Automatic mapping of high-risk urban areas for Aedes aegypti infestation based on building facade image analysis

Background Dengue, Zika, and chikungunya, whose viruses are transmitted mainly by Aedes aegypti, significantly impact human health worldwide. Despite the recent development of promising vaccines against the dengue virus, controlling these arbovirus diseases still depends on mosquito surveillance and control. Nonetheless, several studies have shown that these measures are not sufficiently effective or ineffective. Identifying higher-risk areas in a municipality and directing control efforts towards them could improve it. One tool for this is the premise condition index (PCI); however, its measure requires visiting all buildings. We propose a novel approach capable of predicting the PCI based on facade street-level images, which we call PCINet. Methodology Our study was conducted in Campinas, a one million-inhabitant city in S{small tilde}ao Paulo, Brazil. We surveyed 200 blocks, visited their buildings, and measured the three traditional PCI components (building and backyard conditions and shading), the facade conditions (taking pictures of them), and other characteristics. We trained a deep neural network with the pictures taken, creating a computational model that can predict buildings conditions based on the view of their facades. We evaluated PCINet in a scenario emulating a real large-scale situation, where the model could be deployed to automatically monitor four regions of Campinas to identify risk areas. Principal findings PCINet produced reasonable results in differentiating the facade condition into three levels, and it is a scalable strategy to triage large areas. The entire process can be automated through data collection from facade data sources and inferences through PCINet. The facade conditions correlated highly with the building and backyard conditions and reasonably well with shading and backyard conditions. The use of street-level images and PCINet could help to optimize Ae. aegypti surveillance and control, reducing the number of in-person visits necessary to identify buildings, blocks, and neighborhoods at higher risk from mosquito and arbovirus diseases.

[1]  G. Ribeiro,et al.  Density of Aedes aegypti (Diptera: Culicidae) in a low-income Brazilian urban community where dengue, Zika, and chikungunya viruses co-circulate , 2023, Parasites & Vectors.

[2]  Hafiz Tayyab Rauf,et al.  WebGIS-Based Real-Time Surveillance and Response System for Vector-Borne Infectious Diseases , 2023, International journal of environmental research and public health.

[3]  C. Wondji,et al.  Spatial distribution and insecticide resistance profile of Aedes aegypti and Aedes albopictus in Douala, the most important city of Cameroon , 2022, PloS one.

[4]  D. Villela,et al.  Citywide Integrated Aedes aegypti Mosquito Surveillance as Early Warning System for Arbovirus Transmission, Brazil , 2022, Emerging infectious diseases.

[5]  G. Bouzillé,et al.  Data-driven methods for dengue prediction and surveillance using real-world and Big Data: A systematic review , 2022, PLoS neglected tropical diseases.

[6]  J. A. Quintanilha,et al.  Water tank and swimming pool detection based on remote sensing and deep learning: Relationship with socioeconomic level and applications in dengue control , 2021, PloS one.

[7]  Md. Siddikur Rahman,et al.  Mapping the spatial distribution of the dengue vector Aedes aegypti and predicting its abundance in northeastern Thailand using machine-learning approach. , 2021, One health.

[8]  A. Morrison,et al.  A dengue outbreak in a rural community in Northern Coastal Ecuador: An analysis using unmanned aerial vehicle mapping , 2021, PLoS neglected tropical diseases.

[9]  F. Chiaravalloti-Neto,et al.  Diffusion of sylvatic yellow fever in the state of São Paulo, Brazil , 2021, Scientific Reports.

[10]  Le Wang,et al.  Detecting individual abandoned houses from google street view: A hierarchical deep learning approach , 2021 .

[11]  Min Kang,et al.  Facilitating fine-grained intra-urban dengue forecasting by integrating urban environments measured from street-view images , 2021, Infectious Diseases of Poverty.

[12]  Vikram Kumar,et al.  Social and environmental risk factors for dengue in Delhi city: A retrospective study , 2021, PLoS neglected tropical diseases.

[13]  Sergio L. Netto,et al.  A Comparative Analysis of Object Detection Metrics with a Companion Open-Source Toolkit , 2021, Electronics.

