Dengue in Bangladesh: assessment of the influence of climate and under-reporting in national incidence
Date
2016
Authors
Sharmin, Sifat
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Abstract
Dengue occurs in many tropical countries, despite substantial
effort to control the Aedes
mosquitoes that transmit the virus. The majority of the burden
occurs in the South-East Asian
Region of the World Health Organization. Bangladesh is a
lower-middle income country
located in South Asia, with strong seasonal weather variation,
heavy monsoon rainfall, and
high population density. Dengue has been endemic in Bangladesh
since an epidemic in 2000.
The aim of my research was to investigate the influence of
climate on dengue transmission in
Bangladesh over the period January, 2000 - December, 2009. To
achieve this aim, I conducted
a series of studies integrating epidemiological and
socio-environmental factors into a unified
statistical modelling framework to better understand transmission
dynamics.
In a narrative review (Chapter 3), I discuss the emergence and
establishment of dengue along
with the possibility of future epidemics of severe dengue.
Introduction of a dengue virus strain
from neighbouring Thailand likely caused the first epidemic in
2000. Cessation of
dichlorodiphenyltrichloroethane (DDT) spraying, climatic,
socio-demographic, and lifestyle
factors also contributed to epidemic transmission and endemic
establishment of the virus.
However, there has been a decline in reported case numbers
following the largest epidemic in
2002, albeit with relatively greater case numbers in alternate
years. This occurred despite the
absence of significant additional control measures and no changes
in the surveillance system
having been introduced during the study period. The observed
decline from 2002 may be an
artefact of the national hospital-based passive surveillance
system even though a real decline
in incidence could plausibly have occurred due to increased
prevalence of immunity, greater
public awareness, and reduced mosquito breeding sites.
From a temporal negative binomial generalised linear model
(Chapter 4), developed using
monthly dengue cases in Dhaka from January, 2000 - December,
2009, I identify that mean
monthly temperature (coefficient estimate: 6.07; 95% confidence
interval: 3.38, 8.67) and
diurnal temperature range (coefficient estimate: 15.57; 95%
confidence interval: 8.03, 22.85)
influence dengue transmission, with significant interaction
between the two (coefficient
estimate: -0.56; 95% confidence interval: -0.81, -0.29), at a lag
of one month in Dhaka, the
capital city of Bangladesh where the highest number of cases were
reported during the study period. In addition to mean monthly
rainfall in the previous two months, dengue incidence is
associated with sea surface temperature anomalies in the current
and previous months through
concomitant anomalies in the annual rainfall cycle. Population
density is also significantly
associated with increased dengue incidence in Dhaka.
Chapter 5 reports an investigation into non-linear
dengue–climate associations using the same
dataset as used for the previous model in Chapter 4. A Bayesian
semi-parametric thin-plate
spline approach estimates that the optimal mean monthly
temperature for dengue transmission
in Dhaka is 29oC and that average monthly rainfall above 15mm
decreases transmission. This
study also reveals that between 2000 and 2009 only 2.8% (95%
Bayesian credible interval 2.7-
2.8) of cases estimated to have occurred in Dhaka were reported
through passive case detection.
A Bayesian spatio-temporal model (Chapter 6), formulated using
monthly dengue cases
reported across the country from January, 2000 - December, 2009,
identifies that the majority
of dengue cases occur in southern Bangladesh with the highest in
Dhaka (located almost in the
middle of the country), accounting for 93.0% of estimated total
cases across the country from
2000-2009. Around 61.0% of Bangladeshi districts are identified
as affected with dengue virus
during the high transmission season of August and September,
contrasting with national
surveillance data suggesting that only 42.0% of districts are
affected.
My thesis provides a better understanding of the dengue-climate
relationships that will enable
more accurate predictions of the likely impacts of changing
climate on dengue risk. Knowledge
about the extent of under-reporting will facilitate precise
estimation of dengue burden which is
vital to assess the risk of severe epidemics. These will help
public health professionals to design
interventions to strengthen the country’s capacity for
prevention of severe dengue epidemics.
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Keywords
Dengue, Passive surveillance, Under-reporting, Climatic factors, Socio-economic context, Urbanisation, Bayesian generalised linear model, spatio-temporal mapping
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