- Open Access
Attractive toxic sugar baits for controlling mosquitoes: a qualitative study in Bagamoyo, Tanzania
© The Author(s) 2018
Received: 30 August 2017
Accepted: 4 January 2018
Published: 10 January 2018
Malaria elimination is unlikely to be achieved without the implementation of new vector control interventions capable of complementing insecticide-treated nets and indoor residual spraying. Attractive-toxic sugar baits (ATSBs) are considered a new vector control paradigm. They are technologically appropriate as they are simple and affordable to produce. ATSBs kill both female and male mosquitoes attracted to sugar feed on a sugary solution containing a mosquitocidal agent and may be used indoors or outdoors. This study explored the views and perceptions on ATSBs of community members from three Coastal Tanzanian communities.
Three communities were chosen to represent coastal urban, peri-urban and rural areas. Sensitization meetings were held with a total of sixty community members where ATSBs were presented and explained their mode of action. At the end of the meeting, one ATSB was given to each participant for a period of 2 weeks, after which they were invited to participate in focus group discussions (FGDs) to provide feedback on their experience.
Over 50% of the participants preferred to use the bait indoors although they had been instructed to place it outdoors. Participants who used the ATSBs indoors reported fewer mosquitoes inside their homes, but were disappointed not to find the dead mosquitoes in the baits, although they had been informed that this was unlikely to happen. Most participants disliked the appearance of the bait and some thought it to be reminiscent of witchcraft. Neighbours that did not participate in the FGDs or sensitizations were sceptical of the baits.
This study delivers insight on how communities in Coastal Tanzania are likely to perceive ATSBs and provides important information for future trials investigating the efficacy of ATSBs against malaria. This new vector control tool will require sensitization at community level regarding its mode of action in order to increase the acceptance and confidence in ATSBs for mosquito control given that most people are not familiar with the new paradigm. A few recommendations for product development and delivery are discussed.
Malaria across endemic regions of sub-Saharan Africa is declining [1, 2], mainly thanks to vector control interventions, such as long-lasting insecticide-treated bed nets (LLINs) and indoor residual spray (IRS) . Despite the success achieved so far, elimination is challenging and the shortfalls of the current interventions need to be addressed with new and complementing vector control tools. Attractive-toxic sugar baits (ATSBs) are considered a new vector control paradigms that kills both female and male mosquitoes [4–10]. The concept exploits the sugar feeding behaviour of mosquitoes, attracting them to sugar feed from a source containing an insecticidal ingredient. The bait targets mosquitoes when they are sugar feeding rather than host seeking or resting, which are traditionally targeted by LLINs, IRS and ATSBs.
The hypothesis is the ATSBs could be an appropriate way to complement existing vector control interventions as they are low-tech, low-maintenance and very affordable. Whereas scientific evidence on the efficacy and effectiveness was proven in controlled conditions, field trials are required to understand how local populations would perceive them. This is especially the case ATSBs as they do not provide direct personal protection but rely on wider effects on the mosquito population to reduce human-vector contact. The current study describes the first social study aiming at describing views and perceptions of community members from Coastal Tanzania on the use of ATSBs.
Three wards of Bagamoyo district, in the Pwani Coastal Region of Tanzania were selected to participate in the study: Dunda, Kerege, and Kiromo. The villages in each ward represented a range of urban, peri-urban, and rural communities within the area. Dunda covers much of the main town of Bagamoyo (urban) as well as the fishing village of Kaole, Kiromo is situated 10 km south of Bagamoyo town and is mainly composed of small traders and farmers (rural) and Kerege is 25 km south of Bagamoyo with busy roadside commerce and outlying agricultural areas nearing Dar es Salaam (peri-urban). Twenty individuals from each village were invited to participate in sensitization and focus group discussions (FGDs) regarding the ATSBs. Gender was mainstreamed by separating men and women, the methodology also avoided inhibiting women’s opinions.
