Data

To test model predictions we used data on parasite rates (PR) and ITN use for malaria protection (ITNMP) from Aneityum, Vanuatu and Lake Victoria Islands (LVI), Kenya. For the analysis we used (PR) based on blood slide examination, which were about 1/3 of the estimates with a rapid diagnostic test (RDT). Per cent ITNMP was based on ITN self-reported usage by residents, corrected by the percentage of the population covered with ITNs (see Table 1 for further details about coverage, use and PRs using BSE and RDT).

Table 1. Insecticide-treated net (ITN) self-reported use, coverage and malaria parasite rates in Aneytium, Vanuatu and islands (Nghode, Takawiri, Kibougi, Mfangano) in Lake Victoria, Kenya

* All surveys sampled representatively the demographic profile of the islands.

^a The value outside the parentheses is the estimate based on blood slide examination, the value inside the parentheses is the estimate based on a Rapid Diagnostic test (Paracheck-Pf®) and na indicates not available.

^b % population owning a bednet.

^c % population using bednets independent of coverage.

^d Pre-elimination baseline survey.

^e Post-elimination baseline survey.

Ethical approval

This study was approved by the Vanuatu Department of Health, the Scientific Steering Committee and National Ethics Review Committee of the Kenya Medical Research Institute (SSC No. 1310 and 2131), and the ethics review committee of Nagasaki University.

Expected payoff matrix

The expected payoff matrix represents the set of strategies and rewards (commonly referred as payoffs in the game theory literature) that players can employ regarding a behaviour in a game model. In the ITN game, the 2 players have a common set of strategies denoted by T and F, which correspond to ITN malaria protection use and misuse, respectively. Each player chooses a strategy (T or F) based on his/her malaria infection risk, labour productivity, and expected payoff. Thus, the ITN game can have 4 profiles, which result from the combination of the strategies by the 2 players: (T, T), (T, F), (F, T) and (F, F).

The relation between the ITN game profiles and the malaria infection risk can be represented by an infection probability (IP) matrix (Fig. 2A). In this matrix we define an IP P, which can take any value between 0 and 1 (i.e. 1⩾P ⩾ 0). P can be interpreted as the probability of malaria infection by an individual in the setting where she/he resides. To make the connection with epidemiological literature, P could be seen as a function of malaria infection risk factors, i.e. the higher the odds of an individual being infected, the higher the value of P. The use of an ITN by a player is assumed to reduce the individual probability of infection by α ₁, as observed in numerous studies (Howard et al. Reference Howard, Omumbo, Nevill, Some, Donnelly and Snow2000; Hawley et al. Reference Hawley, Phillips-Howard, ter Kuile, Terlouw, Vulule, Ombok, Nahlen, Gimnig, Kariuki, Kolczak and Hightower2003; Lindblade et al. Reference Lindblade, Eisele, Gimnig, Alaii, Odhiambo, ter Kuile, Hawley, Wannemuehler, Phillips-Howard, Rosen, Nahlen, Terlouw, Adazu, Vulule and Slutsker2004; Fegan et al. Reference Fegan, Noor, Akhwale, Cousens and Snow2007), and the use of ITNs by other residents in the community can lead to an emergent ‘community effect’ (Howard et al. Reference Howard, Omumbo, Nevill, Some, Donnelly and Snow2000; Kaneko et al. Reference Kaneko, Taleo, Kalkoa, Yamar, Kobayakawa and Björkman2000; Hawley et al. Reference Hawley, Phillips-Howard, ter Kuile, Terlouw, Vulule, Ombok, Nahlen, Gimnig, Kariuki, Kolczak and Hightower2003; Fegan et al. Reference Fegan, Noor, Akhwale, Cousens and Snow2007; Chaves et al. Reference Chaves, Kaneko, Taleo, Pascual and Wilson2008) that further reduces P by a factor (α ₂) ⁿ , where n is the number of players that use the ITN for malaria prevention. Thus, the ‘community effect’ is null when no players use bednets and the magnitude of its impact increases as more individuals use the ITNs for malaria prevention. The α parameters can take any value above 0 and below 1 (i.e. 0<α _i  < 1, i = 1, 2). We can then define a labour productivity matrix (Fig. 2B) that quantifies the utility of labour in malaria uninfected players, L, and the increased utility β by using bednets for alternative purposes to malaria prevention. Finally, with these two matrices we can define the expected payoff matrix (Fig. 2C) as the product of the probability of not being infected with malaria (1-probability of malaria infection) and the labour utility. The model assumes a perfect knowledge of the costs and benefits for different ITN uses. The 2-player model has the advantage of rendering general results independently of whether the impacts of ITN use for malaria protection are density or frequency dependent, since results for small n are independent of density/frequency-dependent pathogen transmission (Antonovics et al. Reference Antonovics, Iwasa and Hassell1995) and, in general, 2-player games are useful tools to understand the emergence of different behaviours in a population (Smith and Price, Reference Smith and Price1973).

