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Revista Costarricense de Salud Pública
versão impressa ISSN 1409-1429
Rev. costarric. salud pública vol.22 no.1 San José Jan./Jun. 2013
Review
Chemical control of Aedes aegypti: a historical perspective
Control Químico de Aedes aegypti: Una Perspectiva Histórica
Alejandra Manjarres-Suarez1*, Jesus Olivero-Verbel2*
Abstract
Objective: To describe the use of chemical insecticides throughout history as the main tool to fight against Aedes aegypti, a vector of dengue virus.
Methods: A text mining approach was conducted on databases, such as PUBMED and SCIENCE DIRECT, using the keywords “Aedes aegypti”, combined with the words “insecticides”, “resistance”, “organochlorines”, “organophosphates”, “carbamates” and “pyrethroids”. Results related to historical information dealing with the chemical control of Aedes aegypti, in particular those containing data on insecticide resistance for this species, were scrutinized and analyzed.
Results: Different chemical groups have been utilized to control A. aegypti, including organochlorine, organophosphate, carbamate and pyrethroid insecticides. In general, the tendency has been to replace a particular pesticide, for which resistance had been detected, for a new one, mosquito-sensitive, and with little evidence of deleterious effects derived from its use. The spread of resistance has been registered in several countries of
Conclusion: Excessive use of chemical insecticides and the lack of dosing control have led to widespread resistance in A. aegypti, as no “safer” alternative chemical options are available for vector control in different countries, impacting human health
Keywords: Aedes, Vector control, Insecticide Resistance, Toxic Substances. (source: MeSH/NLM).
Resumen
Objetivo: Describir el uso de insecticidas químicos a través de la historia como la principal herramienta contra Aedes aegypti, un mosquito vector del virus del dengue.
Métodos: Una búsqueda en minería de textos fue realizada en bases de datos como PubMedy Science Direct, utilizando las palabras clave “Aedes aegypti”, en combinación con “insecticidas”, “resistencia”, “organoclorados”, “organofosforados”,“carbamatos” y “piretroides”.Resultados afines con la información histórica relacionada con el control químico del mosquito Aedes aegypti, en particular las que contienen datos sobre la resistencia a insecticidas de esta especie, fueron examinados y analizados.
Resultados: Diferentes grupos químicos han sido desarrollados para el control de A. aegypti, siendo los más utilizados organoclorados, organofosforados, carbamatos y piretroides. En general, la tendencia ha sido la de sustituir un pesticida particular, para el que ha sido detectado resistencia, por uno nuevo, mosquito-sensible, y con evidencia de efectos perjudiciales derivados de su uso. La propagación de la resistencia se ha registrado en varios países de América, Asia y África. Dos mecanismos han sido altamente referenciados de ser responsable de la resistencia, el aumento de actividad de las enzimas de desintoxicación, y los cambios estructurales en el sitio de destino de los insecticidas, en su mayoría dentro del sistema nervioso central.
Conclusión: El uso excesivo de insecticidas químicos y la falta de control de dosificación han dado lugar a una resistencia generalizada en Aedes aegypti, y alternativas químicas “más seguras” no están disponibles para el control de vectores en diferentes países, afectando la salud humana.
Palabras claves: Aedes, Control de vectores, Sustancias Tóxicas. (fuente:DeCS/BIREME).
Over the last 25 years there has been a global increase in both the distribution of A. aegypti and the epidemic dengue virus activity (5). It has been estimated that worldwide, 2.5 billion people are at risk of acquiring the disease, approximately 50–100 million cases of dengue fever are reported each year, 500,000 people with severe dengue require hospitalization, and around 2.5% of diseased people die (6). The expansion of the mosquito populations may be explained by many factors, including demographic explosion, global warming, and the traffic of people between the infested communities and those previously vector free (7).
