Chlorothalonil


Chlorothalonil is an organic compound mainly used as a broad spectrum, nonsystemic fungicide, with other uses as a wood protectant, pesticide, acaricide, and to control mold, mildew, bacteria, algae. Chlorothalonil-containing products are sold under the names Bravo, Echo, and Daconil. It was first registered for use in the US in 1966. In 1997, the most recent year for which data are available, it was the third most used fungicide in the US, behind only sulfur and copper, with used in agriculture that year. Including nonagricultural uses, the United States Environmental Protection Agency estimates, on average, almost were used annually from 1990 to 1996.

Uses

In the US, chlorothalonil is used predominantly on peanuts, potatoes, and tomatoes, although the EPA recognizes its use on many other crops. It is also used on golf courses and lawns and as a preservative additive in some paints, resins, emulsions, and coatings.
Chlorothalonil is commercially available in many different formulations and delivery methods. It is applied as a dust, dry or water-soluble grains, a wettable powder, a liquid spray, a fog, and a dip. It may be applied by hand, by ground sprayer, or by aircraft.

Mechanism of action

Chlorothalonil reduces deactivates glutathione. Its mechanism of action is similar to that of trichloromethyl sulfenyl fungicides such as captan and folpet.

Toxicity

Acute

According to the EPS, chlorothalonil is a toxicity category I eye irritant, producing severe eye irritation. It is in toxicity category II, "moderately toxic", if inhaled For skin contact and ingestion, chlorothalonil is rated toxicity category IV, "practically nontoxic", meaning the oral and dermal is greater than 10,000 mg/kg.

Chronic

Long-term exposure to chlorothalonil resulted in kidney damage and tumors in animal tests.

Carcinogenic

Chlorothalonil is a Group B2 "probable human carcinogen", based on observations of cancers and tumors of the kidneys and forestomachs in laboratory animals fed diets containing chlorothalonil.

Environmental

Chlorothalonil was found to be an important factor in the decline of the honey bee population, by making the bees more vulnerable to the gut parasite Nosema ceranae.
Chlorothalonil is highly toxic to fish and aquatic invertebrates, but not toxic to birds.
At a concentration of 164 μg/L, chlorothalonil was found to kill a species of frog within a 24-hour exposure.

Contaminants

Common chlorothalonil synthesis procedures frequently result in contamination of it with small amounts of hexachlorobenzene, which is toxic. US regulations limit HCB in commercial production to 0.05% of chlorothalonil. According to the EPA report, “post-application exposure to HCB from chlorothalonil is not expected to be a concern based on the low level of HCB in chlorothalonil. 2,3,7,8-Tetrachlorodibenzodioxin being one of the most potent carcinogens known is also a known contaminant”.

Environmental contamination

Chlorothalonil has been detected in ambient air in Minnesota and Prince Edward Island, as well as in groundwater in Long Island, New York and Florida. In the first three cases, the contamination is presumed to have come from potato farms. It has also been detected in several fish kills in Prince Edward Island.
The main breakdown product of chlorothalonil is hydroxy-2,5,6-trichloro-1,3-dicyanobenzene. It has been shown to be 30 times more acutely toxic than chlorothalonil and more persistent in the environment. Laboratory experiments have shown it can thin the eggshells of birds, but no evidence supports this happening in the environment.
In 2019, a review of the evidence found that "a high risk to amphibians and fish was identified for all representative uses", and that chlorothalonil breakdown products may cause DNA damage. Around the same time, research indicated chlorothalonil and other fungicides to be the strongest factor in bumblebee population decline.

Bans

In March 2019, as a result of the previously mentioned research, the European Union banned the use of chlorothalonil. Switzerland followed in December 2019.

Production

Chlorothalonil can be produced by the direct chlorination of isophthalonitrile or by dehydration of tetrachloroisophthaloyl amide with phosphoryl chloride. It is a white solid. It breaks down under basic conditions, but is stable in neutral and acidic media. Technical grade chlorothalonil contains traces of dioxins and hexachlorobenzene, a persistent organic pollutant banned under the Stockholm Convention.