Most large urban areas in the intertropical zone have high population growth rates. In addition, rural populations are increasingly migrating to the cities to meet better living conditions. We are thus witnessing the emergence of working-class neighborhoods, non-urbanized outskirts, or the creation of slums in which sanitation infrastructure is deficient or even absent
[1]
-
[3]
. This has significant repercussions on the hygiene and health of populations
[4]
. Indeed, this results in the development of sewage collection which constitutes breeding grounds for disease-carrying mosquitoes
[5]
-
[7]
. These urban areas will therefore have to deal with the emergence or resurgence of certain transmissible and non-transmissible diseases, linked in particular to the urban lifestyle
[8]
. Like most African cities, Burkina Faso’s towns have the same characteristics
[9]
. Indeed, the urban bangs of Burkina Faso’s cities are dominated by vast areas of settlement described as illegal, spontaneous, informal, or, more commonly, “non-housed”, which are at once considered part of the city but present a habitat close to rural habitat
[10]
. In addition, these peripheral areas, most often built on the bangs of the formal and legal urbanization process, are not counted as urban areas but are generally home to the majority of urban populations
[11]
. These populations lead a lifestyle that straddles the gap between their village of origin and the city, taking advantage of the informal nature of their area to carry out activities that are forbidden in urban environments, notably arable farming, gardening, and livestock breeding
[10]
. This lifestyle creates favorable habitats for the development of mosquitoes
[12]
. Indeed, it is common to find in this city collections of stagnant wastewater, generated and maintained by human practices of water use, among other things badly cleaned gutters, open catch basins or simply closed by a sheet of metal
[13]
[14]
. These stationary wastewater collections are the main source of mosquitoes that carry several pathogens, thus constituting a major public health problem
[15]
. Some species of mosquitoes have adapted to urban environments and preferentially lay their eggs in wastewater
[3]
[16]
. This makes vector control ineffective despite the efforts of various control programs. For more than a decade, Burkina Faso has been subject to Dengue epidemics, especially in its capital
[8]
[17]
and recent studies have shown that malaria in urban areas is a reality
[13]
[14]
. Knowledge of the ecological characteristics of mosquito breeding sites in such a context would be a key element in the implementation of effective vector-borne disease control strategies and measures. This study aims to characterize mosquito breeding sites in the city of Ouagadougou, to improve strategies for the control and prevention of these infections.
2. Materials and Methods2.1. Study Site
Our study was conducted from September to November 2020 in the city of Ouagadougou, Burkina Faso. It is located in the center of the country between 12˚21'58" North and 1˚31'05" West. The city extends into the Nakanbe basin and belongs to the north Soudanian zone. It harbors many rainfed reservoirs and diverse channels, most often poorly maintained which lead water to these reservoirs. These lotic water bodies promote the proliferation of mosquitoes. In addition, the appearance of slums, non-urbanized peripheral areas, and shanty towns in which sanitation infrastructures are deficient or even absent increased mosquito development. The city has a tropical savannah climate with two seasons, a rainy season from June to October and a dry season between November and May. Rainfall ranges from 750 to 900 mm per year. The average annual temperature is 33˚C. Three localities in the city were chosen for the collection of mosquito larvae, taking into account their socio-demographic characteristics and their geographical location. These were the districts of Dapoya, Zongo, and Yamtenga. Dapoya is one of Ouagadougou’s formerly urbanized districts. It’s a densely populated district in the center of Ouagadougou. It is characterized by a large number of households made up of modern houses built close together. Yamtenga is located to the east of the city. It is one of the new outlying districts. Yamtenga is characterized by dispersed houses, mostly built of banco. The Zongo district is a former peripheral neighborhood located to the west of the city. It is characterized by condensed houses made of mixed construction materials (
Figure 1
).
Figure 1. Map of Ouagadougou showing the sampling site.
2.2. Breeding Habitat Characterization
To characterize the breeding habitat, a collection sheet was drawn up. It includes the nature of the breeding habitat, its position, its physicochemical parameters, and also its climatic data. The position of the habitat was defined according to whether it was located inside or outside a human habitat. The geographical coordinates of each habitat were taken by GPS. The physicochemical parameters of the habitat were measured in the field using a multi-parameter before the larvae were collected.
