Pesticide toxicity to bees
Pesticides vary in their effects on bees. Contact pesticides are usually sprayed on plants and can kill bees when they crawl over sprayed surfaces of plants or other areas around it. Systemic pesticides, on the other hand, are usually incorporated into the soil or onto seeds and move up into the stem, leaves, nectar, and pollen of plants.[1]
Of contact pesticides, dust and wettable powder pesticides tend to be more hazardous to bees than solutions or emulsifiable concentrates. When a bee comes in contact with pesticides while foraging, the bee may die immediately without returning to the hive. In this case, the queen bee, brood, and nurse bees are not contaminated and the colony survives. Alternatively, the bee may come into contact with an insecticide and transport it back to the colony in contaminated pollen or nectar or on its body, potentially causing widespread colony death.[2]
Actual damage to bee populations is a function of toxicity and exposure of the compound, in combination with the mode of application. A systemic pesticide, which is incorporated into the soil or coated on seeds, may kill soil-dwelling insects, such as grubs or mole crickets as well as other insects, including bees, that are exposed to the leaves, fruits, pollen, and nectar of the treated plants.[3]
Pesticides, especially neonicotinoids, have been investigated in relation to Colony Collapse Disorder. Potentially toxic effects studied in the laboratory have often been followed by field studies that fail to show effects on actual bee populations.[4] Despite gaps in the scientific evidence, regulators have restricted the use of neonicotinoids in Europe[5] and elsewhere[6] largely on the basis of concerns for bee health.
Classification[]
Insecticide toxicity is generally measured using acute contact toxicity values LD50 – the exposure level that causes 50% of the population exposed to die. Toxicity thresholds are generally set at[7][8]
- highly toxic (acute LD50 < 2μg/bee)
- moderately toxic (acute LD50 2 - 10.99μg/bee)
- slightly toxic (acute LD50 11 - 100μg/bee)
- nontoxic (acute LD50 > 100μg/bee) to adult bees.
Pesticide toxicity[]
Acute toxicity[]
The acute toxicity of pesticides on bees, which could be by contact or ingestion, is usually quantified by LD50. Acute toxicity of pesticides causes a range of effects on bees, which can include agitation, vomiting, wing paralysis, arching of the abdomen similar to sting reflex, and uncoordinated movement. Acute toxicity may depend on the mode of exposure, for instance, many pesticides cause toxic effects by contact while neonicotinoids are more toxic when consumed orally.[citation needed] The acute toxicity, although more lethal, is less common than sub-lethal toxicity or cumulative effects.[9]
Sublethal and chronic effects[]
Field exposure to pesticides, especially with relation to neonicotinoids,[10] may lead to multiple physiological and/or behavioral sublethal effects in exposed bees.[11] Sublethal effects to honey bees can include behavioral disruptions such as disorientation,[12] thermoregulation,[13] reduced foraging,[14] decreased flight[15] and locomotion[16][17] abilities, impaired memory and learning, phototaxis (response to light),[16] and altered communication behaviors.[citation needed] Additional sub-lethal effects may include compromised immunity of bees and delayed development.[18]
Colony collapse disorder[]
Colony collapse disorder (CCD) is a syndrome that is characterized by the sudden loss of adult bees from the hive. Many possible explanations for it have been proposed, but no one primary cause has been found. The US Department of Agriculture indicated in a 2010 report to Congress that a combination of factors could be causing colony collapse disorder, including pesticides, pathogens, and parasites. Although pesticides were suspected to be part of the problem, a survey of healthy and CCD-affected colonies revealed similar levels of pesticides in wax and pollen.[19]
Bee kill rate per hive[]
The kill rate of bees in a single bee hive can be classified as:[20]
- < 100 bees per day - normal die off rate
- 200-400 bees per day - low kill
- 500-900 bees per day - moderate kill
- 1000+ bees per day - High Kill
Pesticide formulations[]
Pesticides come in different formulations:[2]
- Dusts (D)
- Wettable powders (WP)
- Soluble powders (SP)
- Emulsifiable concentrates (EC)
- Solutions (LS)
- Granulars (G)
Pesticides[]
All substances listed are insecticides, except for 2,4-D, which is an herbicide. Some substances are arachnicides too.
