"ඩී.ඩී.ටී" හි සංශෝධන අතර වෙනස්කම්

|MolarMass=354.49 g/mol

|Density=0.99 g/cm³<ref name="ATSDRc5"/>

|BoilingPt=decomp.<ref name="ATSDRc5"/>}}

|Section7={{Chembox Hazards

{{cite journal |author=Stokstad E |title=Species conservation. Can the bald eagle still soar after it is delisted? |journal=Science |volume=316 |issue=5832 |pages=1689–90 |year=2007 |month=June |pmid=17588911 |doi=10.1126/science.316.5832.1689 |url=http://www.sciencemag.org/cgi/content/summary/316/5832/1689}}</ref>

 

 

 

[http://www.deq.state.or.us/lq/ECSI/ecsidetail.asp?seqnbr=398 Environmental Cleanup Site Information Database for Arkema (former Pennwalt) facility], Oregon DEQ, April 2009.</ref> and [[Velsicol Chemical Corporation]],<ref>{{

cite news |url=http://www.themorningsun.com/stories/012708/loc_tests.shtml| title=Tests shed light on how pCBSA got into St. Louis water|last=Rosemary|first=Rosemary|date=2008-01-27|publisher=Morning Sun|accessdate=2008-05-16}}</ref> production peaked in 1963 at 82,000 tonnes per year.<ref name=EHC9/> More than 600,000 tonnes (1.35 billion lbs) were applied in the U.S. before the 1972 ban. Usage peaked in 1959 at about 36,000 tonnes.<ref name=EPA1975>

cite web|url=http://www.pops.int/documents/ddt/Global%20status%20of%20DDT%20SSC%2020Oct08.pdf|title=Global status of DDT and its alternatives for use in vector control to prevent disease|last=van den Berg|first=Henk|coauthors=Secretariat of the [[Stockholm Convention]]|date=October 23, 2008|publisher=[[Stockholm Convention]]/[[United Nations Environment Programme]]|accessdate=2008-11-22}}</ref>

 

cite journal |author=Denholm I, Devine GJ, Williamson MS |title=Evolutionary genetics. Insecticide resistance on the move |journal=Science |volume=297 |issue=5590 |pages=2222–3 |year=2002 |pmid=12351778 |doi=10.1126/science.1077266}}</ref>

 

In humans, however, it may affect health through [[genotoxicity]] or [[Endocrine disruptor|endocrine disruption]]. ''See [[#Effects_on_human_health|Effects on human health]]''.

 

First synthesized in 1874 by [[Othmar Zeidler]],<ref name=EHC9/> DDT's insecticidal properties were not discovered until 1939 by the [[Swiss (people)|Swiss]] scientist [[Paul Hermann Müller]], who was awarded the 1948 [[Nobel Prize]] in Physiology and Medicine for his efforts.<ref name=nobel/>

 

cite book|last=Dunlap|first=Thomas R.|title=DDT: Scientists, Citizens, and Public Policy|publisher=Princeton University Press|location=New Jersey|year=1981|isbn=0-691-04680-8}}</ref> In 1945, it was made available to farmers as an agricultural insecticide,<ref name=EHC9/> and it played a minor role in the final elimination of malaria in Europe and [[North America]].<ref name="Larson"/> By the time DDT was introduced in the U.S., the disease had already been brought under control by a variety of other means.<ref name="OreskesErik M. Conway2010">{{

cite book|last1=Oreskes|first1=Naomi|authorlink1=Naomi Oreskes|last2=Erik M. Conway|first2=Erik M|title=[[Merchants of Doubt]]: How a Handful of Scientists Obscured the Truth on Issues from Tobacco Smoke to Global Warming|edition=First|year=2010|publisher=Bloomsbury Press|location=San Francisco, CA|isbn=1-59691-610-9}}</ref> One [[Centers for Disease Control|CDC]] physician involved in the United States' DDT spraying campaign said of the effort that "we kicked a dying dog."<ref>

Cite journal |last = Sadasivaiah |first = Shobha |last2 = Tozan |first2 = Yesim |last3 = Breman |first3 = Joel G. |title = Dichlorodiphenyltrichloroethane (DDT) for Indoor Residual Spraying in Africa: How Can It Be Used for Malaria Control? |journal = Am. J. Trop. Med. Hyg. |volume = 77 |issue = Suppl 6 |pages =249–263 |date=1 December 2007|url = http://www.ajtmh.org/cgi/content/full/77/6_Suppl/249 }}</ref>

 

cite journal |author=Rogan WJ, Chen A |title=Health risks and benefits of bis(4-chlorophenyl)-1,1,1-trichloroethane (DDT) |journal=Lancet |volume=366 |issue=9487 |pages=763–73 |year=2005 |pmid=16125595 |doi=10.1016/S0140-6736(05)67182-6}}</ref>

 