2.3. Mosquito Larvae Sampling and Identification
Larvae were collected inside the concessions, particularly in artificial breeding sites (tyres, canaries, etc.) and outside in natural breeding sites (puddles, temporary pools, etc.) scattered around the various study sites. A distance of thirty (30) metres was maintained between the natural breeding sites. All breeding sites were surveyed for the presence of mosquito larvae. If larvae were present in the natural breeding sites, approximately 500 ml of water containing larvae was collected using a ladle and filtered through a 60 µm sieve. The larvae retained were transferred, using a funnel, into containers on which we placed labels bearing the type of site, the site number, the locality, the name of the collector and the date of collection. For sites consisting of small containers (generally artificial breeding sites where there is not much water), the larvae were transferred directly into the boxes. The samples were then taken back to the laboratory for sorting and rearing. A consent form is read and signed beforehand by the head of the family or by his or her guarantor if he or she agrees to the collections (for breeding sites located inside concessions).
Once in the laboratory, the larvae were first reared to adulthood for better identification. The adult mosquitoes emerging from the larvae were then put to sleep in a freezer, identified, and preserved in tubes containing a desiccant (1.5 mL Eppendorf tubes for small numbers and 15 mL Falcone tubes for large numbers of individuals). Mosquitoes were identified using the morphological identification keys of Gillies and De Meillon (1968); Gillies and Coetzee (1987); and Huang (2004).
2.4. Statistic Analysis
The data collected in the field were entered by Excel 2013 software. Statistical tests and graphs were performed by using the software “R” version R-4.1.1. Boxplots were used to visualize variations in physico-chemical parameters in the gites. The Kruskal-Wallis test was used to compare the mosquito populations in the different sites and habitat types with a significance level of 5%. We produced boxplots to show the variations in physicochemical parameters depending on the type of breeding site. An RDA was also performed to assess the effect of physico-chemical parameters on the collected mosquito populations by combining physicochemical variables with biological data.
3. Results3.1. Typologies of Breeding Sites
A total of 83 positive larval sites were encountered during our study. These breeding sites included artificial breeding sites consisting of old abandoned objects (watering cans, motorcycle helmets, cradles, buckets, car tires, canaries, metal, and plastic cans) and natural breeding sites (puddles and temporary pools) (
Figure 2
and
Figure 3
).
3.2. Categories and Nature of the of Breeding Sites
The different breeding sites were classified into artificial and natural breeding sites. The majority of the breeding sites studied were artificial (n = 62; 75%). These habitats were dominated by plastic materials (n = 32; 39%), followed by ceramic materials (n = 19; 23%). The breeding sites composed of metallic materials were less represented (n = 11; 13%). Natural habitats accounted for 25% (n = 21) and were dominated by the puddle. The temporary ponds were 03 in number. The majority of these breeding sites were found in Zongo (n = 34; 41%) followed by Yamtenga (n = 23; 34%) and Dapoya (21; 25%). In terms of diversity, Yamtenga brought together the greatest number of types of breeding sites.
Table 1
summarizes the categories and types of larval breeding sites encountered.
<xref ref-type="bibr" rid="scirp.134811-"></xref>Table 1. The abundance of breeding sites according to the categories, nature, and locality.
In general, there is a significant difference between the values of physicochemical parameters according to the types of sites. Thus, the median value of pH is higher in ceramic containers and lower in plastic containers. The median water temperature value is higher in puddles and lower in ceramic containers. As for conductivity and turbidity, the median values are higher in the puddles and lower in the ceramic containers.
In general, there is a significant difference between the values of the physicochemical parameters depending on the type of site. For example, the median pH value was higher in ceramic containers and lower in plastic containers (0.019). The median water temperature was higher in the ponds and lower in the ceramic containers (p = 0.023). As for conductivity and turbidity, the median values were higher in the puddles and lower in the ceramic containers (0.019) (
Figure 4
).