Common name (ISO) | Examples of Brand names | Pesticide Class | length of residual toxicity | Comments | Bee toxicity |
---|---|---|---|---|---|
Aldicarb | Temik | Carbamate | apply 4 weeks before bloom | Relatively nontoxic | |
Carbaryl[21] | Sevin,
(b) Sevin XLR |
Carbamate | High risk to bees
foraging even 10 hours after spraying; 3 – 7 days (b) 8 hours @ 1.5 lb/acre (1681 g/Ha) or less. |
Bees poisoned with carbaryl can take 2–3 days to die, appearing inactive as if cold. Sevin should never be sprayed on flowering crops, especially if bees are active and the crop requires pollination. Less toxic formulations exist. | Highly toxic |
Carbofuran[22] | Furadan | Carbamate | 7 – 14 days | U.S. Environmental Protection Agency ban on use on crops grown for human consumption (2009) carbofuran (banned in granular form)[22] | Highly toxic |
Methomyl[23] | Lannate, Nudrin | Carbamate | 2 hours | Should never be sprayed on flowering crops especially if bees are active and the crop requires pollination. | Highly toxic |
Methiocarb | Mesurol | Carbamate | Highly toxic | ||
Mexacarbate[24] | Zectran | Carbamate | Highly toxic | ||
Pirimicarb | Pirimor, Aphox | Carbamate | Relatively nontoxic | ||
Propoxur[25] | Baygon | Carbamate | Propoxur is highly toxic to honey bees. The LD50 for bees is greater than one ug/honey bee.[citation needed] | Highly toxic | |
Acephate[26] | Orthene | Organophosphate | 3 days | Acephate is a broad-spectrum insecticide and is highly toxic to bees and other beneficial insects.[27] | Moderately toxic |
Azinphos-methyl[28] | Guthion, Methyl-Guthion | Organophosphate | 2.5 days | Banned in EU since 2006.[29] | Highly toxic |
Chlorpyrifos[30] | Dursban, Lorsban | Organophosphate | Banned in US for home and garden use. Should never be sprayed on flowering crops especially if bees are active and the crop requires pollination. | Highly toxic | |
Coumaphos[31] | Checkmite | Organophosphate | This is an insecticide that is used inside the beehive to combat varroa mites and small hive beetles, which are parasites of the honey bee. Overdoses can lead to bee poisoning. | Relatively nontoxic | |
Demeton | Systox | Organophosphate | <2 hours | Highly toxic | |
Demeton-S-methyl[32] | Meta-systox | Organophosphate | Banned worldwide for toxicity to humans | Moderately toxic | |
Diazinon[33] | Spectracide | Organophosphate | Sale of diazinon for residential use was discontinued in the U.S. in 2004. Should never be sprayed on flowering crops especially if bees are active and the crop requires pollination. | Highly toxic | |
Dicrotophos[34] | Bidrin | Organophosphate | Dicrotophos toxicity duration is about one week.[35] | highly toxic | |
Dichlorvos[36] | DDVP, Vapona | Organophosphate | Highly toxic | ||
Dimethoate[37] | Cygon, De-Fend | Organophosphate | 3 days | Should never be sprayed on flowering crops especially if bees are active and the crop requires pollination. | Highly toxic |
Fenthion[38] | Entex, Baytex, Baycid, Dalf, DMPT, Mercaptophos, Prentox, Fenthion 4E, Queletox,Lebaycid | Organophosphate | Should never be sprayed on flowering crops especially if bees are active and the crop requires pollination. | Highly toxic | |
Fenitrothion[39] | Sumithion | Organophosphate | Highly toxic | ||
Fensulfothion | Dasanit | Organophosphate | Highly toxic | ||
Fonofos[40] | Dyfonate EC | Organophosphate | 3 hours | List of Schedule 2 substances (CWC) | Highly toxic |
Malathion | Malathion USB, ~ EC, Cythion, maldison, mercaptothion | Organophosphate | >8 fl oz/acre (58 L/km2) ⇒ 5.5 days | Malathion is highly toxic to bees and other beneficial insects, some fish, and other aquatic life. Malathion is moderately toxic to other fish and birds, and is considered low in toxicity to mammals.[41] | Highly toxic |