As early as the 1940s, scientists in the U.S. had begun expressing concern over possible hazards associated with DDT, and in the 1950s the government began tightening some of the regulations governing its use.<ref name=EPA1975/> However, these early events received little attention, and it was not until 1957, when the ''[[New York Times]]'' reported an unsuccessful struggle to restrict DDT use in [[Nassau County, New York]], that the issue came to the attention of the popular naturalist-author, [[Rachel Carson]]. [[William Shawn]], editor of ''[[The New Yorker]]'', urged her to write a piece on the subject, which developed into her famous book ''[[Silent Spring]]'', published in 1962. The book argued that [[pesticide]]s, including DDT, were poisoning both wildlife and the environment and were also endangering human health.<ref name="Lear">Lear, Linda (1997). ''Rachel Carson: Witness for Nature.'' New York: Henry Hoyten.</ref>

 

Some uses of DDT continued under the public health exemption. For example, in June 1979, the California Department of Health Services was permitted to use DDT to suppress flea vectors of [[bubonic plague]].<ref name="urlAEI - Short Publications - The Rise, Fall, Rise, and Imminent Fall of DDT">{{cite web |url=http://www.aei.org/outlook/27063 |title=AEI - Short Publications - The Rise, Fall, Rise, and Imminent Fall of DDT }}</ref> DDT also continued to be produced in the US for foreign markets until as late as 1985, when over 300 tonnes were exported.<ref name="ATSDRc5"/>

 

In the 1970s and 1980s, agricultural use was banned in most developed countries, beginning with [[Hungary]] in 1968<ref>{{

cite web|url=http://www.fvm.hu/main.php?folderID=1564&articleID=6169&ctag=articlelist&iid=1&part=2| title=Selected passages from the history of the Hungarian plant protection administration on the 50th anniversary of establishing the county plant protection stations

cite journal | url=http://www.cdc.gov/ncidod/eid/vol3no3/roberts.htm | first=Donald R.| last=Roberts | title=DDT, global strategies, and a malaria control crisis in South America | journal=Emerging Infectious Diseases | month=July-September | year=1997 | pages=295–302 | volume=3 | issue=3 | pmid=9284373 | doi=10.3201/eid0303.970305 | last2=Laughlin | first2=LL | last3=Hsheih | first3=P | last4=Legters | first4=LJ | pmc=2627649}}</ref>

 

DDT is a [[persistent organic pollutant]] that is extremely [[hydrophobic]] and strongly absorbed by [[soil]]. Depending on conditions, its soil [[half life]] can range from 22 days to 30 years. Routes of loss and degradation include runoff, volatilization, [[photolysis]] and [[aerobic]] and [[anaerobic]] [[biodegradation]]. When applied to [[aquatic ecosystem]]s it is quickly absorbed by organisms and by soil or it evaporates, leaving little DDT dissolved in the water itself. Its breakdown products and metabolites, DDE and DDD, are also highly persistent and have similar chemical and physical properties.<ref name="ATSDRc5"/> DDT and its breakdown products are transported from warmer regions of the world to the [[Arctic]] by the phenomenon of [[global distillation]], where they then accumulate in the region's [[food web]].<ref>{{

cite journal|title=The Grasshopper Effect and Tracking Hazardous Air Pollutants|journal=The Science and the Environment Bulletin|publisher=Environment Canada|issue=May/June 1998|url=http://www.ec.gc.ca/science/sandemay/PrintVersion/print2_e.html|format={{Dead link|date=November 2009}}}}</ref>

cite journal|last=D Kantachote, R Naidu, B Williams, N McClure, M Megharaj, I Singleton |date=2004|title=Bioremediation of DDT-contaminated soil: enhancement by seaweed addition|journal=Journal of Chemical Technology & Biotechnology|volume=79|issue=6|pages=632–8|url=http://www3.interscience.wiley.com/journal/108060819/abstract|accessdate=2009-05-26}}</ref>

 

DDT is toxic to a wide range of animals in addition to insects, including marine animals such as [[crayfish]], [[daphnia|daphnids]], [[shrimp|sea shrimp]] and many species of [[fish]]. It is less toxic to mammals, but may be moderately toxic to some [[amphibian]] species, especially in the [[larvae|larval]] stage. Most famously, it is a reproductive toxicant for certain birds species, and it is a major reason for the decline of the [[bald eagle]],<ref name="pmid17588911"/> [[brown pelican]]<ref>

"Endangered and Threatened Wildlife and Plants; 12-Month Petition Finding and Proposed Rule To Remove the Brown Pelican (Pelecanus occidentalis) From the Federal List of Endangered and Threatened Wildlife; Proposed Rule," Fish and Wildlife Service, U.S. Department of the Interior, February 20, 2008. {{USFR|73|9407}}</ref> [[peregrine falcon]], and [[osprey]].<ref name="ATSDRc5"/> [[Birds of prey]], [[waterfowl]], and [[passerine|song birds]] are more susceptible to [[eggshell]] thinning than [[chicken]]s and [[Galliformes|related species]], and DDE appears to be more potent than DDT.<ref name="ATSDRc5"/>

cite web|last=Guillette| first=Louis J., Jr.|year=2006| url= http://www.ehponline.org/members/2005/8045/8045.pdf |format=PDF| title= Endocrine Disrupting Contaminants |accessdate=2007-02-02}}</ref><ref name="Lundholm, 1997">{{

cite journal| last=Lundholm| first=C.E.| year=1997| title= DDE-Induced eggshell thinning in birds| journal=Comp Biochem Physiol C Pharmacol Toxicol Endocrinol| issue=118| doi= 10.1016/S0742-8413(97)00105-9| volume= 118| pages= 113}}</ref> There is also evidence that o,p'-DDT disrupts female reproductive tract development, impairing eggshell quality later.<ref name="pmid17022422">{{