Figure 4. Variation of physicochemical parameters according to the nature of the deposits. Tir: Tires; Cer: Ceramics; MC: Metal Conteners; PC: Plastics Conteners; Pdle: Puddle; Pds: Ponds.
3.4. Mosquito Population Composition According to the Type and Category of Breeding Sites
A total of 8352 mosquitoes belonging to four genera and 06 species were collected from these different localities. The genus Aedes was the most dominant with a population of 5967 specimens. It is represented by 02 species namely Aedes aegypti and Aedes albopictus. Followed by the genus Culex represented by the species Culex quinquefasciatus with a population of 1373 specimens; the species Anopheles gambiae and Anopheles funestus are the species representing the genus Anopheles with 1009 individuals. The genus Mansonia is represented by the species Mansonia africana with only 03 specimens. The majority of larvae were collected in artificial breeding sites (75%) and only 25% in natural breeding sites (
Table 2
).
<xref ref-type="bibr" rid="scirp.134811-"></xref>Table 2. Abundance and diversity of mosquitoes according to the Category and the type of breeding sites.
Type of breeding sites
Ae.
aegypti
Ae. albopictus
An.
gambiae
An. funestus
Cx. quinquefasciatus
M. africana
Watering can
19
22
0
0
4
0
Metal box
372
0
10
0
0
0
Motorbike helmet
78
0
0
0
0
0
Aliminum dish
30
0
0
0
0
0
Metal dish
330
0
0
0
0
0
Metal bucket
132
0
0
0
6
0
Total in the metal breeding sites (1.003)
Plastic dish
57
0
0
0
0
0
Battery
96
0
0
0
0
0
Cradle
445
0
0
0
0
0
Can
273
0
0
0
15
0
Plastic box
13
0
0
0
0
0
Bouillard
45
0
0
0
0
0
Tires
1367
33
1
0
121
1
Plastic bucket
178
15
0
0
118
0
Total in the plastic breeding sites (2778)
Ceramics
2260
93
2
0
94
0
Total in ceramic breeding sites (2449)
Duck basins
30
0
0
0
0
0
Puddle
37
0
798
4
1014
2
Ponds
42
0
194
0
1
0
Total in natural breeding sites (2122)
3.5. Mosquito Population Composition According to the Locality
In terms of abundance by locality, the mosquitoes collected were distributed as follows, 3199 mosquitoes collected in Zongo, 2604 in Dapoya and 2549 in Yamtenga (
Table 3
).
<xref ref-type="bibr" rid="scirp.134811-"></xref>Table 3. Abundance and diversity of mosquitoes according to the locality.
Species
Dapoya (31.18%)
Yamtenga (30.52%)
Zongo (38.30%)
Ae. aegypti
2120 (81.41%)
2048 (80.35%)
1636 (51.14%)
Ae. albopictus
28 (1.08%)
0 (0.00%)
135 (4.22%)
An. gambiae
8 (0.31%)
382 (14.98%)
615 (19.23%)
An. funestus
0 (0.00%)
4 (0.16%)
0 (0.00%)
Cx. quinquefasciatus
448 (17.20%)
113 (4.43%)
812 (25.38%)
M. africana
0 (0.00%)
2 (0.8%)
1 (0.03%)
Over total
2604 (1.00%)
2549 (1.00%)
3199 (1.00%)
3.6. Influence of Physicochemical Parameters on Mosquito Populations
The six species of mosquitoes are distant from the center of the benchmark. They thus present a clear distribution concerning the physicochemical parameters. Thus, An. gambiae and Cx. quinquefasciatus mosquitoes are positively correlated to water temperature, turbidity and conductivity. An. funestus is positively correlated to the water pH. While Ae. aegypti, Ae. albopictus and M. africana are mosquitoes that are negative to all physico-chemical parameters (
Figure 5
).
Figure 5. RDA showing the correlation between environmental parameters and collected mosquito Species (Ae. aeg: Aedes aegypti; Ae. alb: Aedes albopictus; M. afri: M. africana; An. fun: Anopheles funestus; C. quin: Culex quinquefasciatus).
