Ecology, Distribution and Risk of Transmission of Viral Haemorrhagic Fevers by Aedes Mosquitoes around the Port Areas of Tema in Southern Ghana ()
1. Introduction
Some species in this genus transmit arthropod-borne viruses of public health importance including dengue fever, yellow fever, rift valley fever, Venezuelan equine encephalitis, Japanese encephalitis, zika, la Crosse viruses and chikungunya [5] [6] which negatively impact the economy of many countries. Human activity such as international shipping of goods has been known to expand the distribution of Aedes aegypti and Ae. albopictus [7]. It is also known that the spread of the container-breeding species Ae. albopictus and Ae. aegypti beyond their native range has been facilitated by the trade of goods, significantly in used tyres and machinery through the land and sea ports [8] [9] [10].
Yellow fever is known to be endemic in Ghana and the major outbreak that happened in the country between 1969-1970 in Damongo and Pong-Tamale in the Northern Region, Bolgatanga and Navrongo in the Upper East Region, and Nandom and Jirapa in the Upper West Region recorded 319 cases with 79 deaths [11].
Although not much transmission of arboviruses has been reported in the country, there are reports of arboviruses such as Dengue circulating in Ghana [12] [13] which borders Côte d’Ivoire and Burkina Faso where outbreaks have been documented [14] [15]. Ae. albopictus has also been documented to be present in southern Ghana [16]. This species has been documented in Gabon as the main vector for Zika Virus is currently known to be spreading to countries in West Africa [17]. This prompts the apt need for vector surveillance especially at the port areas since it has been documented that the main route of introduction of this species to countries has been through the importation of used tyres [18].
Also, considering the increased migration of people across borders of countries, unchecked international trade and the absence of organized mosquito control programme, there is the need to generate comprehensive information on Aedes vectors of Dengue and other viral hemorrhagic fevers especially around the port areas in the country. The objective of this study was to determine the ecology and distribution of Aedes mosquitoes as well as assess the risk of transmission of viral haemorrhagic fevers around the port areas in Tema.
2. Materials and Methods
2.1. Study Areas
The study was carried out in areas around the Tema Port which comprises Tema Community One (5.64574˚N, 0.00235˚E and 24 m), Tema New Town (5.6530˚N, 0.0252˚E and 24 m) and Golden Jubilee Terminal of Tema Seaport (5.6246˚N, 0.01187˚E and 23 m) (Figure 1). The collections were carried out during the wet (October-November and April) and dry (January-March) seasons of 2016 and 2017. These areas are all in Tema, which is a large settlement located on the Gulf of Guinea and Atlantic shore of Ghana. It is situated around 30 kilometres east of the capital city, Accra, in the Greater Accra Region. Tema is characterized by a dry equatorial climate lying in the coastal savannah zone. It is found in the arid part of Southern Ghana, experiencing normal yearly rainfall of around 750 millimetres [19]. The inhabitants of the study areas work in the Tema port, the fishing harbour and other industries in Tema, while some are self-employed or are engaged in elementary occupations such as road-side hawking of snacks or soft drinks while the aged ones who cannot work always stay at home throughout the day. This is a typical urban settlement although some structures are typical of those which can be found in a rural settlement.
2.2. Household Mosquito Larval Surveys
A house-to-house entomological survey was carried out in houses and peri-domestic areas in each of the study area using a simple random sampling method. Each house selected was examined to detect mosquito larval breeding sites. Water storage containers and tyres (imported and those at vulcanizer shops)
Figure 1. Map of Ghana showing Tema Metropolis and the three study sites.
were inspected for the presence of pre-adult stages of Aedes mosquitoes for larval indices estimation. Each container was recorded for container type, location within the house and sun exposure. Mosquito larvae and pupae were collected from used tyres and other artificial containers with a 350 m ladle, pipette or scooper into a well labeled transparent water holding containers which were covered with perforated lid to provide aeration. A torch light was used for visibility in dark containers and dark rooms.
2.3. Oviposition Traps
Ovitraps were randomly set at strategic points at each study site. They were placed at concealed places to prevent being tampered with by the inhabitants. These traps were set in order to detect the presence and to estimate population density of Aedes mosquitoes during the rainy and dry season. The ovitraps consist of small plastic containers which were modified by placing a wooden paddle inside the ovitraps to serve as landing base/support for ovipositing female mosquitoes and by baiting them with grasses and a pinch of larvae feed (TetraMin® fish flakes) which gave a conducive breeding site for Aedes larvae. These traps were observed every three days for a month and all the eggs or any hatched immature stages found in the ovitraps were emptied into well-labeled transparent water-holding containers and reared into adults.