[http://www.fws.gov/contaminants/examples/AlaskaPeregrine.cfm Division of Environmental Quality]</ref>

 

Potential mechanisms of action on humans are genotoxicity and endocrine disruption. DDT may be directly [[genotoxicity|genotoxic]],<ref name=Cohn07>{{

cite journal |coauthors=Cohn BA, Wolff MS, Cirillo PM, Sholtz RI |title=DDT and breast cancer in young women: new data on the significance of age at exposure |journal=Environ. Health Perspect. |volume=115 |issue=10 |pages=1406–14 |year=2007 |month=October |pmid=17938728 |pmc=2022666 |doi=10.1289/ehp.10260 |last1=Cohn |first1=BA }}</ref> but may also induce [[enzyme]]s to produce other genotoxic intermediates and [[DNA adduct]]s.<ref name=Cohn07/> It is an endocrine disruptor; The DDT metabolite [[Dichlorodiphenyldichloroethylene|DDE]] acts as an [[antiandrogen]] (but not as an [[estrogen]]). p,p'-DDT, DDT's main component, has little or no androgenic or estrogenic activity.<ref name=Cohn07/> Minor component o,p'-DDT has weak estrogenic activity.

 

DDT is classified as "moderately toxic" by the United States [[National Toxicology Program]] (NTP)<ref>[http://pesticideinfo.org/Detail_Chemical.jsp?Rec_Id=PC33482 Pesticideinfo.org]</ref> and "moderately hazardous" by the [[World Health Organization]] (WHO), based on the rat oral [[LD50|{{chem|LD|50}}]] of 113&nbsp;mg/kg.<ref name = "zvgfrt">

World Health Organization, [http://www.who.int/ipcs/publications/pesticides_hazard_rev_3.pdf ''The WHO Recommended Classification of Pesticides by Hazard''], 2005.</ref> DDT has on rare occasions been administered orally as a treatment for [[barbiturate]] poisoning.<ref>{{

cite journal| journal=Clin Toxicol| year=1973| volume=6| issue=2| pages=147–51| title=Use of oral DDT in three human barbiturate intoxications: hepatic enzyme induction by reciprocal detoxicants| last=Rappolt| first=RT| pmid=4715198| doi=10.3109/15563657308990512}}</ref><!-- not about toxicity-->

 

[[Organochlorine]] compounds, generally, and DDT and DDE, specifically, have been linked to [[diabetes]]. A number of studies from the US, Canada, and Sweden have found that the prevalence of the disease in a population increases with serum DDT or DDE levels.<ref>{{Cite journal |last = Jones |first = Oliver AH |last2 = Maguire |first2 = Mahon L |last3 = Griffin |first3 = Julian L |title = Environmental pollution and diabetes: a neglected association |journal = Lancet |volume = 371 |pages = 287–8 |date = January 26, 2008 |url = http://www.sciencedirect.com/science?_ob=MImg&_imagekey=B6T1B-4RNK38J-B-1&_cdi=4886&_user=4420&_orig=browse&_coverDate=02%2F01%2F2008&_sk=996280390&view=c&wchp=dGLbVtb-zSkzS&md5=49ceb153cf41f91572ac41664bcf057e&ie=/sdarticle.pdf |format=PDF| doi = 10.1016/S0140-6736(08)60147-6 |pmid = 18294985 |issue = 9609 }}</ref><ref>{{cite journal|last=Turyk|first=Mary|date=March 6, 2009|title=Organochlorine Exposure and Incidence of Diabetes in a Cohort of Great Lakes Sport Fish Consumers|journal=Environ. Health Perspect. |url=http://www.ehponline.org/docs/2009/0800281/abstract.html}}</ref><ref>{{Cite journal |last = Codru |first = Neculai |last2 =Schymura| first2 = MJ | title = Diabetes in Relation to Serum Levels of Polychlorinated Biphenyls and Chlorinated Pesticides in Adult Native Americans |journal =Environ. Health Perspect. | volume = 115 |issue = 10| pages =1442–7 |year = 2007 |url = http://www.ehponline.org/members/2007/10315/10315.pdf|format=PDF |pmid = 17938733 |last3 = Negoita |first3 = S |author4 = Akwesasne Task Force on Environment |last5 = Rej |first5 = R |last6 = Carpenter |first6 = DO |doi = 10.1289/ehp.10315 |pmc = 2022671}}</ref><ref>{{Cite journal |last = Cox |first = Shanna |title = Prevalence of Self-Reported Diabetes and Exposure to Organochlorine Pesticides among Mexican Americans: Hispanic Health and Nutrition Examination Survey, 1982–1984 |journal = Environ. Health Perspect | volume = 115 |issue = 12| pages = 1747–52 |year = 2007 |url = http://www.ehponline.org/members/2007/10258/10258.pdf|format=PDF |pmid = 18087594 |last3 = Narayan |first3 = KM |last4 = Marcus |first4 = M |doi = 10.1289/ehp.10258 |pmc = 2137130 |last2 = Niskar |first2 = AS}}</ref><ref name="pmid19654916">{{cite journal |author=Turyk M, Anderson H, Knobeloch L, Imm P, Persky V |title=Organochlorine exposure and incidence of diabetes in a cohort of Great Lakes sport fish consumers |journal=Environ. Health Perspect. |volume=117 |issue=7 |pages=1076–82 |year=2009 |month=July |pmid=19654916 |doi=10.1289/ehp.0800281 |pmc=2717133}}</ref><ref>{{cite journal|last=Philibert|first=Aline|coauthors=Harold Schwartz and Donna Mergler|date=11 December 2009|title=An Exploratory Study of Diabetes in a First Nation Community with Respect to Serum Concentrations of p,p’-DDE and PCBs and Fish Consumption|journal=Int. J. Environ. Res. Public Health|volume=6|issue=12|pages=3179–89|url=http://www.mdpi.com/1660-4601/6/12/3179|doi=10.3390/ijerph6123179|pmid=20049255|pmc=2800343}}</ref>