Sensitization meetings were held in each village before distributing the ATSBs. During the meetings communities were introduced to the concept of attracting mosquitoes to sugar-feed to kill them and were explained how the ATSB worked. All questions, concerns and opinions were answered and recorded. During sensitizations, participants were shown how the bait could be made using basic materials commonly found in household waste. Materials used included: a plastic water bottle (12 L) cut in half, sponge, black cloth, water, sugar, injectable ivermectin solution (IVOMEC® 1%) and string.
The production of an ATSB was demonstrated during the sensitization meeting so that participants could understand how they were made and they were advised to place the baits outside close to vegetation. This has been demonstrated as the best peri-domestic location to place the baits in semi-field experiments and maximize the likelihood of mosquitoes sugar-feeding on the ATSB . The bait had a string tied around it, making it easy to hang and place out of reach from small children or pets. Participants were asked to check that the bait’s sponge was kept moist. Participants were instructed if it dried up to add enough water to soak the sponge but not immerse it. Participants were also informed that the baits did not act immediately, mosquitoes would take 24–28 h to die after ingesting the sugar solution. In addition, it was mentioned that the purpose of this study was not to measure changes in the population of mosquitoes, or longevity of the baits, but rather to understand the practical experience of community members using an ATSB and to receive feedback on how to improve and guide future research. At the end of the sensitization meeting, one ATSB was given to each of the participants and 2 weeks later the community met again for FGDs to ascertain the feedback following the roll-out of the baits. During each session guiding questions were developed to keep discussions on track and to ensure useful feedback was collected. FGDs were documented and common responses were identified and clustered.
Number of individuals who participated in sensitization and focus group discussions by gender and village
Focus group discussions
Placement of ATSBs
Views and perceptions of the participants from Dunda, Kiromo and Kerege in Tanzania to the ATSB
Respondents (n = 48)
General acceptance of the ATBS
Acceptance of the appearance
Acceptance of maintenance needs
Acceptance of design and concept
Perceived as effective
Preferred placement of the baits
“I placed my bait near my shop and had to explain to customers that it was not meant for juju or witchcraft. I think this is related to its appearance and the black cloth”-Female Participant, Kerege
On the hand, one participant said he had moved the bait indoors but ended taking it back outside because the bait attracted a lot of mosquitoes.
The majority of participants did not like the appearance of the baits (Table 2). A few participants in Kerege expressed that the baits were not very attractive and that their neighbours had associated the black cloth used in the bait with witchcraft. Participants suggested using more colourful materials and printing a pattern or icon that could relate the bait to mosquito control. In the more rural village, participants reported that their neighbours did not believe that the bait meant to kill mosquitoes and there was general disbelief amongst those that had not attended the sensitization meetings. In the urban areas, participants reported mixed experiences with neighbours. Many wanted to know what it was and after learning of its function became excited about it. A few community members wanted to borrow the ATSB and use it in their homes. Many participants reported enjoying teaching others about the baits. One participant complained that the baits produced a bad smell and attracted ants. Another comment was that children became afraid of the bait once they learned it killed mosquitoes.
Design and maintenance
Most participants were happy with the design of the baits and liked that the fact that they were made with locally available materials that were easy to obtain (Table 2). Some deemed that surface area for mosquito feeding in ATSB was too small and suggested using wider containers, which may attract more mosquitoes. Some suggested construction of a structure that could not be easily moved or stolen, something permanent, for example made of concrete. The most commonly mentioned challenge was the need to check if the baits had dried out (Table 2). Most people said it was an annoyance and mentioned they would easily forgot to maintain the bait because of other responsibilities. Also, a few participants moved the bait indoors because they said if they would place them outside they would have difficulty in maintaining the level of the solution because of the exposure to intense sunshine and/or rain.
“Every night when I sleep I can hear the mosquitoes flying around. Once I moved my bait inside, I did not hear them anymore, even though I still did not find any dead mosquitoes in the bait”-Female Participant, Kiromo
One participant reported that he would see mosquitoes in the baits in the mornings, but when he touched the bait, all would fly away, making him unsure if the bait was working. However despite this over 50% of the participants perceived the bait as effective (Table 2) and were interested in continuing to use the baits after the project was terminated.
