Where Have All the Parasites Gone? Modelling Early Malaria Parasite Sequestration Dynamics

Deborah Cromer,Ashraful Haque,Miles Davenport,Christian Engwerda,Shannon E Best,Claudio Romero Farias Marinho

doi:10.1371/journal.pone.0055961

Deborah Cromer, Ashraful Haque + Show 4 more

Open Access

https://doi.org/10.1371/journal.pone.0055961

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Journal: PloS one	Publication Date: Feb 18, 2013
Citations: 39	License type: CC BY 4.0

Affiliation: UNSW Sydney, QIMR Berghofer Medical Research Institute

Abstract

Traditional approaches to measuring the level of malaria infection involve counting the proportion of parasite-infected red blood cells (iRBC) in circulating blood, known as parasitaemia. However, iRBC can also accumulate within the microvasculature of tissues and organs, a process called sequestration. Thus measurements of parasitemia do not necessarily reflect the total parasite burden (TPB). Recent experimental advances have allowed TPB measurements to be made in humans and experimental models. TPB is particularly important because it is the best current predictor of malaria disease severity and death in humans. Understanding the relationship between freely circulating iRBC versus tissue-sequestered iRBC is an important question in infection dynamics. The recent ability to experimentally measure the dynamics of iRBC in blood and tissue during murine malaria provides an exciting potential window into sequestration, but new modeling approaches are clearly required to understand these interactions. We present a model of malaria dynamics during early infection that incorporates iRBC that both circulate in the blood and sequester in tissue microvasculature. We explore the effect that perturbations to the system have on the ratio of the number of iRBC between these compartments, and consider which changes are most consistent with experimental data from mice. Using this model we predict an increase in the clearance rate of sequestered iRBCs around the time when mild symptoms become apparent, but a more pronounced increase in the rate of sequestration of iRBCs associated with the onset of severe malaria symptoms.

Highlights

The term ‘‘severe malaria’’ encompasses a wide spectrum of syndromes, including severe anaemia, hyper-parasitaemia, acute respiratory distress, clinical jaundice, and cerebral malaria (CM) [1]
The growth rate of parasitaemia slows throughout the infection, while the growth rate of total parasite burden (TPB) slows between day 4 and 5, causing a transient decrease in the ratio between TPB and parasitaemia (Figure 2C) but increases again between days 5 and 6, causing a large increase in the ratio
There is no significant difference between the growth rate of parasitaemia and that of TPB from day 3 to 4 or from day 4 to day 5 (p.0.19), there is a significant difference between the growth rate of parasitaemia and that of TPB from day 5 to 6 (p = 661026)

Summary

Introduction

The term ‘‘severe malaria’’ encompasses a wide spectrum of syndromes, including severe anaemia, hyper-parasitaemia, acute respiratory distress, clinical jaundice, and cerebral malaria (CM) [1]. Severe malaria syndromes account for ,900,000 deaths annually, with the majority of these caused by CM [1]. A general feature of severe malaria syndromes including CM is that the estimated total number of iRBC in the body (or Total Parasite Burden: TPB) is significantly higher than in patients suffering uncomplicated malaria [4]. Parasitaemia, a measure of iRBC circulating in the bloodstream is less reliable at differentiating patients with severe and uncomplicated malaria [4]. One hypothesis drawn from these observations in humans is that iRBC within host tissues play an important role in mediating severe disease symptoms during malaria

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