“…To illustrate our findings, in section 2, several predator-prey models available in the literature, satisfying our assumptions, are considered and thresholds conditions for the corresponding eco-epidemiological model automatically obtained from our results: in our Example 1, we consider the situation where f ≡ 0 in system (1), corresponding to a generalized version of the situation studied in [12]; in Example 2, we obtain a particular form for the threshold conditions in the context of periodic models and particularize our result for a model constructed from the predator-prey model in [5]; in Example 3, we start with an uninfected subsystem with Gausetype interaction (a predator-prey model with Holling type II functional response of predator to prey, logistic growth of prey in the absence of predators and exponential extinction of predator in the absence of prey) and, using [10], obtain the corresponding results for the eco-epidemiological model; in Example 4, we consider the eco-epidemiological model obtained from an uninfected subsystem with ratiodependent functional response of predator to prey, a type interaction considered as an attempt to overcome some know biological paradoxes observed in models with Gause-type interaction and again obtain the corresponding results for the ecoepidemiological model, based on the discussion of ratio-dependent predator-prey systems in [7]; finally, in Examples 5 and 6, we consider eco-epidemiological models, based on the discussion of the corresponding predator-prey models in [14,16] where the uninfected subsystem has some specific type of non-autonomy in the prey equation (Example 5) or the predator equation (Example 6). For all these examples we present some simulation that corroborate our conclusions.…”