2.4. Estimation of Man-Vector Contact Rates
Hourly collections of adult femaleAedes mosquitoes were done to determine diurnal biting patterns of Aedes mosquitoes prevalent in two of the study sites (Tema Community One and Tema New Town). This was carried out from 15:00 to 18:00 hrs GMT. This exercise was carried out both indoors and outdoors in selected places in two of the study sites during the rainy and dry seasons. Four collectors (two indoors and the other two outdoors) were involved in this collection exercise. All adult female mosquitoes which landed on the exposed skin of the limbs of the collectors to bite were collected using a 15 ml falcon tubes and transferred into well labeled sealed paper cups, killed with chloroform and left for identification. For each season, a total of 48 man-hours were used to carry out the landing catches both indoors and outdoors.
2.5. Species Identification
All eggs, larvae and pupae of mosquitoes collected were incubated to adult stages at the insectary of Noguchi Memorial Institute of Medical Research (NMIMR) and identified to species level under a microscope, using identification keys [20] [21].
3. Data Analysis
Data collected were input into Microsoft Excel and analyzed using SPSS 23.0 statistical software package. Pearson’s Chi-square was used to test for association between variables, while the t-test was used to compare data for significant difference.
To estimate the risk of transmission of viral haemorrhagic fevers at the study sites, three larval indices were calculated. These are House index (HI), Container index (CI) and Breteau index (BI). HI was expressed as the percentage of houses infested with Aedes larvae; CI as the percentage of containers infected with larvae or pupae; and BI as the number of positive containers per 100 inspected houses.
The risk of transmission of Viral Haemorrhagic Fevers (VHFs) at the study site was estimated using the WHO criteria as follows: 1) An area where BI, HI, and CI exceeded 50, 35 and 20 respectively, the risk of Aedes mosquitoes- transmitted VHF’s was be considered to be high. 2) An area where BI is between 5 and 50, the density of Aedes mosquitoes was considered to be sufficient enough to promote an outbreak of VHF disease. 3) An area where BI, HI and CI were less than 5, 4 and 3 respectively, was considered to be unlikely for VHF transmission to occur [22] [23]. The man-vector contact (man biting rate) was assessed by the number of biting adult female Aedes mosquitoes per man-hour. Man-vector count exceeding two female bites per man-hour was also indicative of a significant risk of transmission of the disease [23]. Ovitrap index (OI) expressed as the percentage of traps infested with Aedes immature stages was also calculated for each site.
4. Results
4.1. Species Composition and Ovitrap Index
A total of 404 houses (240 at Tema Community One, 150 at Tema New Town and 14 at Golden Jubilee Terminal) were surveyed during the study period for the presence of immature Aedes in water holding containers in the various study sites. Out of the total number of houses surveyed, 122 (30.2%) were positive forAedes larvae.
A total of 6498 mosquitoes were collected from the three study using ovitraps, larval and human landing collections during the period of survey. A higher number, 5715 (88.0%) of Aedes mosquitoes were collected from during the larval surveys, compared to 574 (8.8%) from ovitraps and 209 (3.2%) from human landing catches. Of the 6498 mosquitoes collected, 6038 (92.9%) were Aedes aegypti, while Culex spp. and Anopheles gambiae constituted 5.2% (337) and 1.9% (123) respectively. Majority, 3053 (47%) and 3057 (47%) were collected from Tema Community One and Tema New Town respectively compared to 388 (6%) from Golden Jubilee Terminal area. The ovitrap index ranged from 2.5 to 12.5 with the highest index recorded at the Golden Jubilee Terminal (Figure 2). The ovitrap index was generally high in the rainy season compared to the dry season.
4.2. Larval Indices
Larval indices estimated as House Index (HI), Container Index (CI) and Breteau Index (BI) varied in all the sites. Tema New Town recorded the highest indices compared to Tema Community One and Golden Jubilee Terminal. The HI, CI, BI estimated were respectively as follows Tema Community One (34.2, 39.4 and 108.3 for rainy and 23.3, 31.7 and 82.5 for dry season), Tema New Town (41.3, 44.9 and 134.7 for rainy and 28, 40.6 and 109.3 for dry season) and Golden Jubilee Terminal (14.3, 28.6 and 85.7 for rainy and 0 for all in dry season) as shown in Table 1. Seasonal variations in the larval indices observed were generally higher during the rainy season than the dry season.