 

 

 

cite journal |author=Rogan WJ, Ragan NB |title=Evidence of effects of environmental chemicals on the endocrine system in children |journal=Pediatrics |volume=112 |issue=1 Pt 2 |pages=247–52 |year=2003 |pmid=12837917 |url=http://pediatrics.aappublications.org/cgi/pmidlookup?view=long&pmid=12837917 |doi=10.1542/peds.112.1.S1.247 |doi_brokendate=2009-11-27}}</ref> Some 21st century researchers argue that these effects may increase infant deaths, offsetting any anti-malarial benefits.<ref>{{

cite journal |author=Roberts D, Curtis C, Tren R, Sharp B, Shiff C, Bate R |title=Malaria control and public health |journal=Emerging Infect. Dis. |volume=10 |issue=6 |pages=1170–1; author reply 1171–2 |year=2004 |pmid=15224677 |url=http://www.cdc.gov/ncidod/eid/vol10no6/03-0787_03-1116.htm}}<!-- Includes author reply --></ref>

A 2008 study, however, failed to confirm the association between exposure and difficulty breastfeeding.<ref>{{

cite journal |last = Cupul-Uicab |first = LA |title = DDE, a Degradation Product of DDT, and Duration of Lactation in a Highly Exposed Area of Mexico |journal = Environ. Health Perspect. |volume = 116 |issue = 2 |pages = 179–183 |year = 2008 |url = http://www.ehponline.org/docs/2007/10550/abstract.html |doi = 10.1289/ehp.10550 |pmid = 18288315 |last2 = Gladen |first2 = BC |last3 = Hernández-Avila |first3 = M |last4 = Weber |first4 = JP |last5 = Longnecker |first5 = MP |pmc = 2235222}}</ref>

 

cite web| url=http://news.bbc.co.uk/2/hi/health/5145450.stm|title=DDT 'link' to slow child progress| author=BBC| accessdate=2006-07-05 | date=2006-07-05}}</ref> and other studies have found that even low levels of DDT or DDE in [[umbilical cord]] serum at birth are associated with decreased attention at infancy<ref>{{

cite journal |author=Sagiv SK, Nugent JK, Brazelton TB, ''et al.'' |title=Prenatal organochlorine exposure and measures of behavior in infancy using the Neonatal Behavioral Assessment Scale (NBAS) |journal=Environ. Health Perspect. |volume=116 |issue=5 |pages=666–73 |year=2008 |month=May |pmid=18470320 |pmc=2367684 |doi=10.1289/ehp.10553 |url=http://www.ehponline.org/docs/2008/10553/abstract.html}}</ref> and decreased cognitive skills at 4 years of age.<ref>{{

cite journal |author=Torres-Sánchez L, Rothenberg SJ, Schnaas L |title=In utero p, p'-DDE exposure and infant neurodevelopment: a perinatal cohort in Mexico |journal=Environ. Health Perspect. |volume=115 |issue=3 |pages=435–9 |year=2007 |pmid=17431495 |doi=10.1289/ehp.9566 |pmc=1849908}}</ref>

