- Open Access
From river blindness control to elimination: bridge over troubled water
Infectious Diseases of Poverty volume 7, Article number: 21 (2018)
An estimated 25 million people are currently infected with onchocerciasis (a parasitic infection caused by the filarial nematode Onchocerca volvulus and transmitted by Simulium vectors), and 99% of these are in sub-Saharan Africa. The African Programme for Onchocerciasis Control closed in December 2015 and the World Health Organization has established a new structure, the Expanded Special Project for the Elimination of Neglected Tropical Diseases for the coordination of technical support for activities focused on five neglected tropical diseases in Africa, including onchocerciasis elimination.
In this paper we argue that despite the delineation of a reasonably well-defined elimination strategy, its implementation will present particular difficulties in practice. We aim to highlight these in an attempt to ensure that they are well understood and that effective plans can be laid to solve them by the countries concerned and their international partners.
A specific concern is the burden of disease caused by onchocerciasis-associated epilepsy in hyperendemic zones situated in countries experiencing difficulties in strengthening their onchocerciasis control programmes. These difficulties should be identified and programmes supported during the transition from morbidity control to interruption of transmission and elimination.
Please see Additional file 1 for translations of the abstract into the five official working languages of the United Nations.
According to the World Health Organization (WHO), at least 25 million people are currently infected with onchocerciasis (a parasitic infection caused by the filarial nematode Onchocerca volvulus), and 123 million people, 99% of them in sub-Saharan Africa, live in areas that put them at risk of infection [1, 2]. The parasite is transmitted by Simulium (blackfly) vectors which breed in fast-flowing waters, from which arises the name by which the disease is best known: River Blindness. As a consequence of onchocerciasis, before the inception of the African Programme for Onchocerciasis Control (APOC) in 1995, 10 million people suffered from its dermatological manifestations, with > 400 000 of them blind and 900 000 visually impaired . Studies have also reported a significant association between onchocerciasis and excess human mortality [4, 5], as well as between onchocerciasis and epilepsy [6,7,8]. Despite this, the proportion of persons suffering from onchocerciasis-associated epilepsy remains to be determined.
Major efforts to control River Blindness started with the establishment of the Onchocerciasis Control Programme in West Africa (OCP) in 1974. Through at least 14 years of weekly aerial spraying with larvicidal insecticides of the simuliid vectors’ riverine breeding sites, this programme succeeded in eliminating transmission (and hence the parasite) in virtually all of the ‘core’ savannah areas of the seven initial OCP countries [9, 10]. Subsequently, by integrating this vector control with yearly mass distribution of the (broad-spectrum) anti-parasitic drug ivermectin, onchocerciasis was also eliminated as a disease of public health importance from 10 of the final 11 West African OCP countries by the time the programme closed in 2002 . In some OCP foci, onchocerciasis was eliminated by (annual or biannual) mass drug administration of ivermectin even in the absence of vector control [12, 13].
Ivermectin (Mectizan®), a safe and efficacious anthelmintic with effects on the microfilarial stages (among others) of the parasite, was registered for onchocerciasis control in 1987, and is being donated by Merck Sharp & Dohme, MSD (known as Merck & Co. Inc. in the USA and Canada) for use in Africa, Latin America and Yemen for as long as necessary to eliminate the disease as a public health problem . To take advantage of this donation, many eye-care non-governmental organizations (NGOs) working with the governments of endemic countries began mass ivermectin treatment in the most heavily infected communities and particularly in Africa [15, 16]. APOC was established in 1995 to co-ordinate and extend these activities using Community-Directed Treatment with Ivermectin (CDTI) as its main strategy to increase ivermectin coverage, and it aimed to control onchocerciasis in 20 endemic countries outside the OCP [2, 17]. Before the start of APOC in 1995, 32 million people were infected with onchocerciasis, with > 100 million of these at risk . By 2014 (1 year before APOC’s closure), 112 million people were benefitting from CDTI, which averted annually the loss of 2 million Disability-Adjusted Life Years (DALYS) at a cost of only US$27 per DALY averted, making it very cost-effective . In 2010, APOC shifted its focus from control of the disease to its elimination  and, in 2012, the WHO, in its roadmap for “Accelerating work to overcome the global impact of neglected tropical diseases” (NTDs), set the goals of eliminating onchocerciasis in selected African countries by 2020 . Also in 2012, APOC’s Joint Action Forum expanded this goal to 80% of endemic countries with onchocerciasis eliminated by 2025 .
