, P403+P233, P405, P501
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).

Azoxystrobin is a broad spectrum systemic fungicide widely used in agriculture to protect crops from fungal diseases. It was first marketed in 1996 using the brand name Amistar and by 1999 it had been registered in 48 countries on more than 50 crops. In the year 2000 it was announced that it had been granted UK Millennium product status. [3]

Contents

History

EEE (incorrect first published structure) and EZE strobilurin A with the related natural product fungicide oudemansin A Strobilurin oudemansin.png
EEE (incorrect first published structure) and EZE strobilurin A with the related natural product fungicide oudemansin A
Strobilurus tenacellus 2012-04-22 Strobilurus tenacellus (Pers.) Singer 214245.jpg
Strobilurus tenacellus

In 1977, academic research groups in Germany published details of two new antifungal antibiotics they had isolated from the basidiomycete fungus Strobilurus tenacellus . They named these strobilurin A and B but did not provide detailed structures, only data based on their high-resolution mass spectra, which showed that the simpler of the two had molecular formula C16H18O3. [4] In the following year, further details including structures were published [5] and a related fungicide, oudemansin A from the fungus Oudemansiella mucida , whose identity had been determined by X-ray crystallography, was disclosed. [6] When the fungicidal effects were shown to stem from what was then a novel mode of action, [7] chemists at the Imperial Chemical Industries (ICI) research site at Jealott's Hill became interested to use them as leads to develop new fungicides suitable for use in agriculture. [8] The first task was to synthesize a sample of strobilurin A for testing. In doing so, it was discovered that the structure that had been published was incorrect in the stereochemistry of one of the double bonds: the strobilurins, in fact, have the E,Z,E not E,E,E configuration. Once this was realised and the correct material was made and tested it was shown, as expected, to be active in vitro but insufficiently stable to light to be active in the glasshouse. A large programme of chemistry to make analogues was begun when it was discovered that a new stilbene structure containing the β-methoxyacrylate portion (shown in blue and believed to be the toxophore) had good activity in glasshouse tests but still lacked sufficient photostability. [9] :695–696 After more than 1400 analogues had been made and tested the team chose azoxystrobin for commercialisation and it was developed under the code number ICIA5504. [10] [11]

The stilbene was the first synthetic analogue to show activity and led to azoxystrobin Stilbene leads to azoxystrobin.png
The stilbene was the first synthetic analogue to show activity and led to azoxystrobin

First sales were in 1996 using the brand name Amistar: it then gained fast-track registration in the United States, where it was marketed in 1997 as Heritage. By 1999 it had been registered in 48 countries on more than 50 crops. In the year 2000 it was announced that it had been granted Millennium product status by the UK Prime Minister, Tony Blair, as it had become in three years the world's best-selling fungicide. [3] Meanwhile, BASF scientists who were collaborating with the German academic groups that had discovered strobilurin A had independently invented kresoxim-methyl, which was also launched in 1996. [12]

Synthesis

The first synthesis of azoxystrobin was disclosed in patents filed by the ICI group. [13] The sequence of the two substitution reactions allows for the synthesis of a diverse range of structural analogs via an Ullmann-type etherification between the aryl chloride of the first intermediate and a substituted phenol, thus introducing a range of structural diversity while maintaining the central strobin toxophore. The final choice of 2-cyano phenol in the second step of the synthesis was made after many other alternatives had been tested for their fungicidal properties. [9] :704

Azoxystrobin synthesis.png

The crystal structure was published in 2008. [14]

Mechanism of action

Cytochrome bc1 with bound ubiquinone Cytochrome1ntz.PNG
Cytochrome bc1 with bound ubiquinone

Azoxystrobin and other strobilurins inhibit mitochondrial respiration by blocking electron transport. [7] They bind at the quinol outer binding site of the cytochrome b-c1 complex, where ubiquinone (coenzyme Q10) would normally bind when carrying electrons to that protein. Thus production of ATP is prevented. [15] The generic name for this mode of action is "Quinone Outside Inhibitors" QoI.

