TY - JOUR
T1 - Predicting the environmental suitability for Anopheles stephensi under the current conditions in Ghana
AU - Ismail, Rahmat Bint Yusif
AU - Bozorg-Omid, Faramarz
AU - Osei, Joseph Harold Nyarko
AU - Pi-Bansa, Sellase
AU - Frempong, Kwadwo Kyeremeh
AU - Ofei, Mavis Koryo
AU - Boakye, Helena Anokyewaa
AU - Ansah-Owusu, Jane
AU - Akorful, Sandra Candys Adwirba
AU - Tawiah-Mensah, Christopher Nii Laryea
AU - Abudu, Mufeez
AU - Asafu-Adjaye, Andy
AU - Appawu, Maxwell Alexander
AU - Boakye, Daniel Adjei
AU - Vatandoost, Hassan
AU - Sedaghat, Mohammad Mehdi
AU - Youssefi, Fahimeh
AU - Hanafi-Bojd, Ahmad Ali
AU - Dadzie, Samuel Kweku
N1 - Publisher Copyright:
© 2024, The Author(s).
PY - 2024/12
Y1 - 2024/12
N2 - Vector-borne diseases emergence, particularly malaria, present a significant public health challenge worldwide. Anophelines are predominant malaria vectors, with varied distribution, and influenced by environment and climate. This study, in Ghana, modelled environmental suitability for Anopheles stephensi, a potential vector that may threaten advances in malaria and vector control. Understanding this vector’s distribution and dynamics ensures effective malaria and vector control programmes implementation. We explored the MaxEnt ecological modelling method to forecast An. stephensi’s potential hotspots and niches. We analysed environmental and climatic variables to predict spatial distribution and ecological niches of An. stephensi with a spatial resolution of approximately 5 km2. Analysing geospatial and species occurrence data, we identified optimal environmental conditions and important factors for its presence. The model’s most important variables guided hotspot prediction across several ecological zones aside from urban and peri-urban regions. Considering the vector’s complex bionomics, these areas provide varying and adaptable conditions for the vector to colonise and establish. This is shown by the AUC = 0.943 prediction accuracy of the model, which is considered excellent. Based on our predictions, this vector species would thrive in the Greater Accra, Ashanti Central, Upper East, Northern, and North East regions. Forecasting its environmental suitability by ecological niche modelling supports proactive surveillance and focused malaria management strategies. Public health officials can act to reduce the risk of malaria transmission by identifying areas where mosquitoes may breed, which will ultimately improve health outcomes and disease control.
AB - Vector-borne diseases emergence, particularly malaria, present a significant public health challenge worldwide. Anophelines are predominant malaria vectors, with varied distribution, and influenced by environment and climate. This study, in Ghana, modelled environmental suitability for Anopheles stephensi, a potential vector that may threaten advances in malaria and vector control. Understanding this vector’s distribution and dynamics ensures effective malaria and vector control programmes implementation. We explored the MaxEnt ecological modelling method to forecast An. stephensi’s potential hotspots and niches. We analysed environmental and climatic variables to predict spatial distribution and ecological niches of An. stephensi with a spatial resolution of approximately 5 km2. Analysing geospatial and species occurrence data, we identified optimal environmental conditions and important factors for its presence. The model’s most important variables guided hotspot prediction across several ecological zones aside from urban and peri-urban regions. Considering the vector’s complex bionomics, these areas provide varying and adaptable conditions for the vector to colonise and establish. This is shown by the AUC = 0.943 prediction accuracy of the model, which is considered excellent. Based on our predictions, this vector species would thrive in the Greater Accra, Ashanti Central, Upper East, Northern, and North East regions. Forecasting its environmental suitability by ecological niche modelling supports proactive surveillance and focused malaria management strategies. Public health officials can act to reduce the risk of malaria transmission by identifying areas where mosquitoes may breed, which will ultimately improve health outcomes and disease control.
UR - http://www.scopus.com/inward/record.url?scp=85182098895&partnerID=8YFLogxK
U2 - 10.1038/s41598-024-51780-7
DO - 10.1038/s41598-024-51780-7
M3 - Article
C2 - 38212448
AN - SCOPUS:85182098895
SN - 2045-2322
VL - 14
JO - Scientific Reports
JF - Scientific Reports
IS - 1
M1 - 1116
ER -