Emilie Bruzelius1, Matthew Le1, Avi Kenny2,3, Jordan Downey2, Matteo Danieletto4, Aaron Baum1, Patrick Doupe1, Bruno Silva1, Philip J Landrigan5, Prabhjot Singh6. 1. Arnhold Institute for Global Health, Icahn School of Medicine at Mount Sinai, New York, New York, USA. 2. Last Mile Health, Congo Town, Monrovia, Liberia. 3. Department of Biostatistics, University of Washington, Seattle, Washington, USA. 4. Institute for Next Generation Healthcare, Icahn School of Medicine at Mount Sinai, New York, New York, USA. 5. Schiller Institute for Integrated Science and Society, Boston College, Chestnut Hill, Massachusetts, USA. 6. Department of Health Systems Design and Global Health, Arnhold Institute for Global Health, Icahn School of Medicine at Mount Sinai, New York, New York, USA.
Abstract
OBJECTIVE: Community health systems operating in remote areas require accurate information about where people live to efficiently provide services across large regions. We sought to determine whether a machine learning analyses of satellite imagery can be used to map remote communities to facilitate service delivery and planning. MATERIALS AND METHODS: We developed a method for mapping communities using a deep learning approach that excels at detecting objects within images. We trained an algorithm to detect individual buildings, then examined building clusters to identify groupings suggestive of communities. The approach was validated in southeastern Liberia, by comparing algorithmically generated results with community location data collected manually by enumerators and community health workers. RESULTS: The deep learning approach achieved 86.47% positive predictive value and 79.49% sensitivity with respect to individual building detection. The approach identified 75.67% (n = 451) of communities registered through the community enumeration process, and identified an additional 167 potential communities not previously registered. Several instances of false positives and false negatives were identified. DISCUSSION: Analysis of satellite images is a promising solution for mapping remote communities rapidly, and with relatively low costs. Further research is needed to determine whether the communities identified algorithmically, but not registered in the manual enumeration process, are currently inhabited. CONCLUSIONS: To our knowledge, this study represents the first effort to apply image recognition algorithms to rural healthcare delivery. Results suggest that these methods have the potential to enhance community health worker scale-up efforts in underserved remote communities.
OBJECTIVE: Community health systems operating in remote areas require accurate information about where people live to efficiently provide services across large regions. We sought to determine whether a machine learning analyses of satellite imagery can be used to map remote communities to facilitate service delivery and planning. MATERIALS AND METHODS: We developed a method for mapping communities using a deep learning approach that excels at detecting objects within images. We trained an algorithm to detect individual buildings, then examined building clusters to identify groupings suggestive of communities. The approach was validated in southeastern Liberia, by comparing algorithmically generated results with community location data collected manually by enumerators and community health workers. RESULTS: The deep learning approach achieved 86.47% positive predictive value and 79.49% sensitivity with respect to individual building detection. The approach identified 75.67% (n = 451) of communities registered through the community enumeration process, and identified an additional 167 potential communities not previously registered. Several instances of false positives and false negatives were identified. DISCUSSION: Analysis of satellite images is a promising solution for mapping remote communities rapidly, and with relatively low costs. Further research is needed to determine whether the communities identified algorithmically, but not registered in the manual enumeration process, are currently inhabited. CONCLUSIONS: To our knowledge, this study represents the first effort to apply image recognition algorithms to rural healthcare delivery. Results suggest that these methods have the potential to enhance community health worker scale-up efforts in underserved remote communities.
Authors: Carla AbouZahr; Don de Savigny; Lene Mikkelsen; Philip W Setel; Rafael Lozano; Erin Nichols; Francis Notzon; Alan D Lopez Journal: Lancet Date: 2015-05-10 Impact factor: 79.321
Authors: Neal Jean; Marshall Burke; Michael Xie; W Matthew Davis; David B Lobell; Stefano Ermon Journal: Science Date: 2016-08-19 Impact factor: 47.728
Authors: Peter W Luckow; Avi Kenny; Emily White; Madeleine Ballard; Lorenzo Dorr; Kirby Erlandson; Benjamin Grant; Alice Johnson; Breanna Lorenzen; Subarna Mukherjee; E John Ly; Abigail McDaniel; Netus Nowine; Vidiya Sathananthan; Gerald A Sechler; John D Kraemer; Mark J Siedner; Rajesh Panjabi Journal: Bull World Health Organ Date: 2017-02-01 Impact factor: 9.408
Authors: N A Wardrop; W C Jochem; T J Bird; H R Chamberlain; D Clarke; D Kerr; L Bengtsson; S Juran; V Seaman; A J Tatem Journal: Proc Natl Acad Sci U S A Date: 2018-03-19 Impact factor: 11.205
Authors: Joshua J Levy; Rebecca M Lebeaux; Anne G Hoen; Brock C Christensen; Louis J Vaickus; Todd A MacKenzie Journal: Front Public Health Date: 2021-11-05