4. Discussion
A total of 83 positive larval breeding sites were collected during our study. The majority of these sites were artificial breeding sites (75%), mainly from households, and the rest (25%) were natural. This high proportion of artificial breeding sites shows, on the one hand, that mosquitoes easily colonize this category of breeding sites and, on the other, the contribution made by man to the presence of mosquitoes in these different localities. Indeed, the poor management of domestic water due to the absence of sanitation infrastructure is the real cause of the presence of these habitats and therefore of the proliferation of mosquitoes in these different localities
[9]
[18]
. Zongo is the locality with the highest number of breeding sites (35.42%), dominated by canaries. This result could be explained in part by the very physiognomy of the district, which offers a number of anthropogenic activities that provide breeding sites, and in part by the behavior of the population itself in non-urbanized areas
[10]
. According to him, the inhabitants of these areas generally come from the countryside and tend to transfer their original activities there (breeding, preparation of dolo, etc.), which generally contributes to the proliferation of breeding sites. Indeed, during our surveys in Zongo, we noted the presence of activities such as chicken rearing, where troughs are made of clay, and dolo preparation, where jars are most often used. These results confirm those of
[18]
, who also found a sizeable number of larval breeding sites, including ceramics in the same locality. We also noted the presence of artificial breeding sites in all three localities and all concession types. This shows that all these localities and concessions have practically the same wastewater and household waste management, probably due to the type of urbanization experienced in most African cities, where the sanitation system is deficient
[2]
-
[4]
.
The results of the analysis of the characteristics of the physicochemical parameters of the breeding sites show that sites such as buckets, tires, temporary pools, motorbike helmets, and canaries are characterized by high conductivity and turbidity values. High pH values characterized plastic boxes, metal dishes, watering cans, and jerry cans.
The inventory of Culicidae fauna shows four genera of mosquitoes encountered, namely the genera Anopheles composed of two species (An. gambiae and An. funestus) Aedes also composed of two species (Ae. aegypti and Ae. albopictus), Culex and Mansonia with each one species respectively Cx. quinquefasciatus and M. africana. This shows the risks to which the populations of these different localities are exposed, especially since these four genera of mosquitoes are vectors of diseases
[19]
. Indeed, the Anopheles mosquito is known for its formidable role as a vector in the transmission of malaria throughout the world and especially in sub-Saharan Africa
[20]
. It is also responsible for the transmission of Bancroft’s filaria (Wuchereria bancrofti)
[21]
. Culex also plays a role in the transmission of Wuchereria bancrofti in East Africa and India
[16]
. In addition, they can transmit some arboviroses (Japanese encephalitis) and could also harbor the Zika virus
[16]
[22]
. Aedes are considered important vectors of yellow fever, dengue, chikungunya, West Nile virus and Zika, as well as many other arboviruses
[23]
-
[26]
. Mansonia are the potential vectors of brugiosis in India, Indonesia and Malaysia. Several authors have also reported the presence of these four genera in these localities
[17]
[18]
. The number of mosquitoes collected in Zongo was higher (3199) than those collected in Dapoya (2604) and Yamtenga (2549). This may be explained by the fact that the number of breeding sites found in Zongo was higher than those found in Dapoya and Yamtenga.
In terms of Culicidae composition, 75% of the mosquitoes collected were from artificial habitats with a high abundance of plastic habitats (2916 specimens) followed by ceramic habitats (2449 specimens), and metal habitats (865 specimens). This is a corollary of the number of artificial habitats encountered, reflecting once again the role of man as a provider of mosquitoes through his lifestyle
[5]
[7]
[8]
; and also the result of the frequency of encounter of ceramics and tires. Indeed, these types are frequently found in many studies
[18]
.
The highest numbers of Anopheles and Culex mosquitoes were found in natural habitats (ponds and puddles) with respectively 996 specimens and 1014 specimens. This shows that Anopheles and Culex mosquitoes can use the same types of breeding sites. Anopheles are mosquitoes that most often use natural habitats such as puddles, ponds, rice fields, etc
[18]
[27]
.