The control of Aedes populations is performed using several strategies, such as environmental management, chemical, biological and integrated control. The first is the most effective, preventing or reducing the breeding of mosquitoes and human-vector pathogen contact. Environmental management is focused on the destruction, alteration, disposal or recycling of containers, and natural larval habitats, that produce the greatestnumber of adult Aedesmosquitoes in each community. These activities are concurrently developed with health education programs, utilizing communication strategies that encourage community participation in the planning, execution, and evaluation of container–management programs. Three types of environmental management programs have been defined: first, environmental modification based on long lasting physical transformations of vector habitats; second, environmental manipulations, aimed to generate temporary changes to vector habitat, as a result of planned activity to produce unfavorable conditions to vector breeding; and third, changes in human habitat or behavior (8). However, the most widely used control for Aedes populations, due to its effectiveness in regulating larval and adult populations, is the utilization of chemical insecticides (9).
There are three methods of applying chemical control. Larvicide application or focal control, used to treat household drinking water containers, has low, relative toxicity, and is safe for humans. Another method is perifocal treatment, which utilizes sprinklers in larval habitats and destroys not only larvae but also adult mosquitoes. Finally, space spraying is generally employed in emergency outbreaks of dengue (8).
It is important to emphasize that larvicides should be considered as a complementary method to environmental management and those are intended to impact the mosquito density and longevity, as well as other transmission parameters. Another strategy is biological control, which introduces predators or parasites to compete or reduce the populations of the target species. Larvivorous fish and the biocide Bacillus thuriengensis H -14 (BTI) are the two most frequently employed organisms. According to McCall and Kittayapong (10), the pyriproxyfen, and insect growth regulator, has also been used for the control of the dengue vector. This method has been documented to only be effective in the immature stages of the vector mosquitoes (11). Finally, integrated control is the combination of the available control methods in the most effective, economical, and safe manner to decrease vector populations (8).
As chemical insecticides have been the most important tools employed for the management of dengue vector mosquito, the objective of this review was to describe those pesticides that have been used throughout history in the control of Aedes aegypti.
Methods
This paper consists of a thematic review that was done searching in databases such as PUBMED, SCIENCE DIRECT, books, and webpages of public health organizations from several countries, including as well theWorldHealthOrganizationandPanamericanHealth Organization. Keywords as “chemical insecticides”, “Aedes aegypti”, “resistance”, “organochlorines”, “organophosphates”, “carbamates” and “pyrethroids”, were employed to carry out the search. Aspects such as the history of chemical insecticide use, resistance development, resistance mechanisms, and effects of pesticides on human health, constituted the inclusion criteria to consider citations in the review.
Results
Evolution of mosquito control with chemical insecticides
Initially, insect control was carried out with natural products, but the development of chemical insecticides slowed down basic research on this issue (12).
Throughout history, four common classes of chemical insecticides have been used to control A. aegypti: organochlorines, organophosphates, carbamates and pyrethroids (13). Organochlorine pesticides are lipophilic compounds with low vapor pressures and slow degradation rates (14). These are known for their toxicity, persistence in the environment, and bioaccumulation in the food chain. This last property was one of the main reasons why these were replaced by organo phosphate espesticides, as they could be more asily degraded in the environment (15). Organochlorine insecticides were widely used between 1940s and mid 1960s, when they were discontinued due to their environmental effects (14). Organophosphates (OPs) are pesticides of low persistence in the environment, which are hydrolysed to high or low pH (16). These were developed during World War II as nerve gases, and their insecticidal properties were discovered shortly thereafter (17). The OPs have become widely used as replacements for organochlorine insecticides because they do not bioaccumulate in organism tissues or the environment (14). Carbamates are derivatives of the carbamic acid. These chemicals share the same mode of action with OPs, inhibiting the activity of acetylcholinesterase, although this effect can be more easily reversed, and the insects may recover at low doses (18). These last two types of insecticides have a broad spectrum of activity, rapid environmental degradation (19), relatively short biological half-lives, and are rapidly metabolized and excreted (14). The fourth group comprises pyrethroids, the most recently introduced insecticides (20), entering the marketplace in 1980 (21). They are considered safe due to their high insecticidal properties at low application rates, short persistence in the environment, no bioaccumulation and low mammalian toxicity (22), reasons supporting their extensive use (23).