Formulations

Azoxystrobin is made available to end-users only in formulated products. Since the active ingredient has moderate solubility in water, formulations aid its use in water-based sprays by creating an emulsion when diluted. Modern products use non-powdery formulations with reduced or no use of hazardous solvents, for example suspension concentrates. The fungicide is compatible with many other pesticides and adjuvants when mixed by the farmer for spraying. [16]

Usage

Azoxystrobin is a xylem-mobile systemic fungicide with translaminar, protectant and curative properties. In cereal crops, its main outlet, the length of disease control is generally about four to six weeks during the period of active stem elongation. [17] [2] All pesticides are required to seek registration from appropriate authorities in the country in which they will be used. [18] In the United States, the Environmental Protection Agency (EPA) is responsible for regulating pesticides under the Federal Insecticide, Fungicide, and Rodenticide Act (FIFRA) and the Food Quality Protection Act (FQPA). [19] A pesticide can only be used legally according to the directions on the label that is included at the time of the sale of the pesticide. The purpose of the label is "to provide clear directions for effective product performance while minimizing risks to human health and the environment". A label is a legally binding document that mandates how the pesticide can and must be used and failure to follow the label as written when using the pesticide is a federal offence. [20] Within the European Union, a 2-tiered approach is used for the approval and authorisation of pesticides. Firstly, before a formulated product can be developed for market, the active substance must be approved for the European Union. After this has been achieved, authorisation for the specific product must be sought from every Member State that the applicant wants to sell it to. Afterwards, there is a monitoring programme to make sure the pesticide residues in food are below the limits set by the European Food Safety Authority.

Azoxystrobin usage in the US to 2019 (estimated) Azoxystrobin use USA.png
Azoxystrobin usage in the US to 2019 (estimated)

Agriculture and Horticulture

Azoxystrobin possesses a broad spectrum of activity, in common with other QoI inhibitors. Examples of the fungal groups on which it is effective are Ascomycota, Deuteromycota, and Basidiomycota, as well as the oomycetes. In addition, its properties mean that it can move systemically through plant tissue to protect parts of the crop that were not in contact with the spray. This combination of properties has meant that it achieved widespread use very quickly and has reached annual sales of more than $500 million. [21] Important diseases which it controls include leaf spot, rusts, powdery mildew, downy mildew, net blotch and blight. Worldwide, azoxystrobin is registered for use on all important crops. For example, in the European Union and United States, it is registered for use in wheat, barley, oats, rye, soya, cotton, rice, strawberry, peas, beans, onions and many other vegetables. [17] [2] The advantage to the farmer comes in the form of improved yield at harvest. Farmers can act in their best economic interest: the value of the additional yield can be estimated and the total cost of using the fungicide informs the decision to purchase. This cost-benefit analysis by the end user sets a maximum price which the supplier can demand and in practice pesticide prices fluctuate according to the current market value of the crops in which they are used. The estimated annual use of azoxystrobin in US agriculture is mapped by the US Geological Survey and shows an increasing trend from its introduction in 1997 to 2019, the latest date for which figures are available, and now reaching 2,300,000 pounds (1,000,000 kg). [22]

Home and garden

One of the earliest uses of azoxystrobin was to control fungal diseases of turf and it has been used on golf courses and lawns. [23] [24] It is now available for domestic markets under brand names such as Heritage and Azoxy 2SC.

Azoxystrobin is added to mold-resistant Purple wallboards (optiSHIELD AT, mixture of azoxystrobin and thiabendazole) and can leach into house dust, [25] potentially providing a source of life-long exposure to children and adults.

