Spatial analytics to elucidate the incubation period and drivers of visceral leishmaniasis: case of Turkana County in Kenya

Publication Type

Journal Article

Journal Name

Frontiers in Digital Health

Name of Author

Kennedy Senagi, International Centre of Insect Physiology and Ecology Nairobi
Maureen Nzilani, International Centre of Insect Physiology and Ecology Nairobi
Evans Omondi, Strathmore University
David P. Tchouassi, International Centre of Insect Physiology and Ecology Nairobi
Tobias Landmann, International Centre of Insect Physiology and Ecology Nairobi
Damaris Matoke-Muhia, Kenya Medical Research Institute
Emmanuel Okunga, Ministry of Health Nairobi
Barrington Gesimba, International Centre of Insect Physiology and Ecology Nairobi
Elfatih M. Abdel-Rahman, International Centre of Insect Physiology and Ecology Nairobi
Dawn Maranga, Foundation for Innovative New Diagnostics, Switzerland
Joseph M. Ndungu, Foundation for Innovative New Diagnostics, Switzerland
Daniel Masiga, International Centre of Insect Physiology and Ecology Nairobi

Publication Date

1-1-2025

Abstract

Introduction: Visceral leishmaniasis (VL) is a severe and neglected tropical disease of public health concern. VL is fatal if not treated. Kenya has experienced multiple outbreaks of the disease since 2017. The underlying drivers of the disease risk dynamics, as well as the incubation period, are not well understood. Methods: We implemented statistical (spatial logistic regression and Bayesian spatial) and machine learning (random forest, support vector machine, AdaBoost, logistic regression, and extra trees) models to estimate the incubation period and predict areas of low/high risk in Turkana County, an endemic VL foci in Kenya. Two-year (2019–2020) patient data were sourced from 12 VL treatment centers in Turkana County. Environmental and weather data were sourced from satellites, while demographic data were extracted from the Kenyan Population and Housing Census 2019 dataset. The environmental and weather data were lagged up to 8 months to mimic the disease incubation period. Results: The AdaBoost was the best-performing classifier with an area under the curve of the receiver operating characteristic value of 71.2%. The model predicted three months as the optimal incubation period. Age, distance to a healthcare facility, mean monthly humidity, greenness, and total precipitation were identified as the five main predictors. The epidemiological risk map (for December 2024) was generated and deployed on the Web (https://dudumapper.icipe.org/). The Kerio Delta, Lokori, and the shores of the Lake Turkana regions were predicted to have a mid to high risk/number of cases. Discussion: These data-driven findings can improve the understanding of VL risk dynamics and support decision makers in the preparation, mitigation, and elimination of VL.

Keywords

data science, disease modelling, disease risk, environmental influences, epidemiology

Recommended Citation

Senagi, K., Nzilani, M., Omondi, E., Tchouassi, D., Landmann, T., Matoke-Muhia, D., Okunga, E., Gesimba, B., Abdel-Rahman, E., Maranga, D., Ndungu, J., & Masiga, D. (2025). Spatial analytics to elucidate the incubation period and drivers of visceral leishmaniasis: case of Turkana County in Kenya. Frontiers in Digital Health, 7 https://doi.org/10.3389/fdgth.2025.1643314

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.