Sustainability and delivery
One of the topics covered in sensitizations was the sustainability of ATSBs. Participants were asked to think of ways that a program, if implemented, could be effective in their communities. Almost all communities suggested some variation of the same strategy, which would be to train members of the community on how to make the ATSBs and form groups to share costs among members. Most mentioned using the field trial participants themselves as the “ambassadors” or trainers for an initial roll-out. The rationale behind the groups was to offset the costs of making the traps by sharing the costs of materials they needed to buy, i.e. sugar and ivermectin (IVOMEC® 1%). They would also be able to share recycled materials, such as cloth, sponge, rope, or buckets/12 L bottles. Participants emphasized that the first step would be teaching the community about the baits so people would understand how they work, and the importance reducing mosquitoes in their environments. Participants were enthusiastic and mentioned that they were interested in making more baits for themselves and their family members.
Attractive-toxic sugar baits are being promoted as one of the new vector control paradigms. Although there is potential that ATSBs might fill a gap in regards to controlling vectors that LLINs and IRS might fail at, but there is also a fear that the intervention will be badly accepted by the public. Opposed to LLINs and IRS, ATSBs do not directly protect users from mosquito bites and do not trap mosquitoes either. It is difficult for users to perceive a benefit from ATSBs, and thus these may not be accepted and deemed as useless. Current research in the field shows potential of the intervention to reduce mosquitoes by placing ATSBs indoors , community members generally also preferred to place the ATSB inside as perceived benefits were low when the bait was placed outdoors. Results from biodome experiments showed that An. arabiensis mosquitoes are more likely to feed on baits placed outside amongst vegetation but will also, to some extent, feed indoors provided people are sleeping under a bed-net . It is possible that best results would be obtained if both approaches are followed and this way community members are satisfied to see a measurable effect on their indoor mosquito densities but the full potential of the intervention is not wasted. It would be appropriate to brief communities on mosquito behaviour prior to trials and why the ATSBs are more effective outside than in.
Baits were generally well-accepted by the FGD participants despite other community members, who were not participating in the study, expressing wariness that such a thing would not be able to kill mosquitoes. The baits were linked to witchcraft, which is a common belief and practice in communities of Coastal Tanzania, and particularly Bagamoyo. There was consensus that the bait needed a logo or icon that would associate it with mosquito control. Associations with witchcraft will be dependent on the area where the ATSBs are rolled out as well as the ethnicity of the target population. It is likely that other communities in different geographical areas would not make this association. Participants also disliked having to maintain the bait by keeping it moist. Further product development must evaluate ways of keeping the bait moist with minimal care to ensure compliance is maximized by making the bait as low-maintenance as possible.
Community members also expressed concerns regarding toxicity of the baits and what effect it could have on their children in case they ingested the solution. The baits that were provided in this study contained 0.01% ivermectin, which is a common dewormer used in mass-drug administration against onchocerciasis and filariasis, it is also a very popular drug in the veterinary market. For a small child of 15 kg to ingest a therapeutical dose of ivermectin (200 μg per kg), he or she would have to ingest at least 30 mL of the sugar solution contained in the bait. Since the amount of bait required to make the sponge mattress in the prototype wet was 1 L, it would require 10 mL of 1% ivermectin. This dose is greater than the minimum dose recommended for child weighing 15 kg. To count this the design used in the ATSB trapped the solution in a sponge making it difficult to retrieve such an amount without completely dismantling the bait and squeezing the sponge. However, to make the intervention safe for community use grilling or hanging them should be recommended when it comes to the field application. Nonetheless, individuals pro-actively addressed their own concerns by hanging the baits out of children’s reach. Future product development must choose a toxicant with very low or negligible mammalian toxicity. ATSBs in other studies have been commonly tested using 1% boric acid solution [7–9, 12, 13]. Investigators using boric acid in their ATSB formulations should reconsider the use of this compound as it is toxic to mammalian reproduction. If a 2-year-old child consumes sugar solution from a bait containing 1% boric acid, it can be exposed to a dose potentially causing future reproductive complications by only ingesting 0.1 mL of solution .