 

cite journal |author=Jurewicz J, Hanke W, Radwan M, Bonde JP |title=Environmental factors and semen quality |journal=Int J Occup Med Environ Health |volume= 22|issue= 4|pages=1–25 |year=2010 |month=January |pmid=20053623 |doi=10.2478/v10001-009-0036-1 |url=}}</ref><ref>{{

cite journal |author=Aneck-Hahn NH, Schulenburg GW, Bornman MS, Farias P, de Jager C |title=Impaired semen quality associated with environmental DDT exposure in young men living in a malaria area in the Limpopo Province, South Africa |journal=J. Androl. |volume=28 |issue=3 |pages=423–34 |year=2007 |pmid=17192596 |doi=10.2164/jandrol.106.001701}}</ref><ref>{{

cite journal |author=De Jager C, Farias P, Barraza-Villarreal A |title=Reduced seminal parameters associated with environmental DDT exposure and p, p'-DDE concentrations in men in Chiapas, Mexico: a cross-sectional study |journal=J. Androl. |volume=27 |issue=1 |pages=16–27 |year=2006 |pmid=16400073 |doi=10.2164/jandrol.05121}}</ref>

 

 

cite journal |author=Venners SA, Korrick S, Xu X |title=Preconception serum DDT and pregnancy loss: a prospective study using a biomarker of pregnancy |journal=Am. J. Epidemiol. |volume=162 |issue=8 |pages=709–16 |year=2005 |pmid=16120699 |doi=10.1093/aje/kwi275}}</ref> The median serum DDE level of study group was lower than that typically observed in women living in homes sprayed with DDT.<ref>{{

cite journal |author=Longnecker MP |title=Invited Commentary: Why DDT matters now |journal=Am. J. Epidemiol. |volume=162 |issue=8 |pages=726–8 |year=2005 |pmid=16120697 |doi=10.1093/aje/kwi277}}</ref>

 

cite journal |author=Nagayama J, Kohno H, Kunisue T |title=Concentrations of organochlorine pollutants in mothers who gave birth to neonates with congenital hypothyroidism |journal=Chemosphere |volume=68 |issue=5 |pages=972–6 |year=2007 |pmid=17307219 |doi=10.1016/j.chemosphere.2007.01.010 |url=http://linkinghub.elsevier.com/retrieve/pii/S0045-6535(07)00040-9}}</ref> Other studies have also found the DDT or DDE interfere with proper thyroid function.<ref name="pmid17933884">{{

cite journal |author=Alvarez-Pedrerol M, Ribas-Fito N, Torrent M, Carrizo D, Grimalt JO, Sunyer J |title=Effects of PCBs, p, p'-DDT, p, p'-DDE, HCB and {beta}-HCH on thyroid function in preschoolers |journal=Occup Environ Med |year=2007 |month=October |pmid=17933884 |doi=10.1136/oem.2007.032763 }}</ref><ref name="pmid18560538">{{

cite journal |author=Schell LM, Gallo MV, Denham M, Ravenscroft J, Decaprio AP, Carpenter DO |title=Relationship of Thyroid Hormone Levels to Levels of Polychlorinated Biphenyls, Lead, p, p'- DDE, and Other Toxicants in Akwesasne Mohawk Youth |journal=Environ. Health Perspect. |volume=116 |issue=6 |pages=806–13 |year=2008 |month=June |pmid=18560538 |doi=10.1289/ehp.10490 |pmc=2430238}}</ref>

 

Occupational exposure in agriculture and malaria control has been linked to neurological problems (i.e. Parkinsons)<ref>{{

cite journal | author=van Wendel de Joode B, Wesseling C, Kromhout H, Monge P, Garcia M, Mergler D | title=Chronic nervous-system effects of long-term occupational exposure to DDT | journal=Lancet | year=2001 | pages=1014–6 | volume=357 | issue=9261 | pmid=11293598 | doi=10.1016/S0140-6736(00)04249-5}}</ref> and [[asthma]].<ref>

Anthony J Brown, [http://www.sciam.com/article.cfm?alias=pesticide-exposure-tied-t&chanId=sa003&modsrc=reuters Pesticide Exposure Linked to Asthma], Scientific American, September 17, 2007.</ref>

 

DDT is suspected to cause cancer. The NTP classifies it as "reasonably anticipated" the EPA classifies DDT, DDE, and DDD as class B2 "probables" and the [[International Agency for Research on Cancer]] classifies DDT as a "possible" human [[carcinogen]]. These evaluations are based mainly on the results of animal studies.<ref name="ATSDRc5"/><ref name="pmid16125595"/>

 

Epidemiological studies suggest that DDT/DDE '''does not''' cause [[multiple myeloma]],<ref name="pmid16125595"/> or cancers of the [[prostate cancer|prostate]],<ref name="pmid16125595"/> [[endometrial cancer|endometrium]],<ref name="pmid16125595"/><ref name="PineRiver"/> [[colorectal cancer|rectum]],<ref name="pmid16125595"/><ref name="PineRiver"/>[[lung cancer|lung]],<ref name="PineRiver"/> [[bladder cancer|bladder]],<ref name="PineRiver"/> or [[stomach cancer|stomach]].<ref name="PineRiver"/>

 