Mosquitoes of the genus Aedes were present in almost every type of habitat. This shows that they are ubiquitous and can therefore colonize any type of habitat. It is therefore important to pay particular attention to these mosquitoes, as they are the source of many infections
[28]
and can even cause epidemics. In addition, these mosquitoes were frequently encountered in Dapoya (2148) and Yamtenga (2048), which could be explained by the type of breeding sites present in this locality. The majority of Aedes were found in plastic habitats (2606 or 44.90%, compared with 38.94% in ceramic habitats, 14.28% in metal habitats, and 1.88% in natural habitats), these sites were sampled much more frequently in these two localities, and these types of habitat are among those preferentially used by Aedes for breeding.
According to the RDA results, Anopheles and Culex mosquitoes were positively correlated with temperature and negatively correlated with water conductivity, turbidity, and pH. The development of Anopheles and Culex mosquitoes would therefore be influenced by high values of water pH, temperature, turbidity, and conductivity. On the other hand, mosquitoes of the genera Aedes and Mansonia negatively correlated to all physico-chemical parameters (conductivity, turbidity, temperature, and pH). Thus, these mosquitoes would develop in sites with low values of conductivity, turbidity, pH and water temperature. Environmental parameters would therefore be determining factors for the bioecology of Culicidae
[27]
[29]
.
5. Conclusion
Eighty-three habitats were found, including 41% in Zongo, 34% in Yamtenga, and 25% in Dapoya. These habitats were divided into natural habitats (25%) and artificial habitats (75%) made of plastic, ceramic, tires, and metal. The physicochemical parameters of these different habitats varied from one type to another. A total of 8352 mosquitoes were collected and belonged to four genera (Anopheles, Aedes, Culex and Mansonia) and six species (An. gambiae, An. funestus, Ae. aegypti, Ae. albopictus, C. quinquefasciatus and M. africana). The genus Aedes was the most encountered and was found in almost all habitat types. Culex and Anopheles were found in almost the same habitats, namely natural habitats. The presence of Aedes and Mansonia was much more influenced by low values of conductivity, turbidity, temperature, and pH of the water, while that of Anopheles and Culex was influenced by high values of these different parameters. These results show that the presence of mosquitoes in urban areas is mainly due to human activities such as poor water management in homes. It is therefore necessary that for better vector control, the populations are integrated by sensitizing them to the management of wastewater and the knowledge of mosquitoes. Moreover, the genus Aedes is gaining ground because it can colonize several types of habitats. It therefore requires special attention because it is a vector of many arboviruses.
Authors Contributions
KJ: conducted field data collection, sample processing, and statistical data analysis and drafted the manuscript; GA and KBG: designed the study, supervised the work, edited the manuscript, and acquired funding sources; NM: participated in sample processing in the laboratory (identification); MN: supervised the work and edited the manuscript; SS: participated in field data collection and statistical data analysis
Acknowledgements
The authors are grateful to Prof. Athanase Badolo and his laboratory for providing some materials for mosquito collection. The study was funded by The World Academy of Sciences (TWAS) Research Grants Programme in Basic Sciences (No.: 15-251 RG/BIO/AF/AC_I-FR3240287063; No.: 22-337 RG/BIO/AF/AC_G-FR 3240325168) to Dr. Awa Gnémé.
References
Fournet, F., Rican, S., Vaillant, Z., Roudot, A., Meunier-Nikiema, A., Kassié, D., et al. (2016) The Influence of Urbanization Modes on the Spatial Circulation of Flaviviruses within Ouagadougou (Burkina Faso). International Journal of Environmental Research and Public Health, 13, Article 1226. >https://doi.org/10.3390/ijerph13121226
Knudsen, A. and Slooff, R. (2024) Vector-Borne Disease Problems in Rapid Urbanization: New Approaches to Vector Control. Bulletin of the World Health Organization, 701, 1-6. >https://www.semanticscholar.org/paper/Vector-borne-disease-problems-in-rapid-new-to-Knudsen-Slooff/1b5a5842c9a167d5c8443dfca3579a989e96f283
Tougma, A. (2020) Vulnérabilité de la population de la ville de Ouagadougou face à la dengue. Ph.D. Thesis, Normandie Université.