Although it was not the projects objective to measure efficacy of the bait at controlling mosquitoes it was clear that many participants felt they should report they heard fewer mosquitoes inside their homes after moving the baits inside. One participant complained that the bait attracted mosquitoes and these would be seen resting on the walls of the baits but would not be dead. This is consistent with how an ATSB is designed, seeing mosquitoes inside the bait should be regarded as a confirmation that the bait is working. However, a few participants stated they perceived a reduction in mosquitoes within their homes but were disappointed that they didn’t find dead mosquitoes.
The use of recycled materials to produce the ATSBs sparked mixed opinions, although few people regarded the look as shabby and unofficial, most of the participants were pleased with being able to produce the bait themselves rather than buying them or rely on officials to distribute them. A logotype should be incorporated in the design that easily associates the bait with mosquito control. Participants agreed that the way towards reaching sustainability must actively involve the community to create awareness about this new vector control paradigm. In addition, a Training of Trainers (TOT) model was suggested in which programme resources could be used to train and inform individuals about ATSBs, supported by a larger community group who would share the cost of the items that need to be bought or collected. A TOT model would generate a pool of human resources and contribute to capacity building in communities where large proportions may be unemployed, this would lead to members gaining a sense of accomplishment if community recognizes a long-term gain in the intervention by noticing fewer mosquitoes in their homes. However it is questionable if this approach is realistic and if an affordable commercial product supported by a community engagement program wouldn’t be a better option.
This study provides extensive information on how communities of Coastal Tanzania perceive ATSBs. The information summarized here will be very useful for researchers designing future trials aimed at assessing the clinical and epidemiological benefits of using ATSBs in regards to malaria transmission. The ATSBs appearance was important to community members. More than 50% of the respondents disliked the shabby nature of a recycled-based bait and preferred if the baits would have a more official and colourful appearance that could easily associate it with mosquito control. Participants preferred placing the baits indoors because they believed most mosquitoes were indoors. Compliance with keeping a functional ATSB might be low if it needs frequent maintenance. Community members might not accept the new tool because they are unaware of how it works and are sceptical of its efficacy. It was noted that, after sensitization, participants understood the concept of ATSBs and were likely to accept the new way of killing mosquitoes. The introduction of ATSBs as a novel vector control paradigm in Tanzanian communities would require extensive community sensitization to avoid scepticism around the new concept and to ensure communities understand how the baits work and accept them in their daily lives.
MFM designed the experiment, assisted sensitization meetings, focus group discussion, and drafted the manuscript; FT assisted with experimental design, sensitization meetings, focus group discussion and commented on the final version of the manuscript; HN administered the field team, managed the project and commented on the manuscript; AK participated in the sensitization meetings, focus group discussions, was responsible for community training on ATSBs production and reviewed the final manuscript; DM, IB, AA led the community engagement, conducted the sensitization meetings, focus group discussions and reviewed the final version of the manuscript; AS undertook data collation, analysis and reviewed the final version of manuscript; AB developed the survey instruments and training methodology, was responsible for supervising the data collection, data analysis and commented on the manuscript. All authors read and approved the final manuscript.
The authors would like to thank the communities of Dunda, Kerege and Kiromo for their participation and support, especially the community health representatives in each village. In addition, the authors kindly thank all other staff members at International Development Consultants (IDC) and Ifakara Health Institute (IHI) for their support.
The authors declare that they have no competing interests.
Availability of data and materials
The datasets used and/or analysed during the current study are available from the corresponding author on reasonable request.
Consent for publication
All authors have read the final version of the manuscript and consented it for publication.
Ethics approval and consent to participate
The ethical approval for this study was provided by the Institutional Review Board of the Ifakara Health Institute (IHI/IRB/No: 32-2014) and the Tanzanian National Institute of Medical Research (NIMR/HQ/R.8a/Vol.IX/1895). Written informed consent was obtained from all participants.