The question of whether DDT or DDE are [[risk factors of breast cancer]] has been repeatedly studied. While individual studies conflict, the most recent reviews of all the evidence conclude that pre-puberty exposure increases the risk of subsequent breast cancer.<ref name="PineRiver"/><ref name="pmid18557596">{{

cite journal |author=Clapp RW, Jacobs MM, Loechler EL |title=Environmental and occupational causes of cancer: new evidence 2005-2007 |journal=Rev Environ Health |volume=23 |issue=1 |pages=1–37 |year=2008 |pmid=18557596 |pmc=2791455 }}</ref> Until recently, almost all studies measured DDT or DDE blood levels at the time of breast cancer diagnosis or after. This study design has been criticized, since the levels at diagnosis do not necessarily correspond to levels when her cancer started.<ref name="pmid18629310">{{

cite journal |author=López-Cervantes M, Torres-Sánchez L, Tobías A, López-Carrillo L |title=Dichlorodiphenyldichloroethane burden and breast cancer risk: a meta-analysis of the epidemiologic evidence |journal=Environ. Health Perspect. |volume=112 |issue=2 |pages=207–14 |year=2004 |month=February |pmid=14754575 |pmc=1241830 |url=http://www.ehponline.org/members/2003/6492/6492.html}}</ref>

 

 

[[Malaria]] remains a major public health challenge in many countries. 2008 WHO estimates were 243 million cases, and 863,000 deaths. About 89% of these deaths occur in [[Africa]], and mostly to children under the age of 5.<ref name=wmr09>

2009 WHO [http://whqlibdoc.who.int/publications/2009/9789241563901_eng.pdf World Malaria Report 2009]</ref> DDT is one of many tools that public health officials use to fight the disease. Its use in this context has been called everything from a "miracle weapon [that is] like [[Kryptonite]] to the mosquitoes,"<ref name=salon/> to "toxic colonialism."<ref>{{

cite journal |author=Paull, John |title=Toxic Colonialism |journal=New Scientist |issue=2628 |pages=25 |date=3 November 2007 |url=http://www.newscientist.com/article/mg19626280.400-toxic-colonialism.html/}}</ref>

 

 

WHO's anti-malaria campaign of the 1950s and 1960s relied heavily on DDT and the results were promising, though temporary. Experts tie the resurgence of malaria to multiple factors, including poor leadership, management and funding of malaria control programs; poverty; civil unrest; and increased [[irrigation]]. The evolution of resistance to first-generation drugs (e.g. [[chloroquine]]) and to insecticides exacerbated the situation.<ref name="DDTBP.1/2"/><ref>{{

Once the mainstay of anti-malaria campaigns, as of 2008 only 12 countries used DDT, including India and some southern African states,<ref name=wmr09/> though the number is expected to rise.<ref name="DDTBP.1/2"/>

 

When it was first introduced in World War II, DDT was very effective in reducing malaria [[morbidity]] and [[mortality rate|mortality]].<ref name=Dunlap/> The WHO's anti-malaria campaign, which consisted mostly of spraying DDT, was initially very successful as well. For example, in [[Sri Lanka]], the program reduced cases from about 3 million per year before spraying to just 29 in 1964. Thereafter the program was halted to save money, and malaria rebounded to 600,000 cases in 1968 and the first quarter of 1969. The country resumed DDT vector control, but the mosquitoes had acquired resistance in the interim, presumably because of continued agricultural use. The program switched to [[malathion]], which though more expensive, proved effective.<ref name=Gordon>{{

cite book|last=Harrison|first=Gordon A|title=Mosquitoes, Malaria, and Man: A History of the Hostilities Since 1880|publisher=Dutton|year=1978|isbn=0525160256}}</ref>

South Africa is one country that continues to use DDT under WHO guidelines. In 1996, the country switched to alternative insecticides and malaria incidence increased dramatically. Returning to DDT and introducing new drugs brought malaria back under control.<ref>{{cite journal| title=Roll Back Malaria: a failing global health campaign| first=Gavin| last=Yamey| journal=BMJ| year=2004| volume=328| pages=1086–1087| month=8 May| doi=10.1136/bmj.328.7448.1086 | pmid=15130956| issue=7448| pmc=406307}}</ref> According to DDT advocate Donald Roberts, malaria cases increased in [[South America]] after countries in that continent stopped using DDT. Research data shows a significantly strong negative relationship between DDT residual house sprayings and malaria rates. In a research from 1993 to 1995, Ecuador increased its use of DDT and resulted in a 61% reduction in malaria rates, while each of the other countries that gradually decreased its DDT use had large increase in malaria rates.<ref name="Roberts 1997"/>

 

Resistance has greatly reduced DDT's effectiveness. WHO guidelines require that absence of resistance must be confirmed before using the chemical.<ref name="IRS-WHO">

[http://whqlibdoc.who.int/hq/2006/WHO_HTM_MAL_2006.1112_eng.pdf Indoor Residual Spraying: Use of Indoor Residual Spraying for Scaling Up Global Malaria Control and Elimination.] World Health Organization, 2006.</ref> Resistance is largely due to agricultural use, in much greater quantities than required for disease prevention. According to one study that attempted to quantify the lives saved by banning agricultural use and thereby slowing the spread of resistance, "it can be estimated that at current rates each kilo of insecticide added to the environment will generate 105 new cases of malaria."<ref name="pmid7278974"/>

cite journal |author=Hargreaves K, Hunt RH, Brooke BD |title=Anopheles arabiensis and An. quadriannulatus resistance to DDT in South Africa |journal=Med. Vet. Entomol. |volume=17 |issue=4 |pages=417–22 |year=2003 |pmid=14651656 |doi=10.1111/j.1365-2915.2003.00460.x}}</ref>

