Models of Acquired Immunity to Malaria: A Review
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man population. The model demonstrates the impact of NAI on malaria prevalence in two
Niger villages that are entomologically and hydrologically disparate. The model suggests
that the NAI depends on hydrologically driven mosquito abundance over previous years.
Thus, greater acquired immunity is obtainable in the wet village due to more mosquito
bites as compared with the dry village. However, the model also shows how NAI dampens
the effect of increased biting, since without the effects of immunity, the wet village would
have much higher prevalence than the dry village.
5.2.9.3
Effect of population dynamics on immunity acquisition
The assumption of maintaining a constant population size, made in most models for
simplicity, needs to be addressed since it’s unclear if it matters or not, even though it seems
to be artificial. It is known that human population is characterized by birth, mortality and
immigration. Some modelers believe that the consideration of these factors in the mod-
els entails a more realistic modeling of the acquisition of immunity with time since for
instance, malaria is an endemic disease which has a high mortality rate [72], [46], [48],
[109]. Moreover, the interaction between the vector and human populations instigates a
considerable level of variability on especially the mosquito populations for which the as-
sumption of constant population may not be realistic [46].
Ngwa and Shu [46] developed a SEIR model which assumes density dependent death
rates in both the human and mosquito populations, with the total populations varying with
time. Chitnis [49], [48] on the other hand, developed a model with constant immigration
for the Susceptible class such that people enter the latter class either by birth or through
immigration. To account for population dynamics, age-specific fertility and mortality rates
are calculated for each individual and an additional mortality component, specific for each
individual (such as malarial related death), is incorporated in an individual-based malaria
risk assessment model [109]. The model demonstrated the creation of individual disease
history (immunity, infectedness and illness) depending on their circulation behavior (e.g
going to work, traveling) and residence over a given period of time. The model in[103]
includes the variability of both the human and mosquito population; the former, through
yearly census and the later, either measured directly through landing catches or estimated
based on the variability in meteorological conditions (rainfall and temperature).
Some of these models produced results which show the impact of including demo-
graphic effects in predicting the rate of fatalities that could arise from the disease. Incor-
porating population variability of humans might seem pointless in cases where the quan-
titative influence of human population growth is small enough to neglect and deserves far
less attention. However, most models considered mostly the human population dynamics
with little emphasis on the dynamics of the vector population [109], [110] which is the
major driver of malaria transmission. The emphasis on the mosquito population dynamics
dates back from the work of Ross [95]. His work suggests that if the vector population can
be reduced to below a certain threshold, then malaria can be successfully eradicated. This
threshold is typically dependent on biological factors such as the biting rate and vectorial
capacity Table (5.2) which solely depends on the vector population dynamics. In [40], the