The aim of this paper is to argue that despite the development of a reasonably well-defined elimination strategy , its implementation will present difficulties in practice. We aim to highlight such difficulties, to try and ensure that they are well understood so that effective plans can be laid to solve them by the countries concerned and their international partners through technical support by the Expanded Special Project for the Elimination of Neglected Tropical Diseases (ESPEN), a newly created structure at WHO AFRO. A specific concern is the burden of onchocerciasis-associated disease that remains especially in hyperendemic zones situated in countries experiencing difficulties in strengthening their onchocerciasis control programmes. These difficulties need to be carefully identified and the programmes strongly supported during their transition from morbidity control to interruption of transmission and elimination.
Expanded Special Project for the Elimination of Neglected Tropical Diseases (ESPEN)
APOC closed in December 2015 and WHO has established a new structure, the Expanded Special Project for the Elimination of Neglected Tropical Diseases (ESPEN)  for the coordination of technical support for five NTDs in Africa, including onchocerciasis elimination activities. The elimination efforts include extending ivermectin treatment to hypoendemic (previously excluded) and operationally challenging areas, and also implementing intensive surveillance. According to recent estimates, this could save US$1.5–1.6 billion over 2013–2045 compared to the scenario in which onchocerciasis is controlled but not eliminated . The project’s plan includes the setting up of independent ‘national oversight committees’ for onchocerciasis elimination in all countries with onchocerciasis endemic foci, and recently in many countries such committees have been established. The committees operate under a variety of names (e.g. National Onchocerciasis Elimination Committee or NTD Technical Advisory Committee), and are in principle independent and advisory to the ministries of health, the decision makers which operate the national control programmes.
When the oversight committees are set up, their first task is to review the current epidemiological situation throughout the country. This often involves conducting new “elimination” prevalence surveys countrywide or in selected areas. Simultaneously, they try to define the so-called transmission zones in every part of the country (which will allow mapping of the hypoendemic areas where CDTI is to be instigated – usually twice a year) and identify sentinel sites for epidemiological and entomological surveillance. A transmission zone is a geographical area where transmission of O. volvulus occurs by locally breeding vectors and which can be regarded as a natural ecological and epidemiological unit for intervention . As soon as possible, the committees start to assess progress towards elimination in all of the transmission zones, and this assessment includes prevalence surveys and examination of CDTI coverage. This process should identify programmatic insufficiencies in CDTI projects already operating in meso- and hyperendemic areas and result in appropriate corrective action. After the national elimination programmes have finished this initial review period, they are expected to settle into a new phase whereby the oversight committee considers annual progress reports from each transmission zone and recommends as necessary to the Ministry of Health action to reach or accelerate elimination.
The expert advisory committees should be able to consider a country’s progress towards elimination in much greater detail than was possible by APOC. For instance, the Uganda Onchocerciasis Elimination Expert Advisory Committee has already played a major role in guiding the interruption of transmission in 15 of the 17 Ugandan foci. However, Uganda is a small country whose committee is very inclusive, with district vector control officers attending committee meetings, presenting their reports and participating in discussions. Furthermore, in Uganda there has been a history of interest in onchocerciasis, and hence there already existed significant expertise within the Ministry of Health. Besides, Uganda has benefitted from the early and effective establishment of its advisory committee with the support of The Carter Center . Many other countries (such as Liberia) have not had this historical head-start and may find it more difficult to make progress without significant external expertise and support. Also in large countries (Nigeria is an example) it will not be feasible to include Ministry of Health field operatives from all the districts as observers on the committee. ESPEN will have a role in the support of these expert committees which is mostly technical but in some cases also financial. However, ESPEN remains a small organisation and will not have the capacity to intervene directly in every endemic country.
Although the replacement of APOC by ESPEN has the potential advantage of generating a pan-African platform for integrated NTD control, the delays in organising ESPEN have also created some confusion and a temporary lack of direction. ESPEN has been mandated to cover five NTDs (onchocerciasis, lymphatic filariasis, schistosomiasis, soil-transmitted helminthiases and trachoma) with a budget that is far from generous. While it establishes itself, ESPEN has prioritised 14 countries for attention (Benin, Chad, Central African Republic, Comoros, Republic of Congo, Democratic Republic of the Congo, Ethiopia, Guinea, Guinea Bissau, Nigeria, São Tomé & Príncipe, South Sudan, Tanzania and Togo). However, these countries have been chosen from a consideration of all five NTDs, so several of the countries would not have been prioritised on the basis of onchocerciasis alone, and others which have significant onchocerciasis problems have not been included (such as Cameroon and Sierra Leone). This may restrict the budget available for effective onchocerciasis elimination efforts across the whole of Africa. A number of countries (such as the UK and the USA) have stepped in to try and fill the gaps by channelling direct country support through various organisations including NGOs (e.g., Sightsavers in the UK), but it is unclear whether this commitment will be sufficient and sustained until elimination. Whilst ESPEN’s onchocerciasis elimination plans include the expansion of CDTI to hypoendemic zones, there is a risk that the countries with already weak onchocerciasis control programmes may not receive the financial and technical support needed to implement and monitor onchocerciasis elimination programmes effectively.