Dossou-yovo, J., Doannio, J., Rivière, F. and Chauvancy, G. (1995) Urbanization and Establishment of Culex Quinquefasciatus in a West African Rural Area. Acta Tropica, 59, 251-253. >https://doi.org/10.1016/0001-706x(95)00078-s
Hougard, J.M.., Poudiougo, P., Agoua, H., Akpoboua, K.L.B., Back, C., Yaméogo, L., et al. (1994) De la nécessité de mener à terme les activités de lutte antivectorielle du programme de lutte contre l’onchocercose en Afrique de l’Ouest: Rappel des enjeux et proposition d’un budget a minima pour la période 1998-2002. Parasite, 1, 295-303. >https://doi.org/10.1051/parasite/1994014295
Zahouli, J.B.Z., Koudou, B.G., Müller, P., Malone, D., Tano, Y. and Utzinger, J. (2017) Urbanization Is a Main Driver for the Larval Ecology of Aedes Mosquitoes in Arbovirus-Endemic Settings in South-Eastern Côte d’Ivoire. PLOS Neglected Tropical Diseases, 11, e0005751. >https://doi.org/10.1371/journal.pntd.0005751
Boussès, P., Dehecq, J.S., Brengues, C. and Fontenille, D. (2013) Inventaire actualisé des moustiques (Diptera: Culicidae) de l’île de La Réunion, océan Indien. Bulletin de la Société de pathologie exotique, 106, 113-125. >https://doi.org/10.1007/s13149-013-0288-7
Ouédraogo, S., Degroote, S., Barro, S.A., Somé, P.A., Bonnet, E. and Ridde, V. (2019) Épidémies récurrentes de la dengue au Burkina Faso: Préférences communautaires pour une intervention de prévention de la maladie. Revue d’Épidémiologie et de Santé Publique, 67, 375‑382. >https://doi.org/10.1016/j.respe.2019.08.002
Fournet, F., Meunier-Nikiema, A., Salem, G. and Coquery-Vidrovitch, C. (2008) Ouagadougou: 1850-2004 une urbanisation différenciée. IRD. >https://doi.org/10.4000/books.irdeditions.870
Robineau, O. (2014) Les quartiers non-lotis: Espaces de l’entre-deux dans la ville burkinabé. Carnets de géographes, No. 7. >https://doi.org/10.4000/cdg.478 .
UN-Habitat (2008) The State of African Cities 2008: A Framework for Addressing Urban Challenges in Africa. UN-HABITAT.
Hassan, A.N., Nogoumy, N.E. and Kassem, H.A. (2013) Characterization of Landscape Features Associated with Mosquito Breeding in Urban Cairo Using Remote Sensing. The Egyptian Journal of Remote Sensing and Space Science, 16, 63-69. >https://doi.org/10.1016/j.ejrs.2012.12.002
Gnémé, A., Kaboré, J., Kpoda, N.W., Gnoumou, P.S., Mano, K. and Kabré, G.B. (2019) Diversity and Abundance of Mosquitoes in the City of Ouagadougou, Burkina Faso. International Journal of Entomology Research, 4, 26-319.
Fournet, F., Cussac, M., Ouari, A., Meyer, P., Toé, H.K., Gouagna, L., et al. (2010) Diversity in Anopheline Larval Habitats and Adult Composition during the Dry and Wet Seasons in Ouagadougou (Burkina Faso). Malaria Journal, 9, Article No. 78. >https://doi.org/10.1186/1475-2875-9-78
Li, Y., Kamara, F., Zhou, G., Puthiyakunnon, S., Li, C., Liu, Y., et al. (2014) Urbanization Increases Aedes albopictus Larval Habitats and Accelerates Mosquito Development and Survivorship. PLoS Neglected Tropical Diseases, 8, e3301.>https://doi.org/10.1371/journal.pntd.0003301
Ouédraogo, T.D.A. (2011) Lutte bio-écologique contre Culex Pipiens quinquefasciatus en milieu urbain au Burkina Faso. Ph.D. Thesis, Universite de Ouagadougou.