 

cite journal|title=DDT: The fallen angel| first=V. P.| last=Sharma| journal=Current Science| volume=85| pages=1532–1537| issue=11| month=10 December| year=2003| url=http://www.ias.ac.in/currsci/dec102003/1532.pdf|format=PDF}}</ref>

 

{{Main|Indoor residual spraying#Residents's opposition to IRS}}

 

cite journal |author=Mabaso ML, Sharp B, Lengeler C |title=Historical review of malarial control in southern African with emphasis on the use of indoor residual house-spraying |journal=Trop. Med. Int. Health |volume=9 |issue=8 |pages=846–56 |year=2004 |pmid=15303988 |doi=10.1111/j.1365-3156.2004.01263.x}}</ref><ref name = "Thurow">

[http://www.mindfully.org/Health/Malaria-New-Strain.htm In Malaria War, South Africa Turns To Pesticide Long Banned in the West], Roger Thurow, [[Wall Street Journal]], July 26, 2001</ref> [[Pyrethroid]] insecticides (e.g. [[deltamethrin]] and [[lambda-cyhalothrin]]) can overcome some of these issues, increasing participation.<ref name = "Curtis"/>

 

People living in areas where DDT is used for IRS have high levels of the chemical and its breakdown products in their bodies. Compared to contemporaries living where DDT is not used, [[South Africa]]ns living in sprayed homes have levels that are several orders of magnitude greater.<ref name="PineRiver"/> [[Breast milk]] in regions where DDT is used against malaria greatly exceeds the allowable standards for breast-feeding infants.<ref name="Bouwman H, Sereda B, Meinhardt HM 2006 902–17">{{

cite journal |author=Bouwman H, Sereda B, Meinhardt HM |title=Simultaneous presence of DDT and pyrethroid residues in human breast milk from a malaria endemic area in South Africa |journal=Environ. Pollut. |volume=144 |issue=3 |pages=902–17 |year=2006 |pmid=16564119 |doi=10.1016/j.envpol.2006.02.002}}</ref><ref name=Ntow>{{

cite news|url=http://www.indianexpress.com/news/State-public-libraries-gasp-for-breath/472785|title=State public libraries gasp for breath|last=Chakravartty|first=Anupam|date=June 8, 2009|publisher=Indian Express|accessdate=2009-06-08}}</ref> Other example include Ethiopia, where DDT intended for malaria control is reportedly being used in coffee production,<ref>{{

cite journal|last=Katima|first=Jamidu|date=June 2009|title=African NGOs outline commitment to malaria control without DDT|journal=Pesticides News|issue=84|pages=5}}</ref> and Ghana where it is used for fishing."<ref>{{

 

Critics claim that restricting DDT in vector control have caused unnecessary deaths due to malaria. Estimates range from hundreds of thousands,<ref>{{

cite news| url=http://query.nytimes.com/gst/abstract.html?res=F40B1EFB3F580C718DDDAA0894DD404482&n=Top%252fOpinion%252fEditorials%2520and%2520Op%252dEd%252fOp%252dEd%252fColumnists%252fNicholas%2520D%2520Kristof| publisher= New York Times| month=March 12| year=2005| title=I Have a Nightmare| first=Nicholas D.| last=Kristof| pages=Section A, Page 15 , Column 1| nopp=true}}</ref> to much higher figures. Robert Gwadz of the [[National Institutes of Health]] said in 2007, "The ban on DDT may have killed 20 million children."<ref>

cite web|url=http://www.usaid.gov/our_work/global_health/id/malaria/techareas/irs.html|title=USAID Health: Infectious Diseases, Malaria, Technical Areas, Prevention and Control, Indoor Residual Spraying|publisher=USAID|accessdate=2008-10-14}}</ref> in the past it did not. When [[John Stossel]] accused USAID of not funding DDT because it wasn't "politically correct," Anne Peterson, the agency's assistant administrator for global health, replied that "I believe that the strategies we are using are as effective as spraying with DDT ... So, politically correct or not, I am very confident that what we are doing is the right strategy."<ref>{{

cite news|url=http://abcnews.go.com/2020/Stossel/story?id=1898820|title=Excerpt: 'Myths, Lies, and Downright Stupidity'|last=Stossel|first=John|date=November 16, 2007|publisher=ABC News|accessdate=2008-10-14}}</ref> USAID's Kent R. Hill states that the agency has been misrepresented: "USAID strongly supports spraying as a preventative measure for malaria and will support the use of DDT when it is scientifically sound and warranted."<ref>{{

cite web| url=http://www.usaid.gov/our_work/global_health/id/malaria/news/afrmal_ddt.html| title=USAID Health: Infectious Diseases, Malaria, News, Africa Malaria Day, USAID Support for Malaria Control in Countries Using DDT| accessdate=2006-03-15| year=2005}}</ref>

