2018
DOI: 10.1155/2018/7019868
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Mathematical Model for Hepatocytic-Erythrocytic Dynamics of Malaria

Abstract: Human malaria remains a major killer disease worldwide, with nearly half (3.2 billion) of the world's population at risk of malaria infection. The infectious protozoan disease is endemic in tropical and subtropical regions, with an estimated 212 million new cases and 429,000 malaria-related deaths in 2015. An in-host mathematical model of Plasmodium falciparum malaria that describes the dynamics and interactions of malaria parasites with the host's liver cells (hepatocytic stage), the red blood cells (erythroc… Show more

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Cited by 10 publications
(3 citation statements)
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“…The global exchange of pathogen between organs or microcommunities or microenvironments is usually through the circulatory system or through the lymphatic system. For typical examples of single scale models developed at this scale organization see ( Orwa, Mbogo, & Luboobi, 2018 ; Selemani, Luboobi, & Nkansah-Gyekye, 2017 ) for malaria infections and ( Barker & Vaidya, 2020 ; Chen, Cheng, & Rong, 2019 ) for viral infections in the context of environmental transmission. Therefore, the main distinguishing feature for single scale models developed at this scale of organization is that they incorporate multiple microcommunities (i.e.…”
Section: Aims and Assumptions Of The Transmission Mechanism Theorymentioning
confidence: 99%
“…The global exchange of pathogen between organs or microcommunities or microenvironments is usually through the circulatory system or through the lymphatic system. For typical examples of single scale models developed at this scale organization see ( Orwa, Mbogo, & Luboobi, 2018 ; Selemani, Luboobi, & Nkansah-Gyekye, 2017 ) for malaria infections and ( Barker & Vaidya, 2020 ; Chen, Cheng, & Rong, 2019 ) for viral infections in the context of environmental transmission. Therefore, the main distinguishing feature for single scale models developed at this scale of organization is that they incorporate multiple microcommunities (i.e.…”
Section: Aims and Assumptions Of The Transmission Mechanism Theorymentioning
confidence: 99%
“…An in-host P. falciparum malaria model is formulated to study optimal malaria control strategies within the human host. The deterministic model is an extension of the model in ( Orwa et al., 2018a ) and comprises of nine compartments of: (i) sporozoites ( S ), (ii) uninfected hepatocytes ( H ), (iii) infected hepatocytes ( X ), (iv) uninfected red blood cells ( R ), (v) early stage infected red blood cells (blood trophozoites, T ), (vi) mature infected red blood cells (blood schizonts, C ), (vii) merozoites ( M ), (viii) gametocytes ( G ) and (ix) CD8 + T cells ( Z ). The in-host malaria is subjected to a combination of malaria vaccine and anti-malarial drug control strategies.…”
Section: Mathematical Modelmentioning
confidence: 99%
“…The process of verification is however simpler. We can follow the steps as presented in [59, 60]. Let the total erythrocyte population C ( t ) evolve according to the following formulation:dCdtλxμcC,where μ c =min{ μ x , μ ys , μ yr }.…”
Section: Model Analysismentioning
confidence: 99%