Eliminating onchocerciasis – The progress so far
The shift from control to elimination requires a major change in thinking, planning, funding and national support. In the absence of complementary vector control strategies , achieving good geographic and therapeutic ivermectin coverage as well as minimising systematic non-compliance are essential for onchocerciasis elimination. The former refers to the proportion of communities and individuals within communities treated, and the latter to the proportion of individuals that never take treatment. To control onchocerciasis as a public health problem, APOC recommended a minimum ivermectin therapeutic coverage of 65%; however, for elimination ≥80% therapeutic coverage and 100% geographical coverage will be needed as already recommended .
Epidemiological models suggest that to achieve elimination solely by means of mass ivermectin treatment, the minimum required therapeutic coverage of 65–80% of the total population (aged ≥5 years) (equivalent to 80–95% among those eligible) must be attained and sustained over a long period whose duration depends, partly, on the baseline level of onchocerciasis endemicity, measured by initial microfilarial prevalence and load [26,27,28]. The ONCHOSIM and EPIONCHO models predict that the provisional operational thresholds for treatment interruption and initiation of surveillance (pOTTIS), suggested by APOC (2010) , can be reached by annual CDTI (total coverage 80%) within 14–17 years for mesoendemic regions, but may require > 17 years (ONCHOSIM) or > 25 years (EPIONCHO) for highly hyperendemic (holoendemic) foci . In both sets of simulations a 5% of systematic non-compliers was assumed and initial prevalences ranging from 50 to 90% were explored to cover the range from meso- to holoendemic onchocerciasis . However, such predictions may not apply in all endemic areas in Africa because of a) different Onchocerca–Simulium complexes, particularly for forest onchocerciasis ; b) a possible greater proportion of non-adherence to treatment, particularly in loiasis co-endemic areas [31, 32], and c) differences between the magnitude of the pOTTIS and the true transmission breakpoints [28, 33]. The higher the initial endemicity, the lower the true elimination thresholds and, therefore, the less useful the current pOTTIS are as indicative of ultimate elimination. Currently the pOTTIS have been taken as a microfilarial prevalence < 1.4% 1 year after the last treatment round (a weighted mean of the values proposed by APOC 2010 ), but they would have to be much more stringent in areas of high baseline endemicity. In addition, the recent WHO  elimination guidelines do not advocate the measurement of microfilarial prevalence (by skin snips) among the metrics on which to make decisions about stopping treatment and verifying elimination.
APOC was set up in 1995 as a control (morbidity-reduction) programme, and following the Conference on Eradicability of Onchocerciasis in 2002 , it was considered doubtful that elimination could be achieved in Africa with mass administration of ivermectin alone. The arguments put forward included the large size of onchocerciasis endemic areas, the fact that these areas are often contiguous, and that the members of the Simulium damnosum s.l. complex are highly efficient in transmitting O. volvulus. The same conclusions were reached by other authors after assessing the empirical evidence available at the time regarding the impact of repeated ivermectin mass treatments on parasitological and transmission indices in West Africa . At the time of that publication, data on 6-monthly treatments in Africa were sparse and did not allow conclusions to be drawn on the effectiveness of increased treatment frequency. However, elimination was thought to be possible in the Americas where onchocerciasis foci were often smaller and more circumscribed, and where some of the simuliid species involved in transmission have lower vector competence . Indeed, the Onchocerciasis Elimination Program for the Americas (OEPA) has succeeded in eliminating onchocerciasis from Colombia, Ecuador, Guatemala, Mexico, and parts of Venezuela , using mostly biannual (6-monthly, semi-annual) treatment with ivermectin, and quarterly treatments in some foci .