 

{{Main|Indoor residual spraying}}

Advocates of increased use of DDT in IRS claim that alternative insecticides are more expensive, more toxic, or not as effective. As discussed above, susceptibility of mosquitoes to DDT varies geographically. The same is true for alternative insecticides, so its relative effectiveness varies. Toxicity and cost-effectiveness comparisons lack data. Relative insecticide costs vary by location and ease of access, the habits of the local mosquitoes, the degrees of resistance exhibited by the mosquitoes, and the habits and compliance of the population, among other factors. The choice of insecticide has little impact on the total cost of a round of spraying, since product costs are only a fraction of campaign costs. IRS coverage needs to be maintained throughout the malaria season, making DDT's relatively long life an important cost savings.

[[Organophosphate]] and [[carbamate]] insecticides, ''e.g.'' [[malathion]] and [[bendiocarb]], respectively, are more expensive than DDT per kilogram and are applied at roughly the same dosage. [[Pyrethroid]]s such as [[deltamethrin]] are also more expensive than DDT, but are applied more sparingly (0.02-0.3 g/m² vs 1-2 g/m²), so the net cost per house is about the same over 6 months.<ref name="AmJTrop"/>

 

Before DDT, malaria was successfully eradicated or curtailed in several tropical areas by removing or poisoning mosquito breeding grounds and larva habitats, for example by filling or applying oil to standing water. These methods have seen little application in Africa for more than half a century.<ref>{{

cite journal |author=Killeen GF, Fillinger U, Kiche I, Gouagna LC, Knols BG |title=Eradication of Anopheles gambiae from Brazil: lessons for malaria control in Africa? |journal=Lancet Infect Dis |volume=2 |issue=10 |pages=618–27 |year=2002 |pmid=12383612 |doi=10.1016/S1473-3099(02)00397-3}}</ref>

The relative effectiveness of IRS (with DDT or alternative insecticides) versus other malaria control techniques (e.g. bednets or prompt access to anti-malarial drugs) varies greatly and is highly dependent on local conditions.<ref name="AmJTrop"/>

 

[http://www.who.int/malaria/docs/ReportGFImpactMalaria.pdf Impact of long-lasting insecticidal-treated nets (LLINs) and artemisinin-based combination therapies (ACTs) measured using surveillance data in four African countries.] World Health Organization, January 31, 2008.</ref><ref>

[http://www.sfgate.com/cgi-bin/article.cgi?f=/c/a/2008/02/01/MN4EUPS3D.DTL&type=health Malaria deaths halved in Rwanda and Ethiopia Better drugs, mosquito nets are the crucial tools], David Brown (Washington Post), ''SF Chronicle'', A-12, February 1, 2008.</ref>

While the increased numbers of malaria victims since DDT usage collapsed document its value, many other factors contributed to the rise in cases.

 

cite journal| title=The evidence base on the cost-effectiveness of malaria control measures in Africa| author=C. A. Goodman and A. J. Mills| journal=Health Policy and Planning| volume=14| issue=4| pages=301–312| year=1999| url=http://heapol.oxfordjournals.org/cgi/reprint/14/4/301.pdf |format=PDF| pmid=10787646 | doi = 10.1093/heapol/14.4.301}}</ref>

 

cite journal| title=Cost-effectiveness and sustainability of lambdacyhalothrin-treated mosquito nets in comparison to DDT spraying for malaria control in western Thailand| last=Kamolratanakul| first=P.| journal=American Journal of Tropical Medicine and Hygiene| year=2001| volume=65| issue=4| pages=279–84 | pmid=11693869 | doi = 10.1046/j.1365-3156.2001.00700.x| last2=Butraporn| first2=P| last3=Prasittisuk| first3=M| last4=Prasittisuk| first4=C| last5=Indaratna| first5=K| last6=Gumede| first6=J. K.}}</ref> at very least casting some doubt on the unexamined assumption that DDT was the most cost-effective measure to use in all cases. The director of Mexico's malaria control program finds similar results, declaring that it is 25% cheaper for Mexico to spray a house with synthetic pyrethroids than with DDT.<ref name="PMC1119118"/> However, another study in South Africa found generally lower costs for DDT spraying than for impregnated nets.<ref>{{

cite journal |author=Goodman CA, Mnzava AE, Dlamini SS, Sharp BL, Mthembu DJ, Gumede JK |title=Comparison of the cost and cost-effectiveness of insecticide-treated bednets and residual house-spraying in KwaZulu-Natal, South Africa |journal=Trop. Med. Int. Health |volume=6 |issue=4 |pages=280–95 |year=2001 |pmid=11348519 |doi=10.1046/j.1365-3156.2001.00700.x}}</ref>

DDT resistant mosquitoes have generally proved susceptible to pyrethroids. Thus far, pyrethroid resistance in ''Anopheles'' has not been a major problem.<ref name = "Curtis"/>

 

 

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{{Commons category|DDT}}

;Toxicity

 

 

;Politics and DDT

 

;Malaria and DDT

 

{{insecticides}}

 

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