Fig. 2. Deriving an expected payoff matrix for the ITN use game. (A) Infection probability (IP) matrix. P is the malaria infection probability of the players in the absence of ITNs. The parameters α ₁ and α ₂ denote the individual and community effects of ITN use for malaria protection, respectively. To read this and the subsequent matrices the strategy of player 1 is presented in the rows, and of player 2 in the columns. The matrix value for player 1 is the first entry in a given cell. (B) Labour productivity matrix. L is the labour productivity (which can be measured in US $ per capita) of the players without an ITN, L can take any positive value (i.e. L > 0). The parameter β denotes the β-fold increment of L when a player gives an alternative use to his/her ITN, β is assumed to be larger than 1 (i.e. β > 1). (C) Expected payoff matrix. This matrix is the Hadamard product (i.e. matrix-element-wise product) of the complement of the IP matrix (i.e. 1 – IP matrix) and the Labour productivity matrix for each player.

Distribution of Nash equilibria

Nash equilibria are the profiles (combination of player strategies) from which any player has no incentive to deviate, because his/her payoff is maximized in response to the other player strategy (Nash, Reference Nash1950; Smith and Price, Reference Smith and Price1973). Our model has 3 Nash equilibria that were derived by establishing the conditions when given a profile, none of the players can increase his/her payoff by changing his/her strategy. For example, in the case of the profile (T, T), i.e. when both players use their ITNs for malaria prevention we have that (T, T) is a Nash equilibrium when the following inequality holds:

(1) $$(1 - \alpha _1 (\alpha _2 )^2 P)\;L \gt (1 - \alpha _2 P)\;\beta L.$$

This implies a higher payoff for any player if he/she uses the ITN for malaria prevention than if he/she chooses to profit from an alternative ITN use. Here it is worth highlighting that payoffs are independent of labour productivity (L), which cancels out on both sides of Equation (1). Nevertheless, payoffs are proportional to the increase (β) of L by the alternative ITN use. From expression (1) a threshold for IP (P _R ) can be derived which ensures that both players will use their ITNs for malaria prevention when P > P _R :

(2) $$P_R = \displaystyle{{\beta {\rm -} 1} \over {\alpha _2 (\beta {\rm -} \alpha _1 \alpha _2 )}}.$$

Following a similar procedure, P _L , an IP threshold where (F, F), both players giving alternative uses to their ITNs, is a Nash Equilibrium when P < P _L , can be derived:

(3) $$P_L = \alpha _2 P_R .$$

Finally, the profiles (T, F) and (F, T) are Nash equilibria when P follows the following condition:

(4) $$P_L \leqslant P \leqslant P_R .$$

Equation (4) implies the emergence of ‘free rider’ Nash equilibria, where a player with the strategy F benefits from the alternative use of his/her ITN and from the ‘community effect’ in malaria protection that emerges by the use of ITNs for malaria prevention by a player with the strategy T.

Distribution of Pareto equilibria

A Pareto equilibrium is a combination of player payoffs that is efficient for the public welfare (Karlin, Reference Karlin1959), in the context of this study meaning it conduces to a reduction of malaria infection risk in a community. To find the Pareto equilibria we solved several inequalities comparing the different profiles of the ITN game (see Supplementary material, online version only, for a detailed and mathematically rigorous derivation). Our analysis showed the Nash equilibria to be Pareto efficient with the exception of the equilibria for the profile (F, F), where a region with a social dilemma (SD), i.e. where the whole community benefits by a player changing his/her strategy, emerges when:

(5) $$P_L^{\hskip1.3pt*} = \displaystyle{{\beta - 1} \over {\beta - \alpha _1 \alpha _2^2 }}.$$

By definition, P _L ^* < P _L , is the difference between these two thresholds defining the range of malaria infection probability over which a SD emerges, and is expected to be wider as the number of players increases in a community (Nash, Reference Nash1950).