Human safety

Azoxystrobin has little toxicity to mammals with an LD50 of over 5000 mg/kg (rats, oral). [1] However, it can cause skin and eye irritation. First aid information is included with the label. [17] [2] The World Health Organization (WHO) and Food and Agriculture Organization (FAO) joint meeting on pesticide residues has determined that the acceptable daily intake for azoxystrobin is 0-0.2 mg/kg bodyweight per day. [26] [27] The Codex Alimentarius database maintained by the FAO lists the maximum residue limits for azoxystrobin in various food products. [28]

Effects on the environment

Azoxystrobin is categorized as having a low potential for bioconcentration and of moderate risk to fish, earthworms and bees but of high risk to aquatic crustaceans, [1] so care must be taken to avoid runoff into water bodies. [2] Its main degradation product, the carboxylic acid resulting from hydrolysis of its methyl ester, is also potentially harmful to aquatic environments. [29] The benefits and risks of use of QoI fungicides have been reviewed [30] and there is extensive literature on azoxystrobin's environmental profile. [31] [32] Ultimately it is the regulatory authorities in each country who must weigh up the benefits to end users and balance these against the compound's inherent hazards and consequent risks to consumers and the wider environment.

Resistance Management

Fungal populations have the ability to develop resistance to QoI inhibitors. This potential can be mitigated by careful management. Reports of individual pest species becoming resistant to azoxystrobin [1] are monitored by manufacturers, regulatory bodies such as the EPA and the Fungicides Resistance Action Committee (FRAC), [33] who assign fungicides into classes by mode of action. [34] In some cases, the risks of resistance developing can be reduced by using a mixture of two or more fungicides which each have activity on relevant pests but with unrelated mechanisms of action. FRAC assigns fungicides into classes so as to facilitate this. On cereal crops in the US, for example, azoxystrobin may only be used in mixture, [2] usually with an azole fungicide such as difenoconazole. [35]

Brands

Azoxystrobin is the ISO common name [36] for the active ingredient which is formulated into the branded product sold to end-users. By international convention and in many countries the law, pesticide labels are required to include the common name of the active ingredients. These names are not the exclusive property of the holder of any patent or trademark and as such they are the easiest way for non-experts to refer to individual chemicals. Companies selling pesticides normally do so using a brand name or wordmark which allows them to distinguish their product from competitor products having the same active ingredient. In many cases, this branding is country and formulation-specific so after several years of sales there can be multiple brand names for a given active ingredient. The situation is made even more complicated when companies license their ingredients to others, as is often done. In addition, the product may be pre-mixed with other pesticides under a new brand name.

It is therefore difficult to provide a comprehensive list of brand names for products containing azoxystrobin. They include Amistar, Abound, Heritage, Olympus, Ortiva, Priori Xtra, Scotts DiseaseEx, [37] Haedes and Quadris. Suppliers and brand names in the United States are listed in the National Pesticide Information Retrieval System. [38]

Related Research Articles

Q<sub>o</sub>I Kind of chemicals used to kill fungus

Qo inhibitors (QoI), or quinone outside inhibitors, are a group of fungicides used in agriculture. Some of these fungicides are among the most popular in the world. QoI are chemical compounds which act at the quinol outer binding site of the cytochrome bc1 complex.

Strobilurins are a group of natural products and their synthetic analogs. A number of strobilurins are used in agriculture as fungicides. They are part of the larger group of QoIs, which act to inhibit the respiratory chain at the level of Complex III.

<span class="mw-page-title-main">Famoxadone</span> Chemical compound

Famoxadone is a fungicide to protect agricultural products against various fungal diseases on fruiting vegetables, tomatoes, potatoes, curcurbits, lettuce and grapes. It is used in combination with cymoxanil. Famoxadone is a QoI, albeit with a chemistry different from most QoIs. It is commonly used against Plasmopara viticola, Alternaria solani, Phytophthora infestans, and Septoria nodorum.

