Herbicide

Weeds killed with herbicide

An herbicide, commonly known as a weedkiller, is a substance used to kill unwanted plants. Selective herbicides kill specific targets while leaving the desired crop relatively unharmed. Some of these act by interfering with the growth of the weed and are often synthetic "imitations" of plant hormones. Herbicides used to clear waste ground, industrial sites, railways and railway embankments are non-selective and kill all plant material with which they come into contact. Smaller quantities are used in forestry, pasture systems, and management of areas set aside as wildlife habitat.

Some plants produce natural herbicides, such as the genus Juglans (walnuts), or the tree of heaven; the study of such natural herbicides, and other related chemical interactions, is called allelopathy.

Herbicides are widely used in agriculture and in landscape turf management. In the U.S., they account for about 70% of all agricultural pesticide use.[1]

Contents

History

Prior to the widespread use of chemical herbicides, cultural controls, such as altering soil pH, salinity, or fertility levels, were used to control weeds. Mechanical control (including tillage) was also (and still is) used to control weeds.

The first widely used herbicide was 2,4-dichlorophenoxyacetic acid, often abbreviated 2,4-D. It was first commercialized by the Sherwin-Williams Paint company and saw use in the late 1940s. It is easy and inexpensive to manufacture, and kills many broadleaf plants while leaving grasses largely unaffected (although high doses of 2,4-D at crucial growth periods can harm grass crops such as maize or cereals). The low cost of 2,4-D has led to continued usage today and it remains one of the most commonly used herbicides in the world. Like other acid herbicides, current formulations utilize either an amine salt (usually trimethylamine) or one of many esters of the parent compound. These are easier to handle than the acid.

2,4-D exhibits relatively good selectivity, meaning, in this case, that it controls a wide number of broadleaf weeds while causing little to no injury to grass crops at normal use rates. A herbicide is termed selective if it affects only certain types of plants, and nonselective if it inhibits a very broad range of plant types. Other herbicides have been more recently developed that achieve higher levels of selectivity than 2,4-D.

The 1950s saw the introduction of the triazine family of herbicides, which includes atrazine, which have current distinction of being the herbicide family of greatest concern regarding groundwater contamination. Atrazine does not break down readily (within a few weeks) after being applied to soils of above neutral pH. Under alkaline soil conditions atrazine may be carried into the soil profile as far as the water table by soil water following rainfall causing the aforementioned contamination. Atrazine is thus said to have carryover, a generally undesirable property for herbicides.

Glyphosate, frequently sold under the brand name Roundup, was introduced in 1974 for non-selective weed control. It is now a major herbicide in selective weed control in growing crop plants due to the development of crop plants that are resistant to it. The pairing of the herbicide with the resistant seed contributed to the consolidation of the seed and chemistry industry in the late 1990s.

Many modern chemical herbicides for agriculture are specifically formulated to decompose within a short period after application. This is desirable as it allows crops which may be affected by the herbicide to be grown on the land in future seasons. However, herbicides with low residual activity (i.e., that decompose quickly) often do not provide season-long weed control.

Health and environmental effects

Herbicides have widely variable toxicity. In addition to acute toxicity from high exposures there is concern of possible carcinogenicity[2] as well as other long-term problems such as contributing to Parkinson's Disease.

Some herbicides cause a range of health effects ranging from skin rashes to death . The pathway of attack can arise from intentional or unintentional direct consumption, improper application resulting in the herbicide coming into direct contact with people or wildlife, inhalation of aerial sprays, or food consumption prior to the labeled pre-harvest interval. Under extreme conditions herbicides can also be transported via surface runoff to contaminate distant water sources. Most herbicides decompose rapidly in soils via soil microbial decomposition, hydrolysis, or photolysis.