Despite the challenges in achieving good treatment coverage in Africa, there is now a general belief that onchocerciasis elimination should be ultimately feasible in most, if not all, endemic areas and there is empirical evidence to support this notion. In 2005, a longitudinal study in three initially meso- to hyperendemic onchocerciasis foci (with strongly seasonal transmission by S. sirbanum) in Mali and Senegal, where ivermectin had been distributed for 15–17 years, documented no evidence of transmission over a 3–5-year period after stopping treatment . Nevertheless, it should be noted that a recent evaluation study which covered some of the same areas (in the River Gambia focus of Senegal) found 7/279 children positive with antibodies for the Ov16 antigen (the marker of exposure/infection recommended by the recent WHO guidelines ). However, some of these results could be false positives and it is not yet clear whether this represents continuing autochthonous transmission or exposure to infective larvae through the bite of infective immigrant flies . Of interest is a study modelling elimination in the Malian and Senegalese foci of [12, 13], which discussed the possibility of (protracted) recrudescence in the River Gambia focus based on EPIONCHO projections . Other epidemiological studies in Kaduna State in Nigeria  and the Abu Hamed focus in Sudan  have reported interruption of transmission as a result of CDTI. Similarly, an international team of experts evaluated CDTI programmes which, between 2008 and 2014, provided ivermectin for at least 6 years; results from 12 countries showed that in areas with adequate annual ivermectin treatment coverage, satisfactory progress was made towards elimination and that 33 evaluation areas with a total population of 28 million people were close to, or had already reached, elimination . In other (East African) foci, interruption of transmission has been achieved through the disappearance of the local S. neavei vector , or by a combination of long-term ivermectin distribution and vector elimination .
Why onchocerciasis control remains difficult in certain areas
Issues affecting coverage and access to treatment
Achieving consistently high ivermectin treatment coverage remains a challenge and in several African countries, such as the Democratic Republic of the Congo (DRC), Central African Republic (CAR), Angola, Cameroon and South Sudan, onchocerciasis elimination may be out of reach in the near future . Onchocerciasis control has been difficult in those African areas with initial prevalence greater than 60%, especially if ivermectin is only distributed once a year. This is mainly due to the fact that higher endemicity levels require higher coverage and longer treatment durations. For example, by 2015, after 15 years of CDTI, onchocerciasis was reported to remain mesoendemic in the Centre and Littoral Regions of Cameroon . In the North and North-West of the country, the prevalence of onchocerciasis had dramatically decreased after 17 years of CDTI but elimination has certainly not yet been reached . In the DRC not even the target coverage for onchocerciasis morbidity control (of 65%) had been reached by 2012 , let alone the target coverage for elimination (80%).
Barriers to access to treatment and poor treatment compliance contribute to insufficient treatment coverage. Although ivermectin is provided free of charge, several onchocerciasis endemic regions still do not have good access to treatment. For example, people may not receive their annual treatment because of inadequate supply as a result of underestimation of population size , or because the community directed distributors (CDDs) of ivermectin do not visit remote and inaccessible areas. In Cameroon, the number of CDDs available to cover several large villages and zones was deemed too small . In Tanzania, lack of comprehensive understanding of the disease, fears of medication, distrust of the method determining dose, lack of health education materials, insufficient CDD-resident communication, and inflexible drug distribution mechanisms were identified as factors affecting community participation in the CDTI programme . In South Sudan the ivermectin distribution campaign has been disturbed by the war. Moreover, health care providers working in remote endemic zones may fail to diagnose onchocerciasis due to insufficient training and poor resources  and as a result, endemic zones where ivermectin needs to be distributed may be missed.
Political restructuring and inadequate assessment of onchocerciasis endemicity can contribute to reduced coverage. For example, in the Ituri Province in the DRC, the lack of implementation of a CDTI programme in certain villages was caused by the reorganization of the health territory which resulted into the subdivision of health zones into several health areas. The villages of Bessi, Draju, Kanga, Ndroyi, and Wala, in the past belonged to the health zone of Angumu (where, based on rapid epidemiological mapping of onchocerciasis (REMO) assessment, CDTI was needed). Later they were integrated into the Logo health zone, a zone where CDTI was considered not to be necessary and, therefore the population in these villages did not receive ivermectin (M. Mandro, pers. comm.).
In the majority of CDTI projects in Africa, reported coverage has been satisfactory and, by and large, increasing over time . However, ivermectin coverage is commonly calculated using the information provided by CDDs and such estimates can easily lead to over-estimation of coverage (particularly if population censuses are not regularly updated and the CDDs treat an increasing number of residents as populations grow but the denominators remain the same). Furthermore, coverage rates in a community may give a misleading picture of the success of control efforts; if there are individuals or large groups who systematically do not comply with treatment, they may provide a continued focus for transmission [26, 28, 31,32,33, 53] and make elimination of onchocerciasis an unattainable goal.