Fungicides are pesticides used to kill parasitic fungi or their spores. Fungi can cause serious damage in agriculture, resulting in critical losses of yield, quality, and profit. Fungicides are used both in agriculture and to fight fungal infections in animals. Fungicides are also used to control oomycetes, which are not taxonomically/genetically fungi, although sharing similar methods of infecting plants. Fungicides can either be contact, translaminar or systemic. Contact fungicides are not taken up into the plant tissue and protect only the plant where the spray is deposited. Translaminar fungicides redistribute the fungicide from the upper, sprayed leaf surface to the lower, unsprayed surface. Systemic fungicides are taken up and redistributed through the xylem vessels. Few fungicides move to all parts of a plant. Some are locally systemic, and some move upward. Most fungicides that can be bought retail are sold in liquid form, the active ingredient being present at 0.08% in weaker concentrates, and as high as 0.5% for more potent fungicides. Fungicides in powdered form are usually around 90% sulfur.

A biopesticide is a biological substance or organism that damages, kills, or repels organisms seen as pests. Biological pest management intervention involves predatory, parasitic, or chemical relationships.

<span class="mw-page-title-main">Diquat</span> Chemical compound

Diquat is the ISO common name for an organic dication that, as a salt with counterions such as bromide or chloride is used as a contact herbicide that produces desiccation and defoliation. Diquat is no longer approved for use in the European Union, although its registration in many other countries including the USA is still valid.

Acibenzolar-<i>S</i>-methyl Chemical compound

Acibenzolar-S-methyl is the ISO common name for an organic compound that is used as a fungicide. Unusually, it is not directly toxic to fungi but works by inducing systemic acquired resistance, the natural defence system of plants.

<span class="mw-page-title-main">Sulfentrazone</span> Chemical compound

Sulfentrazone is the ISO common name for an organic compound used as a broad-spectrum herbicide. It acts by inhibiting the enzyme protoporphyrinogen oxidase. It was first marketed in the US in 1997 by FMC Corporation with the brand name Authority.

<span class="mw-page-title-main">Cyhalothrin</span> Synthetic pyrethroid used as insecticide

Cyhalothrin is an organic compound that, in specific isomeric forms, is used as a pesticide. It is a pyrethroid, a class of synthetic insecticides that mimic the structure and properties of the naturally occurring insecticide pyrethrin which is present in the flowers of Chrysanthemum cinerariifolium. Pyrethroids such as cyhalothrin are often preferred as an active ingredient in agricultural insecticides because they are more cost-effective and longer acting than natural pyrethrins. λ-and γ-cyhalothrin are now used to control insects and spider mites in crops including cotton, cereals, potatoes and vegetables.

<span class="mw-page-title-main">Epoxiconazole</span> Fungicide

Epoxiconazole is a fungicide active ingredient from the class of azoles developed to protect crops. In particular, the substance inhibits the metabolism of fungi cells infesting useful plants, and thereby prevents the growth of the mycelia. Epoxiconazole also limits the production of conidia (mitospores). Epoxiconazole was introduced to the market by BASF SE in 1993 and can be found in many products and product mixtures targeting a large number of pathogens in various crops. Crops are, for example, cereals, soybeans, banana, rice, coffee, turnips, and red as well as sugar beets.

<span class="mw-page-title-main">Mesotrione</span> Chemical compound used as an herbicide

Mesotrione is a selective herbicide used mainly in maize crops. It is a synthetic compound inspired by the natural substance leptospermone found in the bottlebrush tree Callistemon citrinus. It inhibits the enzyme 4-hydroxyphenylpyruvate dioxygenase (HPPD) and is sold under brand names including Callisto and Tenacity. It was first marketed by Syngenta in 2001.