Phenoxy herbicides are often contaminated with dioxins such as TCDD; research suggested that such contamination results in a small rise in cancer risk after exposure to these herbicides.[3] Triazine exposure has been implicated in a likely relationship to increased risk of breast cancer, although a causal relationship remains unclear.[4]

Herbicide manufacturers have made bold and false or misleading claims about the safety of their products. Chemical manufacturer Monsanto Company agreed to change its advertising after pressure from New York attorney general Dennis Vacco; Vacco complained about misleading claims that its spray-on glyphosate based herbicides, including Roundup, were safer than table salt and "practically non-toxic" to mammals, birds, and fish.[5] Roundup is toxic and has resulted in death after being ingested in quantities ranging from 85-200 ml, although it has also been ingested in quantities as large as 500ml with only mild or moderate symptoms.[6] The manfucturer of Tordon 101 (Dow AgroSciences, owned by the Dow Chemical Company) has claimed that Tordon 101 has no effects on animals and insects[7], in spite of evidence of strong carcinogenic activity of the active ingredient[8] Picloram in studies on rats.[9]

The risk of Parkinson's Disease has been shown to increase with occupational exposure to herbicides and pesticides.[10] The herbicide paraquat is suspected to be one environmental factor causing Parkinson's disease.[11]

All organic and non-organic herbicides must be extensively tested prior to approval for commercial sale and labeling by the Environmental Protection Agency. However, because of the large number of herbicides in use, there is significant concern regarding health effects. In addition to health effects caused by herbicides themselves, commercial herbicide mixtures often contain other chemicals, including inactive ingredients, which have negative impacts on human health. For example, Roundup contains adjuvants which, even in low concentrations, were found to kill human embryonic, placental, and umbilical cells in vitro.[12]. One study also found that roundup caused genetic damage, but found that the damage was not caused by the active ingredient.[13]

Some herbicides may have therapeutic uses. There is current research into the use of herbicides as an anti-malaria drug that targets the plant-like apicoplast plastid in the malaria-causing parasite Plasmodium falciparum.

Ecological effects

Herbicide use generally has negative impacts on bird populations, although the impacts are highly variable and often require field studies to predict accurately. Laboratory studies have at times overestimated negative impacts on birds due to toxicity, predicting serious problems that were not observed in the field.[14] Most observed effects are due not to toxicity but to habitat changes and the decrease in abundance of species birds rely on for food or shelter. Herbicide use in silviculture, used to favor certain types of growth following clearcutting, can cause significant drops in bird populations. Even when herbicides are used which have low toxicity to birds, the herbicides decrease the abundance of many types of vegetation which the birds rely on.[15] Herbicide use in agriculture in Britain has been linked to a decline in seed-eating bird species which rely on the weeds killed by the herbicides.[16] Heavy use of herbicides in neotropical agricultural areas has been one of many factors implicated in limiting the usefulness of such agricultural land for wintering migratory birds.[17]

Scientific uncertainty

The health and environmental effects of many herbicides is unknown, and even within the scientific community there is often disagreement on the risk. For example, a 1995 panel of 13 scientists reviewing studies on the carcinogenicity of 2,4-D had divided opinions on the likelihood that 2,4-D causes cancer in humans.[18] As of 1992 there were too few studies on phenoxy herbicides to accurately assess the risk of many types of cancer from these herbicides, even though evidence was stronger that exposure to these herbicides is associated with increased risk of soft tissue sarcoma and non-Hodgkin's Lymphoma.[2]

Resistance

Scientists generally agree that selection pressure applied to weed populations for a long enough period of time eventually leads to resistance. Plants have developed resistance to Atrazine and to ALS-inhibitors, and more recently, to glyphosate herbicides. Marestail is one weed that has developed glyphosate resistance.[19]

Classification of herbicides

Herbicides can be grouped by activity, use, chemical family, mode of action, or type of vegetation controlled.

By activity:

By use:

  1. Pre-plant incorporated herbicides are soil applied prior to planting and mechanically incorporated into the soil. The objective for incorporation is to prevent dissipation through photodecomposition and/or volatility.
  2. Preemergent herbicides are applied to the soil before the crop emerges and prevent germination or early growth of weed seeds.
  3. Post-emergent herbicides are applied after the crop has emerged.

