Jayakrishnan Ajayakumar1, Andrew J Curtis2, Vanessa Rouzier3, Jean William Pape3, Sandra Bempah4, Meer Taifur Alam5,6, Md Mahbubul Alam5,6, Mohammed H Rashid5, Afsar Ali5,6, John Glenn Morris5. 1. Department of Population and Quantitative Health Sciences, School of Medicine, Case Western Reserve University, Cleveland, OH, USA. jxa421@case.edu. 2. Department of Population and Quantitative Health Sciences, School of Medicine, Case Western Reserve University, Cleveland, OH, USA. 3. Les Centres Haitian Group for the Study of Kaposi's Sarcoma and Opportunistic Infections (GHESKIO), Port-au-Prince, Haiti. 4. Department of Geography, Kent State University, Kent, OH, USA. 5. Emerging Pathogens Institute and Department of Medicine, College of Medicine, University of Florida, Gainesville, FL, 32601, USA. 6. Emerging Pathogens Institute and Department of Environmental & Global Health, College of Public Health and Health Professions, University of Florida, Gainesville, FL, 32601, USA.
Abstract
BACKGROUND: The health burden in developing world informal settlements often coincides with a lack of spatial data that could be used to guide intervention strategies. Spatial video (SV) has proven to be a useful tool to collect environmental and social data at a granular scale, though the effort required to turn these spatially encoded video frames into maps limits sustainability and scalability. In this paper we explore the use of convolution neural networks (CNN) to solve this problem by automatically identifying disease related environmental risks in a series of SV collected from Haiti. Our objective is to determine the potential of machine learning in health risk mapping for these environments by assessing the challenges faced in adequately training the required classification models. RESULTS: We show that SV can be a suitable source for automatically identifying and extracting health risk features using machine learning. While well-defined objects such as drains, buckets, tires and animals can be efficiently classified, more amorphous masses such as trash or standing water are difficult to classify. Our results further show that variations in the number of image frames selected, the image resolution, and combinations of these can be used to improve the overall model performance. CONCLUSION: Machine learning in combination with spatial video can be used to automatically identify environmental risks associated with common health problems in informal settlements, though there are likely to be variations in the type of data needed for training based on location. Success based on the risk type being identified are also likely to vary geographically. However, we are confident in identifying a series of best practices for data collection, model training and performance in these settings. We also discuss the next step of testing these findings in other environments, and how adding in the simultaneously collected geographic data could be used to create an automatic health risk mapping tool.
BACKGROUND: The health burden in developing world informal settlements often coincides with a lack of spatial data that could be used to guide intervention strategies. Spatial video (SV) has proven to be a useful tool to collect environmental and social data at a granular scale, though the effort required to turn these spatially encoded video frames into maps limits sustainability and scalability. In this paper we explore the use of convolution neural networks (CNN) to solve this problem by automatically identifying disease related environmental risks in a series of SV collected from Haiti. Our objective is to determine the potential of machine learning in health risk mapping for these environments by assessing the challenges faced in adequately training the required classification models. RESULTS: We show that SV can be a suitable source for automatically identifying and extracting health risk features using machine learning. While well-defined objects such as drains, buckets, tires and animals can be efficiently classified, more amorphous masses such as trash or standing water are difficult to classify. Our results further show that variations in the number of image frames selected, the image resolution, and combinations of these can be used to improve the overall model performance. CONCLUSION: Machine learning in combination with spatial video can be used to automatically identify environmental risks associated with common health problems in informal settlements, though there are likely to be variations in the type of data needed for training based on location. Success based on the risk type being identified are also likely to vary geographically. However, we are confident in identifying a series of best practices for data collection, model training and performance in these settings. We also discuss the next step of testing these findings in other environments, and how adding in the simultaneously collected geographic data could be used to create an automatic health risk mapping tool.
Authors: Stephen J Mooney; Charles J DiMaggio; Gina S Lovasi; Kathryn M Neckerman; Michael D M Bader; Julien O Teitler; Daniel M Sheehan; Darby W Jack; Andrew G Rundle Journal: Am J Public Health Date: 2016-01-21 Impact factor: 9.308
Authors: Andrew Curtis; Robert Squires; Vanessa Rouzier; Jean William Pape; Jayakrishnan Ajayakumar; Sandra Bempah; Meer Taifur Alam; Md Mahbubul Alam; Mohammed H Rashid; Afsar Ali; John Glenn Morris Journal: Int J Environ Res Public Health Date: 2019-03-05 Impact factor: 3.390
Authors: Andrew Curtis; Sandra Bempah; Jayakrishnan Ajayakumar; Dania Mofleh; Lorriane Odhiambo Journal: Int J Environ Res Public Health Date: 2018-12-24 Impact factor: 3.390
Authors: Victoria M Mwakalinga; Benn K D Sartorius; Yeromin P Mlacha; Daniel F Msellemu; Alex J Limwagu; Zawadi D Mageni; John M Paliga; Nicodem J Govella; Maureen Coetzee; Gerry F Killeen; Stefan Dongus Journal: Malar J Date: 2016-03-01 Impact factor: 2.979
Authors: Jayakrishnan Ajayakumar; Andrew J Curtis; Vanessa Rouzier; Jean William Pape; Sandra Bempah; Meer Taifur Alam; Md Mahbubul Alam; Mohammed H Rashid; Afsar Ali; John Glenn Morris Journal: Int J Environ Res Public Health Date: 2022-07-22 Impact factor: 4.614