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USF using AI to help combat malaria

鈥淥ur algorithm automatically identifies the head, thorax, abdomen, wings and legs from a mosquito image, then it uses specific anatomical components to identify the mosquito type 鈥 for example, the wing for Anopheles stephensi.鈥

USF using AI to help combat malaria

By: Cassidy Delamarter, University Communications and Marketing

最新天美传媒 researchers are using artificial intelligence to revolutionize mosquito surveillance to help combat malaria in Africa. Ryan Carney, associate professor of integrative biology, and Sriram Chellappan, professor in the department of computer science and engineering, will collaborate with an interdisciplinary team of researchers to advance malaria research and explore innovative solutions to target malaria-infected mosquitoes in real-time.

The project is part of an international effort funded by a from the National Institute of Allergy and Infectious Diseases, part of the National Institutes of Health. Known as EMERGENTS (Enhancing Malaria Epidemiology Research through Genomics and Translational Systems), the project will establish a new International Center for Excellence for Malaria Research in west-central Africa, with in-country expertise in Nigeria and Cameroon. According to the , in 2022, there were 249 million new cases of malaria globally and 608,000 resulted in death. Africa is disproportionately affected by the disease, accounting for 95% of the world鈥檚 2022 malaria deaths.

Over the next five years, the international center will advance evidence-based strategies for malaria eradication and elimination, including training a new generation of African scientists, better understanding of insecticide resistance and investigating the geographic expansion of Anopheles stephensi, a dangerous urban malaria vector that has recently started to invade Africa.

The information gathered at the center will be used for global management of malaria. While the primary focus of the EMERGENTS initiative is Africa, the technology and methodologies developed through this project have significant implications for the United States. Florida, with its conducive climate and high rate of international travelers, remains a critical point for monitoring mosquito-borne illnesses.

dashboard

Carney and Chellappan will lead the project鈥檚 image-driven mosquito surveillance efforts by training local scientists how to leverage citizen science through , a global mosquito-tracking dashboard they created in 2022 with funding from the National Science Foundation. The dashboard 鈥 accessible online 鈥 integrates hundreds of thousands of mosquito observations from various platforms into an interactive, real-time dashboard and data portal, using photos that people upload from their smartphones.

Using some of the same unique algorithms, Chellappan is testing an artificial intelligence-enabled smart trap that will lure, capture and monitor Anopheles stephensi. The goal is to deploy multiple prototypes of the patent-pending smart trap throughout west-central Africa during this project to specifically trap and automate the identification of Anopheles stephensi instantaneously.

algorithm example

鈥淲e are the only team that we know of globally that can successfully enable anatomy-based classification from a single photo to identify mosquitoes,鈥 Chellappan said. 鈥淥ur algorithm automatically identifies the head, thorax, abdomen, wings and legs from a mosquito image, then it uses specific anatomical components to identify the mosquito type 鈥 for example, the wing for Anopheles stephensi.鈥

The dashboard and smart trap are powerful tools that provide real-time data to researchers and mosquito-control personnel for the early detection of invasive and disease-carrying mosquitoes. The success of the dashboard and citizen science are documented in published by Carney and Chellappan. 

In an in collaboration with the Centers for Disease Control and Prevention, this process has already been piloted through citizen science activities in countries, including Ethiopia and Madagascar. The additional funding from this new project will allow Carney and Chellappan to refine their algorithms and add additional species for automated identification, with the main target being Anopheles stephensi.

Anopheles stephensi is a very efficient vector of malaria, and something that has adapted itself to the human environment,鈥 Carney said. 鈥淭herefore, it can cause huge, unprecedented epidemics in urban centers, which we have already started to see unfolding in Africa. Florida is ground-zero for mosquito-borne diseases in the U.S. and although Anopheles stephensi has not yet been detected domestically, our citizen science infrastructure and species identification technologies ensure that we are prepared to fight this potential threat.鈥

As the technology advances throughout this project, Chellappan hopes the traps can be sold to citizens at an affordable price to further enhance community-led mosquito surveillance and control both abroad and locally.

This is a global interdisciplinary project with many collaborators, including the University of Florida, African Centre of Excellence for Genomics of Infectious Diseases, Centre for Research in Infectious Diseases, University of North Carolina at Chapel Hill, Africa CDC, Brown University, Centre Pasteur du Cameroun, CERMEL Gabon, DELGEME Plus Mali, Naval Medical Research Unit-3 Italy and University of Dschang in Cameroon.

USF received funding support as a subaward under NIAID grant number鈥疷19AI181594鈥痶o the University of Florida. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.

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