Their classification by mechanism of action (MOA) indicates the first enzyme, protein, or biochemical step affected in the plant following application. The main mechanisms of action are:

Bipirydiums herbicides (like Diquat and Paraquat) hit "Fe-S - Fdx step". Diphenilethers herbicides (like Nitrofen , Nitrofluorfen, Acifluoren) hit "Fdx - NADP step".[20]

Organic herbicides

Almost all herbicides in use today are considered "organic" herbicides in that they contain carbon as a primary molecular component. A notable exception would be the arsenical class of herbicides. Sometimes they are referred to as synthetic organic herbicides. Recently the term "organic" has come to imply products used in organic farming. Under this definition an organic herbicide is one that can be used in a farming enterprise that has been classified as organic. Organic herbicides are expensive and may not be affordable for commercial production. They are much less effective than synthetic herbicides and are generally used along with cultural and mechanical weed control practices.

Organic herbicides include:

Application

Most herbicides are applied as water-based sprays using ground equipment. Ground equipment varies in design, but large areas can be sprayed using self-propelled sprayers equipped with a long boom, of 60 to 80 feet (20 to 25 m) with flat fan nozzles spaced about every 20 in (500 mm). Towed, handheld, and even horse-drawn sprayers are also used.

Synthetic organic herbicides can generally be applied aerially using helicopters or airplanes, and can be applied through irrigation systems (chemigation).

A new method of herbicide application involves ridding the soil of its active weed seed bank rather than just killing the weed. Researchers at the Agricultural Research Service have found that applying herbicides to fields late in the weed’s growing season greatly reduces its seed production, and therefore fewer weeds will return the following season. If herbicides are applied at the correct stage in the weed’s growing season, then the weed’s presence in the soil seed bank will greatly be reduced. Because most weeds are annual grasses, their seeds will only survive in soil for a year or two, so this method will be able to “weed out” the weed with only a few years of herbicide application.[26]

Terminology

Major herbicides in use today

Herbicides of historical interest

See also

  • Bioherbicide
  • List of environmental health hazards
  • Rainbow Herbicides
  • Soil contamination
  • Surface runoff
  • Weed