4.3. Prevalence of Aedes Larvae in Containers
Out of the 1092 breeding containers inspected, 418 (38.3%) were positive with 237 (21.7%) positive for mosquito larvae or pupae in rainy season while 181 (16.6%) were positive in dry season. These were 8 (1.9%) earthenware pots, 1 (0.2%) disposed plastic container, 96 (23.0%) plastic barrels, 205 (49.0%) plastic basins, 14 (3.4%) buckets, 2 (0.5%) poly tank, 62 (14.8%) car tyres, 27 (6.5%) metal drums and 3 (0.7%) jerrycans (Figure 3). Most of these water holding containers were located outdoors (58.1%) while 62.8% of these breeding containers were shaded or not exposed to the sun. Larvae and pupae of mosquitoes (5,715) were found in the above-mentioned breeding containers inspected but mosquitoes preferred to breed in plastic basins (39.0%), plastic barrels (23.3%), car tyres (17.2%), metal drums (8.1%), earthenware pots (5.3%) and poly tank (4.4%) as compared to buckets, jerrycans and disposed plastic container as shown in Table 2. The association between breeding sites and mosquito species was statistically significant (P < 0.001). 3713 (65%) of these mosquitoes were collected in the rainy season and 2002 (35%) collected in the dry season.
Figure 2. Ovitrap index estimated at the three study sites.
Table 1.Aedes mosquito larval indices for the three sites in the study area.
Figure 3. Mosquito larvae/pupae breeding sites: (a) earthenware pot, (b) jerrycan, (c) metal drum, (d) plastic basin, (e) poly tank, (f) bucket, (g) plastic barrel, (h) car tyre, (i) disposed plastic container.
Table 2. Number of mosquito larvae from the nine breeding containers.
4.4. Adult Biting Activity and Man-Vector Contact Rate
A total of 209 adultAedes mosquitoes were collected out of which 133 and 76 were collected during the rainy season and dry season respectively for the two study sites.Ae aegypti was identified as the only mosquito biting in the study sites. More collections of mosquitoes were made outdoors compared to indoors [Tema Community One = 39 (18.7%) indoors and 71 (34.0%) outdoors; Tema New Town = 33 (15.8%) indoors and 66 (31.6%) outdoors] There was significant differences between mosquitoes caught indoors and outdoors in the two communities [Tema Community One (P < 0.001); Tema New Town (P < 0.001)]. However, from the hourly collections of adult mosquitoes made, highest collections were made from the hours of 17:00-18:00 GMT (Tema Community One = 69; Tema New Town = 67) followed by the hours of 16:00-17:00 (Tema Community One = 32; Tema New Town = 24). Least collections were made between the hours of 15:00-16:00 (Community One = 9; Tema New Town = 8). The man vector rates was generally higher during the rainy season than the dry season. The man-vector contact rates for the two residential sites were 1.5 and 0.8 bites per man hour in rainy season and dry season respectively for Tema Community One and 1.3 and 0.8 bites per man hour in rainy season and dry season for Tema New Town. Figure 3 shows the ovitrap index estimated for the three sites. The ovitrap index was highest in Golden Jubilee terminal.
5. Discussion
Different species of Aedes mosquitoes, which are potential vectors for yellow fever, are already known to be distributed all over Ghana as reported by various studies in different parts of the country [11] [16] [24] [25]. The study revealed the presence of only one distinct Aedes species and other mosquito species (Culex spp. and Anopheles gambiae) which are not relevant to this study in the Port areas of Tema. The predominant Aedes species encountered or recorded in this study was Aedes aegypti. This could be a result of the urban nature of Tema. This species has been reported to be the dominant species in densely crowded urban areas [26] [27] where they serve as potential vector for the urban cycle of yellow fever transmission [28]. This mode of transmission is made more possible because of the domestic characteristics of the species wherein they live in close proximity and association with humans.
However, in most urban dwellings, tap and rain water are stored in varying containers which include plastic barrels, buckets and plastic basins due to irregular supply of water [29]. Containers which retain or hold water for longer periods of time serve as potential breeding sites for mosquitoes [30]. In the two residential communities close to the port of Tema where part of the study was also carried out, even in the presence of pipe borne water, water is stored in basins in most households due to intermittent pattern of water supply which is most common in the rainy season compared to the dry season. The study area had different sites that favoured the breeding of Aedes mosquitoes which also resulted in the high larval indices recorded. It was observed that more mosquitoes were breeding in basins followed by plastic barrels and car tyres amongst other types breeding sites. This is may be due to the frequent usage of plastic basins for water storage by various households. Ae. aegypti mosquitoes were the dominant species obtained from all the different types of breeding containers followed byCulex spp. and An. gambiae. Ae. aegypti, Culex spp. and An. gambiae which were mostly found in close association with car tyres and plastic barrels. The presence of these mosquitoes in car tyres has also been reported in other studies [27] [31].