[14]  J. A. Quintanilha,et al.  Predicting Aedes aegypti infestation using landscape and thermal features , 2020, Scientific Reports.

[15]  Zhidong Cao,et al.  Artificial intelligence–enabled public health surveillance—from local detection to global epidemic monitoring and control , 2020, Artificial Intelligence in Medicine.

[16]  Gabriel M. Araujo,et al.  Automatic detection of Aedes aegypti breeding grounds based on deep networks with spatio-temporal consistency , 2020, Comput. Environ. Urban Syst..

[17]  T. S. de Azevedo,et al.  Spatiotemporal evolution of dengue outbreaks in Brazil. , 2020, Transactions of the Royal Society of Tropical Medicine and Hygiene.

[18]  J. A. Quintanilha,et al.  Use of an Extended Premise Condition Index for detection of priority areas for vector control actions. , 2020, Acta tropica.

[19]  Camila Lorenz,et al.  COVID-19 and dengue fever: A dangerous combination for the health system in Brazil , 2020, Travel Medicine and Infectious Disease.

[20]  L. Silveira,et al.  Ocorrência de dengue e sua relação com medidas de controle e níveis de infestação de Aedes aegypti em uma cidade do sudeste brasileiro , 2020, BEPA. Boletim Epidemiológico Paulista.

[21]  Alexander J. Smola,et al.  Dive into Deep Learning , 2020, Journal of the American College of Radiology : JACR.

[22]  J. A. Quintanilha,et al.  Remote sensing for risk mapping of Aedes aegypti infestations: Is this a practical task? , 2020, Acta tropica.

[23]  B. de Thoisy,et al.  Recent sylvatic yellow fever virus transmission in Brazil: the news from an old disease , 2020, Virology Journal.

[24]  Natalia Gimelshein,et al.  PyTorch: An Imperative Style, High-Performance Deep Learning Library , 2019, NeurIPS.

[25]  Gregory Mahr Validation , 2019, Academic Psychiatry.

[26]  M. Kucukoglu,et al.  Investigation , 2000, BMJ : British Medical Journal.

[27]  O. Horstick,et al.  Environmental methods for dengue vector control – A systematic review and meta-analysis , 2019, PLoS neglected tropical diseases.

[28]  Cristian Cechinel,et al.  Combining Street-level and Aerial Images for Dengue Incidence Rate Estimation , 2019, 2019 International Joint Conference on Neural Networks (IJCNN).

[29]  P. Haddawy,et al.  Large scale detailed mapping of dengue vector breeding sites using street view images , 2019, PLoS neglected tropical diseases.

[30]  Michael F Dulin,et al.  An operational machine learning approach to predict mosquito abundance based on socioeconomic and landscape patterns , 2019, Landscape Ecology.

[31]  A. Whiteman,et al.  Aedes Mosquito Infestation in Socioeconomically Contrasting Neighborhoods of Panama City , 2019, EcoHealth.

[32]  M. Blangiardo,et al.  Seroprevalence for dengue virus in a hyperendemic area and associated socioeconomic and demographic factors using a cross-sectional design and a geostatistical approach, state of São Paulo, Brazil , 2019, BMC Infectious Diseases.

[33]  J. A. Quintanilha,et al.  Influence of strategic points in the dispersion of Aedes aegypti in infested areas , 2019, Revista de saude publica.

[34]  Shuchi Mala,et al.  Hotspot Detection of Dengue Fever Outbreaks Using DBSCAN Algorithm , 2019, 2019 9th International Conference on Cloud Computing, Data Science & Engineering (Confluence).

[35]  J. Powell,et al.  Aedes aegypti vector competence studies: A review , 2018, Infection, genetics and evolution : journal of molecular epidemiology and evolutionary genetics in infectious diseases.

[36]  Ricardo Matsumura de Araújo,et al.  Towards Predicting Dengue Fever Rates Using Convolutional Neural Networks and Street-Level Images , 2018, 2018 International Joint Conference on Neural Networks (IJCNN).

[37]  C. Scavuzzo,et al.  Urban environmental clustering to assess the spatial dynamics of Aedes aegypti breeding sites. , 2018, Geospatial Health.