<i>Strobilurus tenacellus</i> Species of fungus

Strobilurus tenacellus, commonly known as the pinecone cap, is a species of agaric fungus in the family Physalacriaceae. It is found in Asia and Europe, where it grows on the fallen cones of pine and spruce trees. The fruit bodies (mushrooms) are small, with convex to flat, reddish to brownish caps up to 15 mm (0.6 in) in diameter, set atop thin cylindrical stems up to 4–7.5 cm (1.6–3.0 in) long with a rooting base. A characteristic microscopic feature of the mushroom is the sharp, thin-walled cystidia found on the stipe, gills, and cap. The mushrooms, sometimes described as edible, are too small to be of culinary interest. The fungus releases compounds called strobilurins that suppress the growth and development of other fungi. Derivatives of these compounds are used as an important class of agricultural fungicides.

<span class="mw-page-title-main">Oudemansin A</span> Chemical compound

Oudemansin A is a natural product first isolated from the basidiomycete fungus Oudemansiella mucida. Its chemical structure was determined by X-ray crystallography in 1979 and absolute stereochemistry by total synthesis. Two closely related derivatives, oudemansin B and X have also been isolated from other basidiomycetes. They are all biologically active against many filamentous fungi and yeasts but with insufficient potency and stability to become useful commercial products. However, their discovery, together with the strobilurins led to agricultural fungicides including azoxystrobin with the same mechanism of action.

<span class="mw-page-title-main">Fluxapyroxad</span> Chemical compound

Fluxapyroxad is a broad-spectrum pyrazole-carboxamide fungicide used on a large variety of commercial crops. It stunts fungus growth by inhibiting the succinate dehydrogenase (SQR) enzyme. Application of fluxapyroxad helps prevent many wilts and other fungal infections from taking hold. As with other systemic pesticides that have a long chemical half-life, there are concerns about keeping fluxapyroxad out of the groundwater, especially when combined with pyraclostrobin. There is also concern that some fungi may develop resistance to fluxapyroxad.

<span class="mw-page-title-main">Cyproconazole</span> Chemical compound

Cyproconazole is an agricultural fungicide of the class of azoles, used on cereal crops, coffee, sugar beet, fruit trees and grapes, and peanuts, on sod farms and golf course turf and on wood as a preservative. It has been used against powdery mildew, rust on cereals and apple scab, and applied by air or on the ground or by chemigation.

<span class="mw-page-title-main">Sedaxane</span> Chemical compound

Sedaxane is a broad spectrum fungicide used as a seed treatment in agriculture to protect crops from fungal diseases. It was first marketed by Syngenta in 2011 using their brand name Vibrance. The compound is an amide which combines a pyrazole acid with an aryl amine to give an inhibitor of succinate dehydrogenase.

<span class="mw-page-title-main">Carboxin</span> Chemical compound used to kill fungi

Carboxin is a narrow-spectrum fungicide used as a seed treatment in agriculture to protect crops from fungal diseases. It was first marketed by Uniroyal in 1969 using their brand name Vitavax. The compound is an anilide which combines a heterocyclic acid with aniline to give an inhibitor of succinate dehydrogenase (SDHI).

<span class="mw-page-title-main">Boscalid</span> Chemical compound used to kill fungi

Boscalid is a broad spectrum fungicide used in agriculture to protect crops from fungal diseases. It was first marketed by BASF in 2002 using their brand name Endura. The compound is an biphenyl amide derived inhibitor of succinate dehydrogenase.

<span class="mw-page-title-main">Pydiflumetofen</span> Chemical compound used to kill fungi

Pydiflumetofen is a broad spectrum fungicide used in agriculture to protect crops from fungal diseases. It was first marketed by Syngenta in 2016 using their brand name Miravis. The compound is an amide which combines a pyrazole acid with a substituted phenethylamine to give an inhibitor of succinate dehydrogenase, an enzyme that inhibits cellular respiration in almost all living organisms.

<span class="mw-page-title-main">Methoxyacrylates</span> Class of chemical compounds

Methoxyacrylates are a group of organic compounds primarily used as fungicides. They comprise an acrylic acid ester unit that also includes a methoxy group, making them a type of enol ether.