Methamidophos[42] | Monitor, Tameron | Organophosphate | Should never be sprayed on flowering crops especially if bees are active and the crop requires pollination. | Highly toxic | |
Methidathion[43] | Supracide | Organophosphate | Should never be sprayed on flowering crops especially if bees are active and the crop requires pollination. | Highly toxic | |
Methyl parathion | Parathion,[44] Penncap-M | Organophosphate | 5–8 days | It is classified as a UNEP persistent organic pollutant and WHO Toxicity Class, "Ia, Extremely Hazardous".[citation needed] | Highly toxic |
Mevinphos[45] | Phosdrin | Organophosphate | highly toxic | ||
Monocrotophos[46] | Azodrin | Organophosphate | Should never be sprayed on flowering crops especially if bees are active and the crop requires pollination. | Highly toxic | |
Naled[47] | Dibrom | Organophosphate | 16 hours | Highly toxic | |
Omethoate | Organophosphate | Should never be sprayed on flowering crops especially if bees are active and the crop requires pollination. | Highly toxic | ||
Oxydemeton-methyl[48] | Metasystox-R | Organophosphate | <2 hours | Highly toxic | |
Phorate[49] | Thimet EC | Organophosphate | 5 hours | Highly toxic | |
Phosmet[50] | Imidan | Organophosphate | Phosmet is very toxic to honeybees.[51] | Highly toxic | |
Phosphamidon | Dimecron | Organophosphate | Highly toxic | ||
Pyrazophos | Afugan | Organophosphate | Fungicide | Highly toxic | |
Tetrachlorvinphos | Rabon, Stirofos, Gardona, Gardcide | Organophosphate | Highly toxic | ||
Trichlorfon, Metrifonate | Dylox, Dipterex | Organophosphate | 3 – 6 hours | Relatively nontoxic | |
Bifenthrin[52][53] | Agri-Medk, Abamectin, Talstar, Bifenthrine, Brigade, Capture, FMC 54800, OMS3024, Torant (with Clofentezine), and Zipak (with Amitraz)[54] | Pyrethroid | < 1 day RT
> 1 day ERT |
Highly toxic | |
Permethrin[55] | Ambush, Pounce | Pyrethroid | 1 – 2 days | Safened by repellency under arid conditions. Permethrin is also the active ingredient in insecticides used against the Small hive beetle, which is a parasite of the beehive in the temperate climate regions. | Highly toxic |
Cypermethrin[56] | Ammo, Demon, Raid, Viper | Pyrethroid | Less than 2 hours | Cypermethrin is found in many household ant and cockroach killers, including Raid and ant chalk. | Highly toxic |
Fenvalerate[57] | Asana, Pydrin | Pyrethroid | 1 day | Safened by repellency under arid conditions | Highly toxic |
Resmethrin[58][59][60] | Black Flag Mosquito Fog Solution, Chrysron, Crossfire, Pynosect, Raid Flying Insect Killer, Scourge, Sun-Bugger #4, SPB-1382, Synthrin, Syntox, Vectrin, Whitmire PT-110 | Pyrethroid | Resmethrin is highly toxic to bees, with an LD50 of 0.063 ug/bee.[citation needed] | Highly toxic | |
Methoxychlor[61] | DMDT, Marlate | Chlorinated cyclodiene | 2 hours | available as a General Use Pesticide | Highly toxic |
Endosulfan[62] | Thiodan | Chlorinated cyclodiene | 8 hours | Banned in EU (2007?), Banned in NZ (2009) | Moderately toxic |
Clothianidin | Poncho | Neonicotinoid | Banned in EU for outdoor use since 2018. | Highly Toxic[63] | |
Thiamethoxam | Actara | Neonicotinoid | Banned in EU for outdoor use since 2018. | Highly Toxic | |
Imidacloprid | Confidor, Gaucho, Kohinor, Admire, Advantage, K9 Advantix, Merit, Confidor, Hachikusan, Amigo, SeedPlus (Chemtura Corp.), Monceren GT, Premise, Prothor, Winner | Neonicotinoid | Banned in France since 1999. Banned in EU for outdoor use since 2018. | Highly toxic | |
Fipronil | Regent, Goliath, Nexa, Adonis, Termidor, Ultrathor, Fipforce, Taurus, Combat Ant-Rid, Anthem, Clearout, Radiate | Phenylpyrazole | Banned in EU for use on maize and sunflowers since 2014. | Highly toxic | |
Sulfoxaflor | Sulfoximine | [64][65] | |||
Dicofol | Acaricide | Relatively nontoxic | |||
Petroleum oils | Relatively nontoxic | ||||
2,4-D[66] | Weed B Gon (also contains dicamba), ingredient in over 1,500 products | Synthetic auxin herbicide | Relatively nontoxic |