In the study, more car tyres and disposed containers were recorded to collect water. This could have triggered the hatching of eggs of Aedes mosquitoes laid during the previous dry season owing to the fact thatAedes eggs can withstand long periods of desiccation thus contributing to the high number of mosquitoes during the rainy season [32].
Temperature, relative humidity and nutrients source is known to contribute to mosquito abundance during rainy season, while absence of all or any of these components and high or extreme temperature decrease mosquito breeding or abundance in the dry season [33]. In this study, high abundance of Aedes immature stages were found in the rainy season than the dry season as previously reported in other studies in northern and southern Ghana [16] [24] [25]. However, another study in northern Ghana found high larval indices in the dry season than the rainy season and ascribed the reason that many people tend to store water much longer during the dry season than the rainy season [34]. Water availability and use has been associated with the breeding of Aedes immature stages [34]. Availability and ready access to pipe-borne water reduced the practice of storing water in containers for long periods necessary to allow the breeding of Aedes mosquitoes. In this study, more containers had water collected in them in the rainy season compared to numbers recorded in the dry season. The study area is much urban and most households have ready access to pipe-borne water even in the dry season. It can therefore be postulated that high prevalence of Aedes immature stages in the area could be due to the availability of water during the rainy season. The recent WHO-TDR document [35] on the use of multisectoral approaches for controlling vector-borne diseases highlights the need for collaboration between the water hygiene and sanitation sector (WASH) and disease control programs to help support the formulation of future control strategies.
Adult Aedes species are day time biters preferring to feed during the day or early evening. They usually bite and rest outdoors before and after feeding [23] [36]. From this study, it was observed that more mosquitoes were biting outdoors as compared to indoors. This situation in the study area may be attributed to the several breeding sites found around houses than inside as more breeding containers were recorded outside houses than inside in this study. The study also revealed that Ae. aegypti, which was the only species recorded from human landing catches, starts biting in the afternoon and peaking around the hours of 17:00-18:00 GMT. These findings are very significant and important for the formulation of future vector control programmes around these areas. The intensity of disease transmission therefore will be expected to be higher around the hours of 17:00-18:00 GMT. Therefore, the use of several protective measures against the bites of Aedes mosquitoes at these times of the day could reduce the transmission of arboviruses in the area.
Use of ovitraps was also helpful for surveillance of Aedes species in the study areas as they assisted in the determination of presence, abundance and distribution of the dengue vectors. It is also an important tool or surveillance method for providing spatial distribution and temporary data for monitoring and assessing the impact of control measures [37]. The relatively high number of Ae. aegypti collected using this method in this study was probably due to the fact that Ae. aegypti mosquitoes are container loving mosquitoes which show high affinity to oviposit in any suitable water holding container which has held water for a long time [38] [39].
6. Conclusion
The results from the larval indices indicate that Aedes population in the study sites was sufficient enough to promote outbreak of yellow fever or any VHF prompting the establishment of a mosquito control programme in the study area. Inhabitants of the two residential communities should be encouraged to use mosquito repellent when outside between 17:00-18:00 hrs GMT (the peak biting time of the species), while water storage containers kept both inside and outside houses should be emptied regularly to reduce mosquito breeding sources. Although Ae. albopictus was not found during the current survey, a previous study identified the species to be present in some areas in southern Ghana where the port is located. The extent of spread of this species in the country is not well known and it calls for more enhanced vector surveillance as well proper sanitation and waste disposal should be carried out in the area to prevent or control the introduction of invasive species into the country.
Data Availability
The datasets used during the current study are available from the corresponding author on reasonable request.
Author’s Contributions
KCO conducted the fieldwork and data analysis and drafted the manuscript; JC, JNO, AAA, SPB, MA, KY, KOA assisted in laboratory work and data analysis; DAG, MAA, RB supervised the work and edited the manuscript; SD designed the study, supervised data analysis and edited the manuscript.
Acknowledgements
The authors gratefully thank the members of the Vector Research Group of the Parasitology Department of the Noguchi Memorial Institute for Medical Research, Ghana and all staff of the Port Health Division of the Ghana Health Service, Ghana.