Issues affecting treatment adherence
In addition to inadequate access to treatment, onchocerciasis control efforts are further limited by poor compliance and uptake of ivermectin in some communities, among other factors, due to seasonal migration of workers at the time of ivermectin distribution, lack of incentives for CDDs, fear of side effects and distrust of CDDs . Similar observations were made in Mahenge in Tanzania, where it was reported (based on a household-based survey) that during the annual 2016 CDTI round, the majority of community members were away for farming; besides, in this locality fear of side effects was one of the main reasons for not taking ivermectin (B. Mmbando, unpublished data). Women in particular were more often non-compliers because of fear of sterility , and since less than 25% of CDDs are female , increasing this proportion may inspire women’s confidence in taking the treatment. In Cameroon, but something also observed in the DRC, certain people do not take the ivermectin orally because they use ivermectin to kill hair lice . In a village in the Bas Uele province of the DRC with a very high prevalence of epilepsy and high exposure to Onchocerca-infected blackflies, people had stopped taking ivermectin because of experiencing side effects and, according to information gathered during four focus-group discussions, having to pay for the treatment of these side effects (A. Rotsaert, unpublished data).
Treatment compliance has been associated with being male , living in an area for a longer time, and having social support . In some settings, older age is associated with ivermectin uptake , whilst in others younger people are more likely to have taken ivermectin . Positive beliefs about ivermectin that have been associated with treatment compliance include beliefs that ivermectin prevents onchocerciasis and blindness , induces intestinal worm expulsion, and increases vitality . Perceived personal risk of onchocerciasis [54, 55] and positive perceptions of the programme have also been associated with good treatment adherence, and those that perceive CDDs as doing their work well, or know at least one CDD in their village, are more likely to take treatment .
Ivermectin treatment in loasis co-endemic areas presents one of the most important challenges . Although considered a “safe” drug, administration of ivermectin to patients with both, onchocerciasis and loiasis, can result in severe adverse events (SAEs), including encephalopathy and death . Early identification and referral of cases of encephalopathy to a hospital to provide medical and nursing care is of paramount importance. Not surprisingly, a fear of SAEs is a major reason for non-compliance in onchocerciasis-loiasis co-endemic areas.
Sub-optimal responses to ivermectin
Studies in Ghana and Cameroon suggest the occurrence of the so-called sub-optimal (or atypical) responses to ivermectin. In these studies ivermectin still killed the microfilariae but seemed to have become less effective in reducing the fertility of the adult female worms . This resulted in a rapid reappearance of microfilariae and an increased risk of onchocerciasis transmission even when the frequency of treatment had been increased from annual to biannual . These, essentially phenotypic, studies have been recently complemented by genome-wide analysis of ivermectin responses by O. volvulus . This analysis suggests that the evolution of sub-optimal responses occurs via selective sweeps of pre-existing quantitative trait loci rather than via selection of relatively rare resistance-conferring mutation(s). The outcome is the accumulation of many alleles in a limited number of functional pathways that facilitate the recovery of adult female worm fecundity from the inhibitory effects of ivermectin. This is consistent with the observation that the microfilaricidal effect of ivermectin remains unaltered in sub-optimally responding populations, but that the difference between these and fully ivermectin-susceptible parasites resides in quantitative variation in the rate and extent to which microfilarial production is resumed after treatment .
Cross-border onchocerciasis transmission is another challenge for onchocerciasis control programmes that focus only on a narrowly-defined geographical area. Parasites can be reintroduced into an area where CDTI has good geographic and therapeutic coverage by immigrant humans (including refugees or seasonal migrants) or vectors from insufficiently controlled areas. Different vector species differ in their propensity to disperse and migrate. For example, S. neavei in Uganda is not known to disperse further than a few kilometres from its breeding sites, whereas S. damnosum s.str. can migrate (wind-assisted) up to 400 km in West Africa and carry parasites into controlled areas . Human and vector migrants can carry parasites across national borders and between foci within a country. The WHO recommends the use of transmission zones as the units of assessment because they are expected to be epidemiologically independent from each other as migration between them is deemed to be negligible . The mapping of transmission zones is, therefore, important for onchocerciasis elimination, but also problematic because patterns of migration (of vectors and humans) will be unique to each area and are very difficult to quantify and to map. One possibility may be through the use of parasite genetic markers to understand patterns of gene flow between populations, and recent advances in genomic analyses of O. volvulus may facilitate this .