The authors thank Grand Challenges Canada for funding this project (Grant Number 0555-01-10).
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Open AccessThis article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.
- O’Meara WP, Mangeni JN, Steketee RW, Greenwood B. Changes in the burden of malaria in sub-Saharan Africa. Lancet Infect Dis. 2010;10:545–55.View ArticlePubMedGoogle Scholar
- WHO. World malaria report. Geneva: World Health Organization; 2015.Google Scholar
- Bhatt S, Weiss DJ, Cameron E, Bisanzio D, Mappin B, Dalrymple U, et al. The effect of malaria control on Plasmodium falciparum in Africa between 2000 and 2015. Nature. 2015;526:207–11.View ArticlePubMedPubMed CentralGoogle Scholar
- Beier JC, Mueller GC, Gu W, Arheart KL, Schlein Y. Attractive toxic sugar bait (ATSB) methods decimate populations of Anopheles malaria vectors in arid environments regardless of the local availability of favoured sugar-source blossoms. Malar J. 2012;11:31.View ArticlePubMedPubMed CentralGoogle Scholar
- Muller G, Schlein Y. Sugar questing mosquitoes in arid areas gather on scarce blossoms that can be used for control. Int J Parasitol. 2006;36:1077–80.View ArticlePubMedGoogle Scholar
- Mueller GC, Beier JC, Traore SF, Toure MB, Traore MM, Bah S, et al. Field experiments of Anopheles gambiae attraction to local fruits/seedpods and flowering plants in Mali to optimize strategies for malaria vector control in Africa using attractive toxic sugar bait methods. Malar J. 2010;9:262.View ArticleGoogle Scholar
- Mueller GC, Beier JC, Traore SF, Toure MB, Traore MM, Bah S, et al. Successful field trial of attractive toxic sugar bait (ATSB) plant-spraying methods against malaria vectors in the Anopheles gambiae complex in Mali, West Africa. Malar J. 2010;9:210.View ArticleGoogle Scholar
- Mueller GC, Junnila A, Schlein Y. Effective control of adult Culex pipiens by spraying an attractive toxic sugar bait solution in the vegetation near larval habitats. J Med Entomol. 2010;47:63–6.View ArticleGoogle Scholar
- Mueller GC, Kravchenko VD, Schlein Y. Decline of Anopheles sergentii and Aedes caspius populations following presentation of attractive toxic (spinosad) sugar bait stations in an oasis. J Am Mosq Control Assoc. 2008;24:147–9.View ArticleGoogle Scholar
- Mueller GC, Schlein Y. Efficacy of toxic sugar baits against adult cistern-dwelling Anopheles claviger. Trans R Soc Trop Med Hyg. 2008;102:480–4.View ArticleGoogle Scholar
- Tenywa FC, Kambagha A, Saddler A, Maia MF. The development of an ivermectin-based attractive toxic sugar bait (ATSB) to target Anopheles arabiensis. Malar J. 2017;16:338.View ArticlePubMedPubMed CentralGoogle Scholar
- Qualls WA, Mueller GC, Traore SF, Traore MM, Arheart KL, Doumbia S, et al. Indoor use of attractive toxic sugar bait (ATSB) to effectively control malaria vectors in Mali, West Africa. Malar J. 2015;14:301.View ArticlePubMedPubMed CentralGoogle Scholar
- Stewart ZP, Oxborough RM, Tungu PK, Kirby MJ, Rowland MW, Irish SR. Indoor application of attractive toxic sugar bait (ATSB) in combination with mosquito nets for control of pyrethroid-resistant mosquitoes. PLoS ONE. 2013;8:e84168.View ArticlePubMedPubMed CentralGoogle Scholar
- EMA: Background review for the excipient boric acid In European Medicines Agency. Committe for Human Medicinal Products, vol. EMA/CHMP/765436/2012; London. 2015.Google Scholar