Although there is abundant information regarding the chronological development of insecticides by chemical group, as shown in Table
Reports of chemical insecticide use to control dengue virus vectors
During the last decades, the use of chemical insecticides has been an important component to control the populations of dengue vectors (9, 29).
Commercially available insecticides used in different countries are shown in Table 2. All these chemicals are not used simultaneously, but each country has employed specific insecticides throughout history, with peculiarities in both use and dosage form. A total of 40 countries from different continents recorded the use of insecticides for control of dengue during 20032005. The most widely used insecticides for vector control have been organophosphates and pyrethroids. In fact, a total of 262 tons of organophosphate (OP) insecticides and 39 tons of pyrethroids per year have been utilized (30).
Among OPs, in a global context, 76 % were utilized for space spraying, 23 % for larviciding, and 1 % for peri-focal spraying, interestingly, 90 % of the total was used in countries from the
Worldwide, the control of A. aegypti is mostly performed with Ops; being malathion the most frequently utilized, constituting 67 % of the average annual use, followed by temephos (22 %) (30).This last has been the leading pesticide used as larvicide in Malaysia (31), Port Suan City (Red Sea State) (32), Thailand (33), Panama, El Salvador, Cuba, Martinique Island, French Guiana, Peru, Brazil, Argentina, Venezuela and Colombia (22, 24, 27, 34-41).
The main dengue vector control with pyrethroids has been performed with cypermethrin (37 %) and permethrin (45 %), followed by alpha-cypermethrin (14 %) (30). Other insecticides have also been critical for the control of A. aegypti, including fenthion, fenitrothion, chlorpyrifos, deltamethrin, cyhalothrin, cyfluthrin, propoxur, bendiocarb, dichloro diphenyl trichloroethane (DDT) and dieldrin (22, 24, 27, 34-41). According to WHO, during
Resistance registered in Aedes aegypti
The continued use of insecticides has induced pressure on populations of A. aegypti, leading to widespread resistance (43). Two main mechanisms have been reported to be responsible (28): the first involves an increased activity of detoxifying enzymes, including esterases, mixed function oxidases (cytochrome P450s), and glutathione S-transferases (GSTs) (44); and the second deals with structural changes in the insecticide target site in the central nervous system (45).
The main insecticide targets are acetylcholinesterase, γ -aminobutyric acid (GABA) receptor and the voltage-gated sodium channel (46).
In LatinAmerica and the
In countries such as Puerto Rico, Dominican Republic, Cuba, French Guiana, and Colombia, among others, have been recorded the resistance development of Aedes aegypti to insecticides such as temephos (9, 37, 38, 47-50) and pyrethroids (13, 37, 44, 51, 54), showing with these, the evolution of resistance registered worldwide.
Because resistance records, as well as the registered effects in the health of humans, such as immunosuppression; endocrinedisruption; reproductive abnormalities; irritant respiratory symptons; adverse genotoxic and neurological effects; and cancer (5560), control of Aedes populations is being conducted through more environmentally friendly alternatives, such the use of plant extracts, reducing adverse effects on non-target organisms (61).
Conclusions
The vector control for A. aegypti has been one of the main strategies against dengue virus transmission, but it is mostly based on chemical in secticides, which induce resistance in mosquitoes and also cause damage to humans and the environment. This resistance is probably due to the lack of regulation in use and in the dosage of each case. This review supports the need to generate mosquito control strategies that are environmentally friendly with minimal affectations on human populations.
Acknowledgements
The authors acknowledge the financial support of the
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1 Biologist. Environmental and Computational Chemistry Group.
2 Pharmaceutical Chemist. Ph.D. Environmental and Computational Chemistry Group. Faculty of Pharmaceutical Sciences. Campus of Zaragocilla.