The vector Aedes aegypti is now present in nearly every tropical and sub-tropical
region in the world and poses a threat to health globally. The mosquito can transmit
several viruses that cause diseases, such as dengue fever, chikungunya, yellow fever
and Zika virus infection. Recent outbreaks of Ae. aegypti-borne diseases have shown
that urban areas are particularly vulnerable because the built environment provides
ideal conditions for mosquito proliferation and contact with humans. Unless the global
public health community takes a coordinated, pre-emptive approach to controlling the
Ae. aegypti population, these outbreaks will become more common and widespread as
urban populations expand and movement of people and their goods increase. Improving
the built environment would contribute to a long-term solution to reducing the threat
of Ae. aegypti-borne diseases.
Our ability to deal with Ae. aegypti-borne viral epidemics is limited. Apart from
supportive care, specific treatments for vector-borne viral diseases are lacking.
No commercial vaccines for Zika or chikungunya are available, the only licensed dengue
vaccine is partially protective
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and globally the yellow fever vaccine is in short supply.
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Although current vector control programmes are often poorly resourced and under-used,
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historically, vector control was the main method for controlling mosquito-borne diseases.
By using container inspections, oiling of breeding sites and later perifocal spraying
of DDT (dichlorodiphenyltrichloroethane) in water containers and on nearby walls,
Ae. aegypti, yellow fever and dengue fever were successfully eliminated from much
of South America in the 1960s.
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In the 1970s and 1980s in Singapore and in the 1980s and 1990s in Cuba, controlling
adult and larval Ae. aegypti reduced dengue transmission. In the future, new methods
of vector control, such as novel delivery systems for insecticides with new modes
of action and release of Wolbachia-infected or genetically-modified mosquitoes, may
contribute to the control or elimination of mosquito-borne diseases.
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Affected towns and cities, however, already have several options to reduce Ae. aegypti-borne
diseases and these options should be built into future planning strategies.
Current Ae. aegypti control focuses on reducing densities of immature and adult mosquitoes
with larvicides or adult insecticides. While these interventions can be effective,
continued reliance on these single-intervention control programmes is resource-intensive
and threatened by insecticide resistance. The World Health Organization
3
,
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and other major international organizations
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have recommended an intersectoral approach to achieve more effective and sustainable
vector control. Governments, however, have often overlooked such approaches when designing
vector control programmes.
An underutilized aspect of integrated vector management is improving the urban built
environment to reduce Ae. aegypti populations and their contact with humans.
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The built environment in many urban areas provides abundant habitats for the immature
stages of Ae. aegypti, and high human population densities create the potential for
large outbreaks of Aedes-borne diseases. More than half of the world’s population
currently lives in urban areas and by 2050 it is estimated that 70% of the population
will live in cities.
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This urban expansion will increase the frequency and intensity of Aedes-borne outbreaks.
However, developing urban areas that minimize human contact with mosquitoes could
enable sustainable and cost–effective prevention of mosquito-borne diseases.
Several aspects of urban planning can be targeted to reduce human contact with Ae.
aegypti. Reducing the availability of small plastic containers around homes and improving
solid waste management will remove habitats for Ae. aegypti larvae development. Provision
of constant piped water will reduce the need to store water in containers in and around
homes, since water-filled containers are known to be favoured habitats for Ae. aegypti.
Houses can be designed to prevent adult mosquitoes from entering, either by sealed
or screened openings. Urban planning to reduce vector proliferation and human contact
can only be successful if it is combined with community engagement, so that communities
understand the diseases transmitted by these vectors and contribute to control efforts.
Reducing vector densities would not only reduce the chance of future epidemics occurring,
but also reduce the biting nuisance by other urban pest mosquitoes. Furthermore, most
improvements that reduce human contact with mosquitoes will have a range of other
social and health benefits by improving the domestic environment, such as easy access
to potable water and more sanitary living conditions. Delivering these urban improvements
should not only be seen as gains for urban development, but also as a supplementary
vector-control intervention to those interventions delivered through the health sector,
such as space spraying or larviciding.
We argue that urban improvements that reduce the mosquito population should be a component
of future Ae. aegypti-borne disease prevention strategies, and be seen as an important
component of sustainable development. This approach is closely aligned with the sustainable
development goals (SDGs), particularly SDG 11 and 17. SDG 11 demands action to “make
cities and human settlements inclusive, safe, resilient and sustainable” through improvements
to housing and basic services. SDG 17 calls for “sustainable development through global
partnerships” and building out Ae. aegypti will require close collaboration between
governments, the private sector and civil society.
A policy framework exists through which these changes can be implemented. The New
urban agenda, which is a product of the SDGs, was adopted by the United Nations (UN)
conference on housing and sustainable development (Habitat III) in Quito, Ecuador
in 2016 and subsequently endorsed by the UN General Assembly.
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The agenda is an attempt to readdress the way in which towns and cities are planned,
designed, financed, developed, governed and managed to make them more resilient and
sustainable. Specifically, the agenda recognizes that urban centres, particularly
in developing countries, are vulnerable to environmental risks including those from
vector-borne diseases and therefore promotes disaster risk reduction and management.
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To build settlements that are resilient against Ae. aegypti-borne diseases, vector
control experts should reach out and work with those who plan and design the built
environment. By creating a safe, reliable and protective water supply system, removing
domestic waste and sealing or screening homes, we can hinder immature mosquito development
and reduce biting densities of mosquitoes. Creating environments unfavourable for
Ae. aegypti must be a priority when building safe, resilient and sustainable towns
and cities.