Highly toxic and banned in the US[]
- Aldrin Banned by US EPA in 1974.[67]
- Dieldrin Banned by US EPA in 1974.[68]
- Heptachlor[69]
- Lindane, BHC Banned in California.[70] Banned for agricultural use in the US by the EPA in 2006.[71]
Regulatory policy[]
Based on a risks to bee health as identified by the European Food Safety Authority (EFSA), in April 2013 the EU decided to restrict the use of the neonicotinoids thiamethoxam, clothianidin, and imidacloprid.[72] Fipronil was also banned for use on maize and sunflowers.[citation needed]
In 2015, the US Environmental Protection Agency (EPA) proposed to prohibit the application of certain pesticides and herbicides that are known to be toxic to bees during pollination periods when crops are in bloom. Seed treatments were not considered to present a risk to bee health. A modified form of these proposals was adopted as EPA policy in January 2017.[73]
In April 2018, member states of the European Union agreed upon a total ban on neonicotinoid insecticide use, except within closed greenhouses.[5] The vote on the proposed ban followed a February 2018 report from the EFSA which concluded that neonicotinoids posed a high risk to both domestic and wild bees.[74] The ban had strong public support, but faced criticism from the agrochemical industry, and from certain farmers' groups.[75]
In 2020, the EPA supplemented its policy with a proposal to restrict the use of neonicotinoids on residential lawns and turf, but otherwise confirmed that they would remain in use in the US.[76]
General measures to prevent pesticide bee kills[]
Application of pesticides at evening or night[]
Avoiding the application of pesticides directly to blooming flowers can help limit the exposure of honeybees to toxic materials. If blooming flowers must be sprayed with pesticides for any reason, they should be sprayed in the evening or night hours when bees are not in the field. The usual foraging hours of honeybees are during the daytime when the temperature is above 55–60 °F (13–16 °C).[2][53][77]
See also[]
- Bees and toxic chemicals
- Colony Collapse Disorder
- Neonicotinoids
- United States Environmental Protection Agency
- Pollination
- Endangered arthropod
- Pesticide misuse
- Pesticides
- Pollinator decline
- Fipronil
- Imidacloprid effects on bees
- Honey bee starvation
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External links[]
- "Honey Bees and Pesticides". Mid-Atlantic Apiculture Research and Extension Consortium. 1978. Archived from the original on 11 March 2007. Retrieved 23 July 2021.
- Hooven L, Sagili R, Johansen E (2016). "How to Reduce Bee Poisoning from Pesticides". Oregon State University. Retrieved 23 July 2021.
- Mayer DF, Johansen CA, Baird CR (1999). "How to Reduce Bee Poisoning from Pesticides" (PDF). Washington State University. Archived from the original (PDF) on 4 February 2007. Retrieved 23 July 2021.
- McBride DK (1997). "Protecting Honeybees From Pesticides". North Dakota State University. Retrieved 23 July 2021.
- Sanford MT (1993). "Protecting Honey Bees From Pesticides". University of Florida.[dead link]
- Krupke CH, Hunt G, Foster RE (2021). "Protecting honey bees from pesticides" (PDF). University of Purdue. Retrieved 23 July 2021.
- Ellis MD, Baxendale FP, Keith DL (1998). "Protecting Bees When Using Insecticides". University of Nebraska Lincoln, Extension. Archived from the original on 8 February 2005. Retrieved 23 July 2021.
- US EPA Pesticide Registration (PR) Notice 2001-5[dead link]
- Bee Health: Background and Issues for Congress Congressional Research Service
- Bee Health: The Role of Pesticides Congressional Research Service
- "The Xerces Society for Invertebrate Conservation". Retrieved July 24, 2021.
- Bee ecology
- Beekeeping
- Environmental effects of pesticides