Larval habitat characteristics of the main malaria vectors in the most endemic regions of Colombia: potential implications for larval control

The study took place in three of the states with the highest malaria transmission in Colombia: Córdoba (northwestern region of the country), Nariño and Valle del Cauca (both in the western region on the Pacific coast). In general, all areas follow an endemic-epidemic [25] and perennial pattern of transmission [26]. Between them a distinctive predominance of Plasmodium species is found. In Córdoba, 70 % of malaria infections are caused by Plasmodium vivax and 30 % by Plasmodium falciparum, while on the Pacific coast, the P. vivax/P. falciparum ratio is reversed with P. falciparum as the predominant parasite [25]. In total, 70 localities were selected for a cross-sectional study: 27 in Cordoba, 21 in Valle del Cauca and 22 in Nariño. The selection criteria included localities with high malaria incidence, easy access by land or river, and safety (Fig. 1).

The localities selected in Córdoba are in an area with northern latitudes between 07°53′53″ and 08°15′41″, and western longitudes between 75°25′30″ and 76°08′49″. Most of the localities are hilly. The annual average rainfall is between 1525 and 2333 mm and the annual average temperature between 26.4 and 28 °C depending on the altitude. The most important economic activities are based on livestock, agriculture (mainly maize, cassava, sorghum, rice, banana crops), forestry, and mining of gold and silver [27]. The localities selected in Nariño and Valle del Cauca are located in an area with northern latitudes between 01°47′55″ and 03°53′36″ and western longitudes between 77°04′11″ and 78°48′56″. Most of the localities are flat to slightly undulating. The annual average rainfall is between 2,191 and 6,980 mm and the annual average temperature between 25.8 and 27 °C. The most important economic activities are based on fishing, with some mining and agriculture (mainly banana, blackberry, cocoa, other local fruits) [27].

Larval specimen collections were carried out in each of the 70 localities with data collection between May 2011 and November 2012. Each locality was visited for 1 week each during which all potential larval habitats present within a 1-km radius of the houses were sampled once for anopheline larvae between the hours of 08:00 and 12:00. The larval habitats were characterized and classified according to their distance to the nearest house, stability (temporary or permanent habitats), presence of vegetation, water flow (stagnant water or with movement), water clarity (clear or turbid), use (drainage, swimming pool, animal, domestic, none) and type defined as excavation site (a hole made by removing material), fishpond (pond or artificial lake used for fish farming), lagoon (a body of fresh water of considerable size, surrounded by land), stream (a body of water flowing in a channel, as a brook), puddle (a small pool of water, as of rainwater on the ground), ditch (a long, narrow channel dug in the ground, such as for drainage or irrigation, trench), bromeliad (epiphytic tropical American plants, having long, stiff leaves and showy flowers) or other.

In each potential habitat larval sampling was done using the standard dipping method with a 400-ml ladle with ten samples per sq m [28]. Collected larvae were maintained for linked rearing and the larval and pupal skins kept for taxonomic determination [29]. A portion of the late instars were immediately preserved in 70 % ethanol and taken to the Medical Entomology Laboratory of the Instituto Nacional de Salud of Colombia in Bogota. Species of mosquito larvae were determined using the most recent Colombian morphological Anopheles key [30].

In order to analyse the stability of the different types of positive larval habitats for Anopheles larvae by state, contrast homogeneity was performed on qualitative variables using RWizard 1.0 (R 3.1.2, The R Project for Statistical Computing). A multiple correspondence analysis (MCA) was used (using R software version 3.2.0, packages ade4 and FactoMineR) to describe the main characteristics associated with each Anopheles species larval habitats. The categorical variables included were: stability, type, presence of vegetation, water flow, clarity of water, and use. The Fager’s affinity index (IFM) [31] was calculated to determine the association between the different anopheline species occurring in the same breeding site according to the following expression: IFM: J/√N_AN_B − 1/2√N_B, where J is the number of co-occurrences, N_A is the total number of occurrences of species A alone, N_B is the total number of occurrences of species B alone and species are chosen such that N_A ≤ N_B. The resulting value provides a quantitative measure of species association. A value ≥0.5 is indicative of affinity. To analyse the interactions between Anopheles species and larval habitats, networks of interaction were constructed using the R statistical software (R Development Core Team 2007). In this model, the abundance and diversity of species by larval habitat were evaluated. Shannon’s diversity index (H′) was used to characterize species diversity in each state to show the abundance and evenness of the species present in the different larval habitats according to the following expression: H′: Σ((Pi) × Ln(Pi)), where Pi is number of individuals of species/total number of samples [32]. Analysis of variance (ANOVA) was used to evaluated the distance between the inspected and positive sites and the nearest houses for each area of study.