Integrating rapid risk mapping and mobile phone call record data for strategic malaria elimination planning

Tatem, Andrew J.; Huang, Zhengjing; Narib, Clothilde; Kumar, Udayan; Kandula, Deepika; Pindolia, Deepa; Smith, David L.; Cohen, Justin M.; Graupe, Bonita; Uusiku, Petrina; Lourenço, Christopher

doi:10.1186/1475-2875-13-52

Cited by 149 publications

(146 citation statements)

References 55 publications

(86 reference statements)

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“…A better understanding of persistence would require, however, additional consideration of spatial variation in demographic and environmental factors at sufficiently high spatial and temporal resolution. Although among demographic factors, human mobility has recently attracted attention [5][6][7][8][9], the role of population density remains poorly understood in the population dynamics of malaria and other vector-transmitted diseases. In particular, larger numbers of hosts in mathematical models generally dilute the number of vector bites and in so doing also decrease transmission rates [10].…”

Section: Introductionmentioning

confidence: 99%

Temperature and population density determine reservoir regions of seasonal persistence in highland malaria

et al. 2015

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A better understanding of malaria persistence in highly seasonal environments such as highlands and desert fringes requires identifying the factors behind the spatial reservoir of the pathogen in the low season. In these 'unstable' malaria regions, such reservoirs play a critical role by allowing persistence during the low transmission season and therefore, between seasonal outbreaks. In the highlands of East Africa, the most populated epidemic regions in Africa, temperature is expected to be intimately connected to where in space the disease is able to persist because of pronounced altitudinal gradients. Here, we explore other environmental and demographic factors that may contribute to malaria's highland reservoir. We use an extensive spatio-temporal dataset of confirmed monthly Plasmodium falciparum cases from 1995 to 2005 that finely resolves space in an Ethiopian highland. With a Bayesian approach for parameter estimation and a generalized linear mixed model that includes a spatially structured random effect, we demonstrate that population density is important to disease persistence during the low transmission season. This population effect is not accounted for in typical models for the transmission dynamics of the disease, but is consistent in part with a more complex functional form of the force of infection proposed by theory for vector-borne infections, only during the low season as we discuss. As malaria risk usually decreases in more urban environments with increased human densities, the opposite counterintuitive finding identifies novel control targets during the low transmission season in African highlands.

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Section: Introductionmentioning

confidence: 99%

Temperature and population density determine reservoir regions of seasonal persistence in highland malaria

et al. 2015

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“…Most of these studies focused on specific cities or city neighborhoods or groups, and were aimed at understanding traffic flows (40), mapping the intensity of human activities at different times (42)(43)(44), or exploring seasonality in foreign tourist numbers and destinations (45,46). Population movement analyses based on MP data are particularly promising for improving responses to disasters (47,48) and for planning malaria elimination strategies (49)(50)(51). However, to date, these data have not been assessed in their capacity to map human population at fine spatial and temporal resolutions over large geographical extents.…”