Model implications

Our model can be used to illustrate the influence of many factors that may underpin patterns of ITN misuse. Malaria is a disease entrenched among the poorest nations in the globe (Chaves and Koenraadt, Reference Chaves and Koenraadt2010) and the alternative use of ITNs could represent a significant increase in a household income. Figure 3A illustrates how the range of malaria infection probability (P) where all players prefer to use ITNs for purposes other than malaria protection doubles its width when a 20% increase in the player income is derived by an alternative ITN use, a figure that may be realistic for the poorest of the poor in many developing nations. This is the case even when assuming that ITN use reduces by 40% (i.e. α ₁ = 0·60, e.g. see Killeen et al. (Reference Killeen, Smith, Ferguson, Mshinda, Abdulla, Lengeler and Kachur2007)) the probability of malaria infection, a value within the range of observed outcomes for ITN trials (Lindblade et al. Reference Lindblade, Eisele, Gimnig, Alaii, Odhiambo, ter Kuile, Hawley, Wannemuehler, Phillips-Howard, Rosen, Nahlen, Terlouw, Adazu, Vulule and Slutsker2004). The free-rider behaviour is expected to become increasingly common as the ‘community effect’ increases (Fig. 3B and C), in an exacerbated manner as the protection level by individual ITN use diminishes (i.e. α ₁ increasing towards 1, Fig. 3C).

Fig. 3. Pareto efficient Nash equilibria (PNE) and Social Dilemma (SD). (A) Equilibria as function of the infection probability, P, the top panel illustrates a case where profitability for alternative ITN use is low (income increases by 10%, i.e. β = 1·1), the bottom panel represents a case of higher profitability for the alternative bednet use (income increases by 30%, i.e. β = 1·3). In the two panels the thresholds P _R , P_L and P _L ^* are indicated (see the main text for an explanation of the thresholds). The legend in panel B applies to panels A, B and C: All-T (All-F) are the equilibria where all players (do not) use the ITN for malaria protection, FR are the free-rider equilibria. (B) Equilibria as function of P and individual bednet protection (α ₁) in a setting with a low level of additional protection via a ‘community effect’ (5% i.e. α ₂ = 0·95). (C) Equilibria as function of P and individual bednet protection (α ₁) in a setting with a high level of additional malaria protection via a community effect (20%, i.e. α ₂ = 0·80).

ITN use and parasite rates (PR) in Vanuatu and Kenya islands, do they follow the model?

Table 1 shows data from malaria surveys made before (PRE) and after (POST) the 1991 elimination intervention, and 2010, in Aneityum (a Vanuatu island) and from 2012 in several LVI (Ngodhe, Takawiri, Kibuogi, Mfangano). In Aneityum, before the 1991 elimination trial, PR was slightly above 20% and ITN coverage was null (Table 1). As part of the elimination trial coverage was raised to 94% and use was around 90% (Kaneko et al. Reference Kaneko, Taleo, Kalkoa, Yamar, Kobayakawa and Björkman2000), and currently coverage is 100% with 97% use. In Vanuatu, current levels of use are in accordance with equation (2) when the parameter β → 1, i.e. when there is no significant increase of labour productivity by an alternative ITN use and with a transmission close to 0 all players will use the ITN for malaria protection (i.e. P _R → 0). Nevertheless, our model fails to explain the patterns observed in Vanuatu under the assumption of β > 1. The situation in LVI reflects a higher coverage and use of ITNs than that observed in Aneityum prior to the elimination trials (Table 1), yet misuse may be higher, since around 20% of the ITNs are not being used for malaria protection (Table 1), and only around 50% of the population use ITNs for malaria protection. ITN use patterns in LVI resemble our model predictions when β > 1.