TY - JOUR
T1 - Antibody Dynamics for Plasmodium vivax Malaria
T2 - A Mathematical Model
AU - Mehra, Somya
AU - McCaw, James M.
AU - Flegg, Mark B.
AU - Taylor, Peter G.
AU - Flegg, Jennifer A.
N1 - Funding Information:
S. Mehra acknowledges funding from the Australian Mathematical Sciences Institute (AMSI) Vacation Research Scholarships 2018/2019. J.M. McCaw’s research is supported by the Australian Research Council (ARC) Discovery Project DP170103076. J.A. Flegg’s research is supported by the ARC DECRA Fellowship DE160100227. P.G. Taylor’s research is supported by the ARC Laureate Fellowship FL130100039 and the ARC Centre of Excellence for the Mathematical and Statistical Frontiers (ACEMS).
Publisher Copyright:
© 2021, Society for Mathematical Biology.
Copyright:
Copyright 2021 Elsevier B.V., All rights reserved.
PY - 2021/1
Y1 - 2021/1
N2 - Malaria is a mosquito-borne disease that, despite intensive control and mitigation initiatives, continues to pose an enormous public health burden. Plasmodium vivax is one of the principal causes of malaria in humans. Antibodies, which play a fundamental role in the host response to P. vivax, are acquired through exposure to the parasite. Here, we introduce a stochastic, within-host model of antibody responses to P. vivax for an individual in a general transmission setting. We begin by developing an epidemiological framework accounting for P. vivax infections resulting from new mosquito bites (primary infections), as well as the activation of dormant-liver stages known as hypnozoites (relapses). By constructing an infinite server queue, we obtain analytic results for the distribution of relapses in a general transmission setting. We then consider a simple model of antibody kinetics, whereby antibodies are boosted with each infection, but are subject to decay over time. By embedding this model for antibody kinetics in the epidemiological framework using a generalised shot noise process, we derive analytic expressions governing the distribution of antibody levels for a single individual in a general transmission setting. Our work provides a means to explore exposure-dependent antibody dynamics for P. vivax, with the potential to address key questions in the context of serological surveillance and acquired immunity.
AB - Malaria is a mosquito-borne disease that, despite intensive control and mitigation initiatives, continues to pose an enormous public health burden. Plasmodium vivax is one of the principal causes of malaria in humans. Antibodies, which play a fundamental role in the host response to P. vivax, are acquired through exposure to the parasite. Here, we introduce a stochastic, within-host model of antibody responses to P. vivax for an individual in a general transmission setting. We begin by developing an epidemiological framework accounting for P. vivax infections resulting from new mosquito bites (primary infections), as well as the activation of dormant-liver stages known as hypnozoites (relapses). By constructing an infinite server queue, we obtain analytic results for the distribution of relapses in a general transmission setting. We then consider a simple model of antibody kinetics, whereby antibodies are boosted with each infection, but are subject to decay over time. By embedding this model for antibody kinetics in the epidemiological framework using a generalised shot noise process, we derive analytic expressions governing the distribution of antibody levels for a single individual in a general transmission setting. Our work provides a means to explore exposure-dependent antibody dynamics for P. vivax, with the potential to address key questions in the context of serological surveillance and acquired immunity.
KW - Antibody dynamics
KW - Infinite server queue
KW - Relapse
KW - Shot noise process
KW - Vivax malaria
UR - http://www.scopus.com/inward/record.url?scp=85098652674&partnerID=8YFLogxK
U2 - 10.1007/s11538-020-00837-5
DO - 10.1007/s11538-020-00837-5
M3 - Article
C2 - 33387082
AN - SCOPUS:85098652674
SN - 0092-8240
VL - 83
JO - Bulletin of Mathematical Biology
JF - Bulletin of Mathematical Biology
IS - 1
M1 - 6
ER -