mentioning

confidence: 99%

Dynamic population mapping using mobile phone data

DeVillé

Linard

Martín

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

729

528

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During the past few decades, technologies such as remote sensing, geographical information systems, and global positioning systems have transformed the way the distribution of human population is studied and modeled in space and time. However, the mapping of populations remains constrained by the logistics of censuses and surveys. Consequently, spatially detailed changes across scales of days, weeks, or months, or even year to year, are difficult to assess and limit the application of human population maps in situations in which timely information is required, such as disasters, conflicts, or epidemics. Mobile phones (MPs) now have an extremely high penetration rate across the globe, and analyzing the spatiotemporal distribution of MP calls geolocated to the tower level may overcome many limitations of census-based approaches, provided that the use of MP data is properly assessed and calibrated. Using datasets of more than 1 billion MP call records from Portugal and France, we show how spatially and temporarily explicit estimations of population densities can be produced at national scales, and how these estimates compare with outputs produced using alternative human population mapping methods. We also demonstrate how maps of human population changes can be produced over multiple timescales while preserving the anonymity of MP users. With similar data being collected every day by MP network providers across the world, the prospect of being able to map contemporary and changing human population distributions over relatively short intervals exists, paving the way for new applications and a near real-time understanding of patterns and processes in human geography.O ur knowledge of human population numbers and distribution for many areas of the world remains poor (1) despite their importance for policy (2, 3), operational decisions (4), and research (5-7) across many fields. In the 1990s, a growing interest in the global mapping of human populations emerged (8, 9), leading to the advanced development of methodologies that undertake the spatial downscaling of human population count data from censuses summarized over large and irregular administrative units to grid squares of 100 m to 5 km resolution (10-16). Initial efforts to downscale these data used simple areal weighting methods (10, 17) or dasymetric modeling approaches (13-15), which use ancillary layers to redistribute population counts within administrative units (18). Modeling techniques that spatially downscale population numbers into gridded datasets continue to be refined, with basic dasymetric models increasing in sophistication, incorporating multiscale remotely sensed and geospatial data and making improvements in the type of statistical algorithms used in the modeling process (19)(20)(21). These detailed population databases have proven crucial for studies reliant on information about human population distributions, typically for calculating populations at risk for human or natural disasters (22-24), to assess vulnerabilities (7, 25), or to derive hea...

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“…Using household surveys, malaria hot-spots (the clustering of high malaria incidence cases) data, and more readily available spatial malaria databases along with a better understanding by decision makers on the usages and capabilities of these spatial analytical methods, can lead to more successful malaria elimination strategies [26]. The use of GIS and GPS systems connected to mobile phones [27] can also aid in malaria case detection and delivery of health services particularly in remote areas of CHT where tracking and analyzing malaria prevalence data can often be difficult [28]. With changing malaria epidemiology and reduced burden of malaria throughout the country, Bangladesh needs to focus on CHT region elimination strategies to address malaria hot-spots efficiently and effectively as well as reduce malaria importation, insecticide resistance, drug resistance [29], and the mapping of asymptomatic carrier [24].…”

Section: Discussionmentioning

confidence: 99%

Geospatial Technology: A Tool to Aid in the Elimination of Malaria in Bangladesh

Kirk

Haq

Alam

et al. 2014

IJGI

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Bangladesh is a malaria endemic country. There are 13 districts in the country bordering India and Myanmar that are at risk of malaria. The majority of malaria morbidity and mortality cases are in the Chittagong Hill Tracts, the mountainous southeastern region of Bangladesh. In recent years, malaria burden has declined in the country. In this study, we reviewed and summarized published data (through 2014) on the use of geospatial technologies on malaria epidemiology in Bangladesh and outlined potential contributions of geospatial technologies for eliminating malaria in the country. We completed a literature review using "malaria, Bangladesh" search terms and found 218 articles published in peer-reviewed journals listed in PubMed. After a detailed review, 201 articles were excluded because they did not meet our inclusion criteria, 17 articles were selected for final evaluation. Published studies indicated geospatial technologies tools (Geographic Information System, Global Positioning System, and Remote Sensing) were used to determine vector-breeding sites, land cover classification, accessibility to health facility, treatment seeking behaviors, and risk mapping at the household, regional, and national levels in Bangladesh. To achieve the goal of malaria elimination in Bangladesh, we concluded that further research using geospatial technologies should be integrated into the country's ongoing surveillance system to identify and better assess progress towards malaria elimination.

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Integrating rapid risk mapping and mobile phone call record data for strategic malaria elimination planning

Cited by 149 publications

References 55 publications

Temperature and population density determine reservoir regions of seasonal persistence in highland malaria

Temperature and population density determine reservoir regions of seasonal persistence in highland malaria

Dynamic population mapping using mobile phone data

Geospatial Technology: A Tool to Aid in the Elimination of Malaria in Bangladesh

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