Individuals are born nonimmune and experience a cycle of infection, treatment or clearance of parasites, and short-lived immunity immediately following an episode, until graduating to a semi-immune state. Semi-immune individuals experience the same cycle, but with a higher probability of carrying an asymptomatic infection and a longer interval between each infection. The graduation from nonimmune to semi-immune depends, at least in part, on the number of attacks, and thus on the frequency of infectious bites. Intervention strategies, such as chemoprophylaxis and IPTi, may be applied differentially to different age groups (or, here, groups with different immune status).

Specifically, infants are born susceptible (compartment S) to malaria infection at a constant rate (μ), and there is a constant death rate from each compartment ( μX, where X = S, A, P, and the other compartments [ Table 1]). The rate at which infectious mosquitoes bite humans is known as the entomological inoculation rate (Λ). A fraction (λ) of susceptible nonimmunes who are bitten will become symptomatic and have a probability (p) of being treated. Symptomatic treated individuals are designated by D. The remaining infected individuals are untreated, designated by A, and include those who are asymptomatic as well as those with symptomatic infections that will go untreated. Some of the untreated individuals will later become symptomatic, either by receiving a new infectious bite (dΛ) or due to other precipitating factors (ν), and have a probability (p) of being treated. In the treated, symptomatic individuals (D), the waiting time between the onset of symptoms and the time when the drug titer becomes high enough to clear the infection is 1/ a d, at which point they enter a new class T ₁. Over a period of 1/ r ₁ d, which is determined by the pharmacokinetic properties of the drug, the drug concentration declines to a level permissive to partially resistant parasites (T ₁′). The drug concentration falls to zero over an additional period of 1/ r ₂ d. After a treated clinical attack, antimalarial immunity (P) develops and provides protection from a new infection for 1/ w d. Thus, the concentration of drug in the blood following treatment declines as a stepwise process until all of the drug is cleared (D → T ₁ → T ₁′ → P). Untreated asymptomatic and symptomatic infections (A) are either cleared quickly and spontaneously with no subsequent protection (σ) or they are cleared more slowly by immune mechanisms (g) resulting in protection from reinfection (P) for 1/ w d.

Susceptible, nonimmune individuals (S) , those with untreated infections (A), and those with immune protection (P) may undergo periodic drug dosing during IPTi at a rate, c, and they progress through a stepwise decay of blood drug concentration similar to those treated for symptoms. A dose of antimalarial drug during IPTi clears any existing, asymptomatic, drug-sensitive infection and prevents reinfection by partially or fully sensitive parasites for a period of 1/ r ₁ d. Between 1/ r ₁ and 1/ r ₁ + 1/ r ₂ d, the drug concentration drops to a level that is still active against fully sensitive parasites, but is permissive for infection by partially resistant parasites (i.e., T _x → T _x′, where x = 1, 2, 3, a). Susceptible nonimmunes (S) become treated nonimmunes (T ₂) after a dose of drug during IPTi, then decay to a level of lower protection (T ₂′), and then return to the susceptible class (S → T ₂ → T ₂′ → S). Those with untreated infections (A) who are treated through IPTi (T ₃) become partially protected (T ₃′), and have a probability (b) of acquiring immune protection as a result of the infection (A → T ₃ → T ₃′ → S or A → T ₃ → T ₃′ → P). Immune-protected individuals (P) may also be treated through IPTi, but IPTi does not affect the development or loss of immunity. We assume that nonimmunes who arrive for IPT treatments with clinical symptoms of malaria are diagnosed and treated (D). Semi-immune status is acquired with some probability after clearing an infection, at a rate that is proportional to entomological inoculation rate (EIR) (γΛ). Immunity to reinfection (P _a) persists for a period of 1/ w′ d, after which susceptibility (S _a) to infection returns. A greater proportion (1 − λ′) of those who are infected maintain an asymptomatic infection or develop symptoms but go untreated (A _a), but a small fraction ( λ′) become ill and have a probability (p) of being treated (D _a) with an antimalarial drug. Treatment leads to parasite clearance and a gradual decline of drug titers, as described above (T _a → T _a′). Asymptomatic, infected individuals may become ill for various reasons ( ν′), but not due to superinfection, and have a probability (p) of being treated for malaria.

Drug-sensitive parasites (RS) can infect susceptible hosts (S, S _a), and a proportion (q) of untreated, infected hosts (A, A _a). Partially resistant parasites (R1) can infect these hosts, and also those who have been treated and whose drug titer has declined, but not hosts whose immune responses have been stimulated by an infection immediately prior to or concurrent with treatment ( Figures 1 and and2).2). For example, they cannot infect T ₁ or T ₁′, because these treated hosts are developing a temporary immune-protected state (P, P _a): their heightened immune state will temporarily protect them as the drug protection wanes. Fully resistant parasites (R2) can infect untreated hosts and any who have been treated, regardless of the drug titer, but not hosts whose immune systems are stimulated by a concurrent infection (as described for R1 above).Thus, the model assumes a degree of superinfection—a single host can harbor mixtures of parasites (RS, R1, R2), restricted only by the concentration of drug in the blood. However, in accord with common practice [ 11, 22, 23], we neglected intrahost dynamics and assumed independence of genetically distinct coinfecting parasites.

The lifetime of an infection is either the inverse of the rate at which the parasites are cleared by the immune system (1/ g) or the rate at which they are cleared by the drug (1/ a) following treatment. The average lifetime of an infection in a host population () is the average of the lifetime of an infection in nonimmunes and the average lifetime in semi-immunes weighted by the proportion of infections that occur in each ( Equation 1C). The lifetime of an infection in nonimmunes ( _NI) is equal to the fraction of infections that are treated multiplied by the rate of clearance by drug treatment plus the fraction of infections that are not treated multiplied by the rate of clearance by immune mechanisms ( Equation 1A). A similar formula ( Equation 1B) describes the lifetime of an infection in semi-immune individuals ( _SI).

The lifetime of a fully resistant infection is always equal to the length of time required for the immune system to clear the infection (1/ g).

The relative fitness (F) is defined here as the ratio of the more resistant parasite type over the more sensitive type:

(It is interesting to note that Equation 3 is identical in structure to Equation 5 in [ 24], where d _r represents the hosts with residual drug [= T ₃′ + (1 − b) T ₂′], and d _s represents the host with no residual drug [= S + qA + S _a + qA _a]. Although these equations were arrived at by different methods, and the variables S, A, T ₃, etc… in our model reflect changes in the underlying epidemiology, the qualitative results from the two approaches are similar.)

The fitness ratio will always be greater than or equal to one. We assumed that there is no significant cost of resistance. If the fitness ratio is greater than one, then the more resistant parasites have a competitive advantage over, or a greater fitness than, the more sensitive parasites. Assuming that sensitive parasites are initially established in the host population and a small fraction of resistant parasites arise, the fitness ratio minus one gives the fraction of spread of the more resistant parasites per generation. The quantity multiplied by 100 gives the percent of spread per parasite generation.

Author contributions. WPO, DLS, and FEM designed the study. WPO analyzed the data. WPO, DLS, and FEM contributed to writing the paper.