Suggestions to improve weak onchocerciasis elimination programmes (Fig. 1)
Areas of insufficient onchocerciasis control need to be identified
Such areas are generally located in hard-to-reach areas and populations, including in insecure areas, and there is little information about the status of onchocerciasis control in those settings. In South Sudan, for example, the CDTI programme seems to have been interrupted and there is no recent information on the onchocerciasis situation in this country. Challenges in accessing remote or conflict-affected areas, combined with poor resources, mean that there is also the need for revision and development of methodologies that will enable rapid, reliable and cost-effective assessment of the onchocerciasis control situation. However, this is not exclusively an issue for hard-to-reach and insecure areas. Five of the six APOC evaluation areas that were identified by Tekle et al.  as having unsatisfactory treatment coverage had no accessibility or security problems, highlighting the importance of monitoring and evaluation in all areas. A high prevalence of epilepsy, and certainly a high incidence of new onset epilepsy in children and youngsters between the ages of 3 and 20 years, in an onchocerciasis endemic area should be a reason to assess the performance of the CDTI programme. In non-onchocerciasis endemic regions in Africa most of the seizures in persons with epilepsy start below the age of 5 years because of obstetric and perinatal problems. In highly onchocerciasis-endemic regions, a large number of individuals may present with seizures after the age of 5, with a peak onset of epilepsy between the age of 8 and 12 years. The latter type of epilepsy should be considered as an early-warning sign of onchocerciasis-associated epilepsy (OAE) (Table 1). Interestingly, the study by Walker et al.  reported that for a given microfilarial load, the relative risk of mortality was significantly greater in children (aged < 20 years) than in those aged 20 years and more.
Geographical coverage of ivermectin needs to be improved and adapted to different contexts
Ivermectin distribution strategies deployed in conflict-affected areas may need to be different from the classical approaches to distribution in non-conflict settings. This could be done through collaboration with local NGOs or international humanitarian organizations such as International Red Cross, whose volunteers are often present in war zones. Training additional CDDs and providing suitable means of transportation in difficult terrain may help to ensure that more people living in remote areas have access to ivermectin.
Treatment uptake and adherence need to be improved through sustainable community participation
An effective social marketing campaign raising awareness about ivermectin, onchocerciasis and onchocerciasis-associated morbidities (including OAE) may motivate people to take up treatment and also improve adherence. Social research on people’s attitudes and perceptions regarding ivermectin and onchocerciasis can be used to advise on advocacy implementation strategies and to identify contextually relevant messages to be used for advocacy campaigns. Population groups with poor treatment uptake and the reasons for this need to be identified. Social science-based research can identify those strategies that, in a given context, will help the shift from insufficient CDTI coverage and adherence to well-performing CDTI programmes.
Timing of CDTI rounds should be improved
Ivermectin distribution campaigns need to be well-planned to take place at a time that ensures that the drug is effectively deployed during the main parasite transmission seasons (if transmission is highly seasonal), while taking into account when people are likely to be present in their communities and available for receiving the treatment (e.g. not during farming/harvesting periods). If increased treatment frequency is implemented, then it is important that treatment is administered 6-monthly to effectively curtail the transmission to blackfly vectors of microfilariae reappearing in the skin. This requires good coordination of the distribution of the drug from central points of arrival and storage to the districts and communities. Providing treatment twice a year but without the necessary interim period of 6 months between treatment rounds negates the benefits of biannual treatment .
Representation of women among community distributors should be increased and the motivation and training of the CDDs should be monitored and maintained
Studies report that female CDDs may strengthen and improve performance of the CDTI programme, as women are more committed, persuasive, more patient and their reports are more accurate . Also, they may help to dispel misunderstandings about treatment and infertility among the women of the communities. However, a study in Uganda showed that it might be difficult for female CDDs to work effectively outside their own kinship zones and, also, that they may face more mistrust from the community than their male counterparts .
The motivation of CDDs and the empowerment of communities are essential for the success of CDTI. Therefore, CDTI needs to be tailored to adapt to local power structures and diverse cultural contexts. For instance, in Uganda traditional social systems are very strong in all rural communities; a kinship-enhanced CDTI strategy that adopts collective decision-making by community members was found to be more effective in achieving better treatment coverage and community participation than a classic CDTI approach, in which decisions are made primarily by community leaders without much involvement of community members [63, 64]. Improvement in treatment coverage observed in Uganda was largely attributable to involvement of kinship groups, avoidance of paying monetary incentives to the CDDs and the satisfaction with the programme of those who had been treated [63,64,65].
