Mesotrione

History

Main article: 4-hydroxyphenylpyruvate dioxygenase inhibitor#History of the discovery of the triketone class of HPPD inhibitors

The invention of the triketone class of herbicides had its beginnings in an observation in 1977 of allelopathic weed control near a bottlebrush tree, Callistemon citrinus. Chemists at the Stauffer Chemical Company identified the compound responsible as leptospermone, a known natural product which had not previously been reported as having biological activity. Extensive work on analogues led to the discovery and development of sulcotrione and mesotrione.[25][26}[12] :{{multiple image

The triketone herbicides were found to be effective on a wide range of commercially-important weed species and to have both pre- and post-emergence activity. Mesotrione was chosen for development (by Zeneca Agrochemicals under the code number ZA1296) because it controls a wide range of broad-leaved weeds that compete with maize and can also suppress some annual grass weeds that may be present in the crop. It achieves this selectivity and lack of damage to the crop owing to its greater potency on the target enzyme found in dicotyledons than monocotyledons and because maize can metabolise the compound in the dione-containing ring.

Synthesis

The synthesis of mesotrione filed by ICI, who had acquired Stauffer in 1987. 1,3-Cyclohexanedione is first reacted with the acid chloride of 4-(methylsulfonyl)-2-nitrobenzoic acid under conditions in which the enolic hydroxyl group of the diketone reacts to form the benzoylated derivative. In a separate step, this is rearranged to mesotrione using a catalytic amount of cyanide ion derived from acetone cyanohydrin.

:[[File:mesotrione synthesis.png |650px]]

Mechanism of action

Mesotrione inhibits the enzyme 4-hydroxyphenylpyruvate dioxygenase (HPPD).

Formulations

Mesotrione is made available to end-users only in formulated products. These use non-powdery material with reduced or no use of hazardous solvents, for example suspension concentrates. The herbicide is compatible with other compounds that may be mixed by the farmer to extend control to the grass weeds which mesotrione itself does not kill.

Usage

Mesotrione is a systemic pre- and post-emergence herbicide for the selective contact and residual control of broadleaf weeds in field corn, seed corn, yellow popcorn and sweet corn.

The estimated annual use of mesotrione in US agriculture is mapped by the US Geological Service and shows an increasing trend from its introduction in 2001 to 2018, the latest date for which figures are available and now reaching 4500000 lb. As would be expected for a compound used almost exclusively in maize, the heaviest use is in the Corn Belt.

Human safety

The LD50 of mesotrione is over 5000 mg/kg (rats, oral), which means that it is practically non-toxic by oral ingestion, but it can cause serious eye irritation. First aid information is included with the label. The World Health Organization (WHO) and Food and Agriculture Organization (FAO) joint meeting on pesticide residues has determined that the acceptable daily intake for mesotrione is 0-0.5 mg/kg bodyweight. The Codex Alimentarius database maintained by the FAO lists the maximum residue limits for mesotrione in various food products, most of which are set at its 0.01 mg/kg limit of detection.

Effects on the environment

Mesotrione is very toxic to aquatic life with long-lasting effects. Its ecotoxicology is summarised in the Pesticide Properties database.

Resistance management

Reports of individual weed species, for example Amaranthus tuberculatus, becoming resistant to mesotrione are monitored by manufacturers, regulatory bodies such as the EPA and the Herbicides Resistance Action Committee (HRAC). In some cases, the risks of resistance developing can be reduced by using a mixture of two or more herbicides which each have activity on relevant weeds but with unrelated mechanisms of action. HRAC assigns active ingredients into classes so as to facilitate this.

Brands

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 there can be multiple brand names for a given active ingredient. Mesotrione may be pre-mixed with other herbicides to provide more complete weed control. For example, Acuron is the name used by Syngenta for a mixture containing bicyclopyrone, atrazine and S-metolachlor in addition to mesotrione. Brand names for mesotrione include Callisto, Instigate, Meristo, Resicore and Tenacity. Suppliers and brand names in the United States are listed in the National Pesticide Information Retrieval System.

References

References

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