References

  1. Kellogg RL, Nehring R, Grube A, Goss DW, and Plotkin S (February 2000), Environmental indicators of pesticide leaching and runoff from farm fields. United States Department of Agriculture Natural Resources Conservation Service. Retrieved on 2010-08-26.
  2. 2.0 2.1 Howard I. Morrison, Kathryn Wilkins, Robert Semenciw, Yang Mao, Don Wigle, "Herbicides and Cancer", Journal of the National Cancer Institute, Vol. 84, No. 24, 1866-1874, Dec. 16, 1992.
  3. Manolis Kogevinas, Heiko Becher, Trevor Benn, Pier Alberto Bertazzi, Paolo Boffetta, H. Bas Bueno-de-Mesqurta, David Coggon, Didier Colin, Dieter Flesch-Janys, Marilyn Fingerhut, Lois Green, Timo Kauppinen, Margareta Littorin, Elsebeth Lynge, John D. Mathews, Manfred Neuberger, Neil Pearce, Rodolfo Saracci, "Cancer Mortality in Workers Exposed to Phenoxy Herbicides, Chlorophenols, and Dioxins An Expanded and Updated International Cohort Study", American Journal of Epidemiology, Vol. 145, No. 12, pp. 1061-1075.
  4. M K Kettles, S R Browning, T S Prince, and S W Horstman, "Triazine herbicide exposure and breast cancer incidence: an ecologic study of Kentucky counties.", Environ Health Perspect, Nov. 1977, Vol. 105, No. 11, pp. 1222–1227.
  5. "MONSANTO PULLS ROUNDUP ADVERTISING IN NEW YORK", Wichita Eagle, Nov. 27, 1996.
  6. Alan Ronald Talbot, Mon-Han Shiaw, Jinn-Sheng Huang, Shu-Fen Yang, Tein-Shong Goo, Shur-Hueih Wang, Chao-Liang Chen, Thomas Richard Sanford, "Acute Poisoning with a Glyphosate-Surfactant Herbicide ('Roundup'): A Review of 93 Cases", Human & Experimental Toxicology, Vol. 10, No. 1, 1-8 (1991).
  7. "Complaints halt herbicide spraying in Eastern Shore", CBC News, June 16, 2009.
  8. "Tordon 101: picloram/2,4-D", Ontario Ministry of Agriculture Food & Rural Affairs, Reviewed Jan. 21, 2008.
  9. Reuber, MD, " Carcinogenicity of Picloram", Journal of Toxicology and Environmental Health, Vol. 7, no. 2, pp. 207-222. 1981.
  10. J. M. Gorell, MD, C. C. Johnson, PhD, B. A. Rybicki, PhD, E. L. Peterson, PhD and R. J. Richardson, ScD, "The risk of Parkinson's disease with exposure to pesticides, farming, well water, and rural living", Neurology, 1998;50:1346-1350.
  11. R.J. Dinis-Oliveira, F. Remião, H. Carmo, J.A. Duarte, A. Sánchez Navarro, M.L. Bastos and F. Carvalho, "Paraquat exposure as an etiological factor of Parkinson's disease", NeuroToxicology, Vol. 27, No. 6, Dec. 2006, pp. 1110-1122.
  12. Benachour, Nora; Gilles-Eric Séralini (December 23, 2008). "Glyphosate Formulations Induce Apoptosis and Necrosis in Human Umbilical, Embryonic, and Placental Cells". Chemical Research in Toxicology 22 (1): 97–105. doi:10.1021/tx800218n. PMID 19105591. http://pubs.acs.org/doi/abs/10.1021/tx800218n. 
  13. Peluso M, Munnia A, Bolognesi C, Parodi S. Environ Mol Mutagen. 1998 31:55-9 PMID 9464316
  14. Lawrence J. Blus, Charles J. Henny, "FIELD STUDIES ON PESTICIDES AND BIRDS: UNEXPECTED AND UNIQUE RELATIONS", Ecological Applications, Vol. 7, No. 4, pp. 1125-1132.
  15. D. S. MacKinnon and B. Freedman, "Effects of Silvicultural Use of the Herbicide Glyphosate on Breeding Birds of Regenerating Clearcuts in Nova Scotia, Canada", Journal of Applied Ecology, Vol. 30, No. 3 (1993), pp. 395-406.
  16. Ian Newton, "The recent declines of farmland bird populations in Britain: an appraisal of causal factors and conservation actions", Ibis, Vol. 146, No. 4, pp. 579-600.
  17. C.S. Robbins, B.A. Dowell, D.K. Dawson, J.A. Colon, R. Estrada, A. Sutton, R. Sutton, D. Weyer, "Comparison of Neotropical migrant landbird populations wintering in tropical forest, isolated forest fragments, and agricultural habitats."
  18. M. A. Ibrahim, G. G. Bond, T. A. Burke, P. Cole, F. N. Dost, P. E. Enterline, M. Gough, R. S. Greenberg, W. E. Halperin, E. McConnell, I. C. Munro, J. A. Swenberg, S. H. Zahm, and J. D. Graham, "Weight of the evidence on the human carcinogenicity of 2,4-D", Environ Health Perspect., 1991 December; 96: 213–222.
  19. "Marestail Jumps Glyphosate Fence", Corn and Soybean Digest, Jan 1, 2002.
  20. 20.0 20.1 Stryer, Lubert (1995). Biochemistry, 4th Edition. W.H. Freeman and Company. pp. 670. ISBN 0-7167-2009-4. 
  21. Spray Weeds With Vinegar?
  22. Weed Management in Landscapes
  23. Organic Weed Management in Vineyards
  24. Kolberg, Robert L., and Lori J. Wiles. 2002. Effect of steam application on cropland weeds. Weed Technology. Vol. 16, No. 1. p. 43–49
  25. Flame weeding for vegetable crops
  26. "A New Way to Use Herbicides: To Sterilize, Not Kill Weeds". USDA Agricultural Research Service. May 5, 2010. http://www.ars.usda.gov/is/pr/2010/100505.htm. 
  27. Fact sheet

Further reading

External links

General Information
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