References

  1. 1 2 3 4 Pesticide Properties Database. "Azoxystrobin". University of Hertfordshire.
  2. 1 2 3 4 5 6 Syngenta US. "Quadris Flowable fungicide".
  3. 1 2 "Syngenta: Celebrating 75 years of scientific excellence at Jealott's Hill International Research Centre" (PDF). Syngenta. 2003. Archived from the original (PDF) on October 11, 2007.
  4. Anke, T.; Oberwinkler, F.; Steglich, W.; Schramm, G. (1977). "The strobilurins - New antifungal antibiotics from the basidiomycete Strobilurus tenacellus". The Journal of Antibiotics. 30 (10): 806–810. doi: 10.7164/antibiotics.30.806 . PMID   563391.
  5. Schramm, Georg; Steglich, Wolfgang; Anke, Timm; Oberwinkler, Franz (1978). "Antibiotika aus Basidiomyceten, III. Strobilurin A und B, antifungische Stoffwechselprodukte aus Strobilurus tenacellus". Chemische Berichte. 111 (8): 2779–2784. doi:10.1002/cber.19781110806.
  6. Anke, Timm; Hecht, Hans Jürgen; Chramm, Georgs; Steglich, Wolfgang (1979). "Antibiotics from basidiomycetes. IX. Oudemansin, an antifungal antibiotic from Oudemansiella mucida (Schrader ex Fr.) hoehnel (Agaricales)". The Journal of Antibiotics. 32 (11): 1112–1117. doi: 10.7164/antibiotics.32.1112 . PMID   528381.
  7. 1 2 Becker, W.F.; von Jagow, G.; Anke, T.; Steglich, W. (1981). "Oudemansin, strobilurin A, strobilurin B and myxothiazol: New inhibitors of the bc 1 segment of the respiratory chain with an E-β-methoxyacrylate system as common structural element". FEBS Letters. 132 (2): 329–333. doi:10.1016/0014-5793(81)81190-8. PMID   6271595. S2CID   11294426.
  8. Clough, J. M. (1993). "The strobilurins, oudemansins, and myxothiazols, fungicidal derivatives of β-methoxyacrylic acid". Nat. Prod. Rep. 10 (6): 565–574. doi:10.1039/NP9931000565. PMID   8121648.
  9. 1 2 Schaefer, Bernd (2014). "Agrochemicals: 8.2 Strobilurins". Natural Products in the Chemical Industry. pp. 688–704. doi:10.1007/978-3-642-54461-3_8. ISBN   978-3-642-54460-6.
  10. Bartlett, Dave W.; Clough, John M.; Godwin, Jeremy R.; Hall, Alison A.; Hamer, Mick; Parr-Dobrzanski, Bob (2002). "The strobilurin fungicides". Pest Management Science. 58 (7): 649–662. doi:10.1002/ps.520. PMID   12146165.
  11. Clough, J.M.; Godfrey, C.R.A. (1998). "The strobilurin fungicides". In Hutson, David Herd; Miyamoto, Junshi (eds.). Fungicidal activity: Chemical and biological approaches to plant protection. pp. 109–148. ISBN   9780471968061.
  12. Sauter, Hubert; Steglich, Wolfgang; Anke, Timm (1999). "Strobilurins: Evolution of a New Class of Active Substances". Angewandte Chemie International Edition. 38 (10): 1328–1349. doi:10.1002/(SICI)1521-3773(19990517)38:10<1328::AID-ANIE1328>3.0.CO;2-1. PMID   29711574.
  13. EPpatent 0382375,Clough, J.M.; Godfrey, C.R.A.& Streeting, I.T.et al.,"Fungicides",issued 1994-03-23, assigned to ICI plc
  14. Chopra, D.; Mohan, T.P.; Rao, K.S.; Row, T.N.G. (2008). "Crystal Structure". CCDC 667485: Experimental Crystal Structure Determination. Cambridge Crystallographic Data Centre. doi:10.5517/ccqdksf.