Amarasinghe, A. (2011) Dengue Virus Infection in Africa. Emerging Infectious Diseases, 17, 1349-1354. >https://doi.org/10.3201/eid1708.101515
Gnémé, A., Kaboré, J. and Mano, K. (2019) Occurrence des anopheles risque d’infection en milieu Urbain. International Journal of Mosquito Research, 6, 6-11.
Ouedraogo, T.D.A., Baldet, T., Skovmand, O., Kabre, G. and Guiguemde, T.R. (2005) Sensibilité de Culex quinquefasciatus aux insecticides à Bobo Dioulasso (Burkina Faso). Bulletin de la Societe de Pathologie Exotique, 98, 406-410.
Zahouli, J.B.Z., Koudou, B.G., Müller, P., Malone, D., Tano, Y. and Utzinger, J. (2017) Effect of Land-Use Changes on the Abundance, Distribution, and Host-Seeking Behavior of Aedes Arbovirus Vectors in Oil Palm-Dominated Landscapes, Southeastern Côte d’Ivoire. PLOS ONE, 12, e0189082. >https://doi.org/10.1371/journal.pone.0189082
Chernin, E. (1983) Sir Patrick Manson’s Studies on the Transmission and Biology of Filariasis. Clinical Infectious Diseases, 5, 148-166. >https://doi.org/10.1093/clinids/5.1.148
Guedes, D.R., Paiva, M.H., Donato, M.M., Barbosa, P.P., Krokovsky, L., et al. (2017) Zika Virus Replication in the Mosquito Culex quinquefasciatus in Brazil. Emerging Microbes&Infections, 6, 1-11. >https://doi.org/10.1038/emi.2017.59
Service, M.W. (1974) Survey of the Relative Prevalence of Potential Yellow Fever Vectors in North-West Nigeria. Bulletin of the World Health Organization, 50, 487‑494.
Adeleke, M., Mafiana, C., Idowu, A., Adekunle, M. and Sam-Wabo, S. (2008) Mosquito Larval Habitats and Public Health Implications in Abeokuta, Ogun State, Nigeria. Tanzania Journal of Health Research, 10, 103-107. >https://doi.org/10.4314/thrb.v10i2.14348
Aigbodion, F.I. and Uyi, O.O. (2012) Temporal Distribution of and Habitat Diversification by Some Mosquitoes (Diptera: Culicidae) Species in Benin City, Nigeria. Journal of Entomology, 10, 13-23. >https://doi.org/10.3923/je.2013.13.23
Chukwuekezie, O., Onwude, O.C., Nwangwu, U. and Obiageli, A.N. (2018) Diversity and Distribution of Aedes Mosquitoes in Nigeria. New York Science Journal, 11, 50-57.
Somé, Y. (2010) Modélisation de la distribution spatiale de formes moléculaire M et S d’Anopheles gambiae au Burkina Faso avec les SIG et l’analyse spatial. Ph.D. Thesis, Université d’Orléans.
Benhissen, S., Habbachi, W., Rebbas, K. and Masna, F. (2018) Études entomologique et typologique des gîtes larvaires des moustiques (Diptera: Culicidae) dans la région de Bousaâda (Algérie). Bulletin de la Société Royale des Sciences de Liège, 87, 112-120. >https://doi.org/10.25518/0037-9565.8221
Yared, S., Gebressilasie, A., Worku, A., Mohammed, A., Gunarathna, I., Rajamanickam, D., et al. (2024) Breeding Habitats, Bionomics and Phylogenetic Analysis of Aedes aegypti and First Detection of Culiseta longiareolata, and Ae. hirsutus in Somali Region, Eastern Ethiopia. PLOS ONE, 19, e0296406. >https://doi.org/10.1371/journal.pone.0296406