Maintaining commitment and motivation of CDDs is challenging, and reduced motivation may contribute to under-performance of CDDs. An appropriate form of compensation for CDDs largely depends on the context in which community leaders must agree to set their own terms of remuneration or locally appropriate incentives (e.g. currency, food or labour). In south-eastern Nigeria, lack of monetary incentives led to significant increases in CDD attrition , but in Plateau State the provision of monetary incentives to CDDs resulted in several problems, including complex logistics and making the position so desirable that community leaders often chose friends and relatives for the job . By contrast, in Uganda, a shift from in-kind payments towards monetary-oriented strategies helped to achieve adequate drug distribution in Kabarole district ; in contrast, avoidance of paying monetary incentives to the ivermectin distributors contributed to improved treatment coverage in ten other districts .
Compensation and motivation of CDDs is very much a local issue based on the value judgements of the CDDs. When decisions regarding CDTI are made collectively, by community members rather than by community leaders and health workers on behalf of the community members, the CDDs’ demands for monetary incentives decline  but, on the other hand, CDDs who work among non-relatives are more likely to demand monetary incentives than those who treat relatives .
Treatment frequency should increase to biannual wherever possible, particularly in highly endemic areas
Regarding treatment frequency, biannual ivermectin distribution has been shown to improve treatment uptake , provide at least one treatment round in the year to those who may have missed the previous round, and shorten the timeframes to elimination by reducing the transmission of microfilariae to vectors in the inter-treatment periods [26,27,28], proving to be cost-effective . Therefore, weak onchocerciasis control programmes, in particular, should be supported not only to increase their geographic and therapeutic coverage but also to implement biannual ivermectin distribution.
Approaches to the monitoring and evaluation of onchocerciasis control programmes should be improved
With ESPEN’s focus on onchocerciasis elimination, there is great need for improved approaches to the monitoring and evaluation of onchocerciasis control efforts. In 2016, the WHO published guidelines about how to make decisions concerning the stopping of CDTI and the evidence required for verification of interruption of transmission , but these guidelines do not provide enough information to advise countries as to how to monitor progress towards elimination. To this end, WHO has now created a working group to develop a programme managers’ guide.
The design of robust monitoring and evaluation activities and the preparation of clear guidance on these, including which data should be collected by programmes, are the subject of ongoing statistical and transmission dynamics modelling work. The various strands of this work include: i) refinement of sampling protocols (e.g. for parasitological, serological and entomological assessments with current tools); ii) incorporation as model outputs of potential additional diagnostic tools (e.g. novel markers of female worm reproductive activity); iii) use of statistically robust approaches for analysis and interpretation of results; iv) refinement of evaluation criteria and thresholds for safe cessation of mass treatment and verification of elimination; v) determination of optimal duration of post-CDTI and post-elimination surveillance periods; and vi) formulation of recommended strategies if achieving elimination proves difficult, or if infection is reignited or reintroduced [26, 28, 41, 70, 71].
Evaluation of progress can make use of skin snip surveys (still the gold standard for diagnosing active infection), and can be conducted in parallel with Ov16 seroprevalence surveys. However, if skin snips are used, particularly for epidemiological evaluations conducted after prolonged CDTI with good coverage, it is recommended to test snips using PCR-based methods to increase test sensitivity. Coverage surveys may not necessarily be the best indicators of onchocerciasis control programmatic effectiveness for the reasons discussed above and because of the insidious impact of systematic non-compliance. Albeit not of true diagnostic value for the determination of individual infection status, seroprevalence surveys using Ov16, especially if conducted at various time points after the start of CDTI, can provide important data to understand temporal (and spatial) trends in exposure patterns. In particular, the serological testing of children aged ≤10 years could be used as a tool for evaluating the performance of CDTI programmes (Table 2).
Testing for Ov16 can be done with an enzyme-linked immunosorbent assay (ELISA) method or with the newly developed rapid Ov16 diagnostic test. The rapid diagnostic test (RDT) has a lower sensitivity and specificity than the ELISA test, but is cheaper, easier to perform and provides an immediate result onsite . Ov16 point-of-care serosurveys in children aged up to 10 years have so far been used to decide whether onchocerciasis transmission has been interrupted [43, 45, 46], but they could also be used for programme evaluation. The WHO has proposed an Ov16 prevalence of 0.1% (upper confidence limit) in children below the age of 10 years as a suitable threshold for stopping ivermectin treatment , but in order to reach this threshold large sample sizes are required and the test specificity should be 100%. Recent modelling studies have sought to investigate the optimal age groups to be sampled under various scenarios of diagnostic performance using ONCHOSIM , while taking into account that a single threshold value may not be appropriate for all levels of initial endemicity (a similar problem arises with the pOTTIS not adequately reflecting the true underlying transmission breakpoints for different baseline endemicities) [26, 28]. Guidelines for using Ov16 serosurveys for programmatic performance evaluation would also need to be developed, and mathematical modelling can help in this endeavour.