[38]  F. Chiaravalloti-Neto,et al.  Low socioeconomic condition and the risk of dengue fever: A direct relationship. , 2018, Acta tropica.

[39]  L. Bowman,et al.  Improved tools and strategies for the prevention and control of arboviral diseases: A research-to-policy forum , 2018, PLoS neglected tropical diseases.

[40]  V. Teich,et al.  Aedes aegypti e sociedade: o impacto econômico das arboviroses no Brasil , 2017 .

[41]  Charitha Elvitigala,et al.  Suppressing dengue via a drone system , 2017, 2017 Seventeenth International Conference on Advances in ICT for Emerging Regions (ICTer).

[42]  Kaiming He,et al.  Focal Loss for Dense Object Detection , 2017, 2017 IEEE International Conference on Computer Vision (ICCV).

[43]  J. Vulule,et al.  Characterization and productivity profiles of Aedes aegypti (L.) breeding habitats across rural and urban landscapes in western and coastal Kenya , 2017, Parasites & Vectors.

[44]  N. Andersson,et al.  Aedes aegypti breeding ecology in Guerrero: cross-sectional study of mosquito breeding sites from the baseline for the Camino Verde trial in Mexico , 2017, BMC Public Health.

[45]  M. Reis,et al.  Storm drains as larval development and adult resting sites for Aedes aegypti and Aedes albopictus in Salvador, Brazil , 2016, Parasites & Vectors.

[46]  David L. Smith,et al.  Quantifying the Epidemiological Impact of Vector Control on Dengue , 2016, PLoS neglected tropical diseases.

[47]  Derek Gatherer,et al.  Zika virus: a previously slow pandemic spreads rapidly through the Americas. , 2016, The Journal of general virology.

[48]  Y. Halasa,et al.  Cost of Dengue Vector Control Activities in Malaysia , 2015, The American journal of tropical medicine and hygiene.

[49]  G. Áñez,et al.  Epidemiological Scenario of Dengue in Brazil , 2015, BioMed research international.

[50]  Duane J. Gubler,et al.  A Critical Assessment of Vector Control for Dengue Prevention , 2015, PLoS neglected tropical diseases.

[51]  S. Higgs,et al.  Evaluation of Simultaneous Transmission of Chikungunya Virus and Dengue Virus Type 2 in Infected Aedes aegypti and Aedes albopictus (Diptera: Culicidae) , 2015, Journal of medical entomology.

[52]  Nildimar A. Honório,et al.  Surveillance of Aedes aegypti: Comparison of House Index with Four Alternative Traps , 2015, PLoS neglected tropical diseases.

[53]  Jimmy Ba,et al.  Adam: A Method for Stochastic Optimization , 2014, ICLR.

[54]  Sarah N. Hemmings,et al.  Correlating Remote Sensing Data with the Abundance of Pupae of the Dengue Virus Mosquito Vector, Aedes aegypti, in Central Mexico , 2014, ISPRS Int. J. Geo Inf..

[55]  Marylene de Brito Arduino,et al.  Spatial Distribution of the Risk of Dengue and the Entomological Indicators in Sumaré, State of São Paulo, Brazil , 2014, PLoS neglected tropical diseases.

[56]  Silvia Runge-Ranzinger,et al.  Assessing the Relationship between Vector Indices and Dengue Transmission: A Systematic Review of the Evidence , 2014, PLoS neglected tropical diseases.

[57]  Gail M Williams,et al.  Internet-based surveillance systems for monitoring emerging infectious diseases , 2013, The Lancet Infectious Diseases.

[58]  Roberto C. Peres,et al.  The use of the Premise Condition Index (PCI) to Provide Guidelines for Aedes aegypti Surveys , 2013, Journal of Vector Ecology.

[59]  M. Koopmans,et al.  Come fly with me: review of clinically important arboviruses for global travelers. , 2012, Journal of clinical virology : the official publication of the Pan American Society for Clinical Virology.

[60]  Melissa Mallon Data Curation , 2012 .

[61]  Minho Kim,et al.  Detection of Swimming Pools by Geographic Object-based Image Analysis to Support West Nile Virus Control Efforts , 2011 .