  15. Moore, David; Robson, Geoffrey D.; Trinci, Anthony P.J. "Agricultural mycocides for the 21st century: strobilurins". Archived from the original on 2019-09-08. Retrieved 2020-02-02.
  16. Syngenta UK (2016-03-08). "Amistar".
  17. 1 2 3 Syngenta UK. "Amistar Product label" (PDF).
  18. Willson HR (1996). "Pesticide Regulations". In Radcliffe EB, Hutchison WD, Cancelado RE (eds.). Radcliffe's IPM World Textbook. St. Paul: University of Minnesota. Archived from the original on July 13, 2017.
  19. "Pesticides and Public Health". Pesticides: Health and Safety. US EPA. 2015-08-20. Archived from the original on January 14, 2014. Retrieved 2020-02-04.
  20. EPA (2013-02-27). "The Pesticide Label" . Retrieved 2020-02-02.
  21. Armstrong, Sarah; Clough, John (1 March 2009). "Crop protection chemicals". Education in Chemistry . Vol. 46, no. 2. Royal Society of Chemistry. pp. 52–56. Retrieved 2020-02-02.
  22. US Geological Survey (2021-10-12). "Estimated Agricultural Use for azoxystrobin, 2019" . Retrieved 2021-12-26.
  23. EPA. "Azoxystrobin fact sheet" (PDF). Archived from the original (PDF) on 2008-07-24.
  24. Clemson Cooperative Extension. "Leaf Diseases of Lawns".
  25. Cooper, Ellen M.; Rushing, Rosie; Hoffman, Kate; Phillips, Allison L.; Hammel, Stephanie C.; Zylka, Mark J.; Stapleton, Heather M. (2020). "Strobilurin fungicides in house dust: is wallboard a source?". Journal of Exposure Science & Environmental Epidemiology. 30 (2): 247–252. doi:10.1038/s41370-019-0180-z. ISSN   1559-064X. PMC   7044059 . PMID   31636368.
  26. "Pesticide Residues in Food 2008" (pdf). Pesticide Residues in Food: Report and Evaluations: Joint Fao/Who Meeting on Pesticide Residues: 55–96. ISBN   9789251061138. ISSN   0259-2517.
  27. Shah, P.V.; Ray, David. "Azoxystrobin" (pdf). WHO.
  28. FAO / WHO. "Azoxystrobin".
  29. Jørgensen, Lisbeth Flindt; Jeanne Kjær; Preben Olsen; Annette Elisabeth Rosenbom (July 2012). "Leaching of azoxystrobin and its degradation product R234886 from Danish agricultural field sites". Chemosphere. 88 (5): 554–562. Bibcode:2012Chmsp..88..554J. doi:10.1016/j.chemosphere.2012.03.027. PMID   22497784.
  30. Vincelli, P. (2012). "QoI (Strobilurin) Fungicides: Benefits and Risks". American Phytopathological Society.
  31. "Azoxystrobin". U.S. National Library of Medicine. Retrieved 2020-02-02.
  32. Code of Federal Regulations 40 Protection of Environment: Parts 150 to 189. National Archives & Records Administration. October 2005. ISBN   9780160739637.
  33. "Fungicides Resistance Action Committee website".
  34. "Fungal control agents sorted by cross resistance pattern and mode of action" (PDF). 2020. Archived from the original (PDF) on 2021-08-16. Retrieved 2020-09-04.
  35. Syngenta US. "Amistar-top".
  36. "Compendium of Pesticide Common Names: Azoxystrobin". BCPC. Retrieved 2023-07-27.
  37. "Scotts® DiseaseExTM Lawn Fungicide". Scotts . 2017-11-01. Retrieved 2022-05-28.
  38. NPIRS Public. "Search Federal Pesticide Products".

Further reading