[62]  Duane J. Gubler,et al.  Dengue, Urbanization and Globalization: The Unholy Trinity of the 21st Century , 2011, Tropical medicine and health.

[63]  E. Massad,et al.  The cost of dengue control , 2011, The Lancet.

[64]  Taha Kass-Hout,et al.  A New Approach to Monitoring Dengue Activity , 2011, PLoS neglected tropical diseases.

[65]  Jo M. Barnes,et al.  Housing conditions, sanitation status and associated health risks in selected subsidized low-cost housing settlements in Cape Town, South Africa , 2011 .

[66]  L. Acquaye Low-income homeowners and the challenges of home maintenance , 2011 .

[67]  O. Horstick,et al.  Dengue vector-control services: how do they work? A systematic literature review and country case studies. , 2010, Transactions of the Royal Society of Tropical Medicine and Hygiene.

[68]  O. Horstick,et al.  Effectiveness of peridomestic space spraying with insecticide on dengue transmission; systematic review , 2010, Tropical medicine & international health : TM & IH.

[69]  Marli Tenório Cordeiro,et al.  Seroprevalence and risk factors for dengue infection in socio-economically distinct areas of Recife, Brazil. , 2010, Acta tropica.

[70]  V. S. Nam,et al.  Reducing costs and operational constraints of dengue vector control by targeting productive breeding places: a multi‐country non‐inferiority cluster randomized trial , 2009, Tropical medicine & international health : TM & IH.

[71]  C. E. Pedreira,et al.  Aedes aegypti immature forms distribution according to type of breeding site. , 2009, The American journal of tropical medicine and hygiene.

[72]  R. Souza-Santos,et al.  Occurrence, productivity and spatial distribution of key‐premises in two dengue‐endemic areas of Rio de Janeiro and their role in adult Aedes aegypti spatial infestation pattern , 2008, Tropical medicine & international health : TM & IH.

[73]  Francisco Chiaravalloti Neto,et al.  Infestação de área urbana por Aedes aegypti e relação com níveis socioeconômicos , 2007 .

[74]  John A. Saghri,et al.  A rectangular-fit classifier for synthetic aperture radar automatic target recognition , 2007, SPIE Optical Engineering + Applications.

[75]  J. Spiegel,et al.  Social and environmental determinants of Aedes aegypti infestation in Central Havana: results of a case–control study nested in an integrated dengue surveillance programme in Cuba , 2007, Tropical medicine & international health : TM & IH.

[76]  L. Harrington,et al.  Insecticide Susceptibility of Aedes aegypti and Aedes albopictus across Thailand , 2005, Journal of medical entomology.

[77]  P. Ribolla,et al.  Application of an alternative Aedes species (Diptera: culicidae) surveillance method in Botucatu City, Sao Paulo, Brazil. , 2005, The American journal of tropical medicine and hygiene.

[78]  M. Salah,et al.  Methodology , 2003 .

[79]  D. Focks,et al.  Pupal survey: an epidemiologically significant surveillance method for Aedes aegypti: an example using data from Trinidad. , 1996, The American journal of tropical medicine and hygiene.

[80]  B. Kay,et al.  The Premise Condition Index: a tool for streamlining surveys of Aedes aegypti. , 1995, The American journal of tropical medicine and hygiene.

[81]  B. Kay,et al.  Understanding productivity, a key to Aedes aegypti surveillance. , 1995, The American journal of tropical medicine and hygiene.

[82]  Norma Banas,et al.  Visualization , 1968 .

[83]  Ananya Joshi,et al.  Review of machine learning techniques for mosquito control in urban environments , 2021, Ecol. Informatics.

[84]  Formal Analysis , 2021, Encyclopedic Dictionary of Archaeology.

[85]  M. L. G. Macoris,et al.  Evaluation of premise condition index in the context of Aedes aegypti control in Marília, São Paulo, Brazil , 2009 .

[86]  P. L. Tauil,et al.  Urbanização e ecologia do dengue , 2001 .

[87]  D. Erickson,et al.  Vector-Borne Diseases, Surveillance, Prevention Evaluation of Unmanned Aerial Vehicles and Neural Networks for Integrated Mosquito Management of Aedes albopictus (Diptera: Culicidae) , 2022 .