As a case study, we performed a survey using the Ov16 RDT point-of-care test in the Mahenge area in Tanzania as part of a research project to study the relationship between the degree of onchocerciasis transmission and the incidence of epilepsy. A high prevalence of Ov16 seropositivity (41%; 95% CI = 34–48%) among children aged 7–10 years was observed in two villages that had a high prevalence of epilepsy (> 3%). In these villages, ivermectin had apparently been distributed for more than 19 years, and onchocerciasis had been considered to be well controlled according to reported treatment coverage data obtained during household surveys (in which about 76% of interviewed individuals stated having taken ivermectin during the previous year) (B. Mmbando, unpublished data). However, Tekle et al.  reported that the Mahenge focus had only 7 years of treatment with > 60% coverage by the time its evaluation by APOC was conducted, with a microfilarial prevalence of 10 – 45%, in agreement with our seroprevalence results.
How such Ov16 serosurveys should be performed in an ethical way as part of programme evaluation needs to be established. If, as seems likely, each country needs to obtain ethical approval for organising Ov16 serosurveys and if informed consent/assent needs to be obtained from each individual to be tested, the costs associated with the testing will be considerable.
Molecular xenomonitoring using blackfly head pools (to detect infection by L3 larvae) has been proposed by the scientific international community for evaluation of impact of onchocerciasis elimination programmes as it provides information on parasite transmission from vectors to humans. As elimination programmes progress, testing for blackfly bodies (abdomens plus thoraces) could provide additional and useful indicators of transmission from humans to vectors (i.e. uptake of live skin microfilariae that would otherwise be difficult to detect by skin snips or skin-snip PCR ). It is paramount that molecular xenomonitoring be conducted as part of epidemiological evaluations as it complements information provided by skin snips or other techniques . However, the technical expertise necessary to perform such entomological investigations in a satisfactory manner (designing well-suited sampling protocols; determining sample sizes, where to sample; when to sample; identifying biting simuliids to species, etc.) is currently lacking in many endemic countries.
Many entomologists with expertise in blackfly vectors have retired or moved to work in other, better funded fields, such as malaria. Therefore, there is an urgent need to train young African entomologists and motivate them to work on Simuliidae. Catching flies also poses the ethical problem of how best to do this. The recommended way is still by human landing capture, which also provides information on biting rates. In Ghana, we have tried a number of strategies, including host-dependent and host-independent catching methods [73, 75], and others have tried to develop and optimise (e.g. Esperanza window) traps that would obviate the need for human attractants [76, 77]. The advantage of human landing catches is their comparative value with the standardised methods used by the OCP . Also they provide the possibility of estimating biting rates and infective biting rates/transmission potentials [73, 75] rather than just proportions of flies infected/infective (which devoid of the context of vector density are non-informative of transmission intensity). As long as the vector collectors are recruited locally and are taking regular ivermectin treatment, the procedure is considered not to be harmful. Ideally, however, as large fly population samples are needed, and the sample size required may increase with decreasing infection levels in the human population, more efficient, non-hazardous, and large-scale sampling methods will be necessary. Recently, it has been reported that Esperanza traps may be effectively operated by community residents and represent a viable alternative to human landing collections for entomological surveillance of O. volvulus transmission .
If during regular programme evaluation issues with ivermectin uptake are identified, these should be picked up by the national elimination committees, which need to recommend corrective actions. These may include conducting a coverage verification study. If coverage is found to be satisfactory, human (and vector) migration studies may need to be undertaken. Parasite genetic studies may also need to be considered if Ov16 serosurveys suggest high levels of ongoing transmission despite long CDTI duration with good coverage. Studies need to investigate potential contributory factors to decreased ivermectin sensitivity and the impact that any potential ivermectin resistance may have on achieving onchocerciasis elimination . Most ivermectin resistance studies had focused on candidate genes (e.g. beta-tubulin) identified in ivermectin-resistant nematodes of farmed ruminants (e.g. ). Consequently, modelling work had explored the spread of (recessive) resistance in one locus-two allele systems (e.g. ). However, the recent work using genome-wide approaches described earlier has revealed that the phenotype of sub-optimal response to ivermectin is likely determined by quantitative trait loci with many genes contributing in a polygenic manner . Ongoing modelling studies are focussing on the impact of the latter upon onchocerciasis elimination (L.E. Coffeng, pers. comm.).
Treatment, care, and support for persons with onchocerciasis-associated morbidities should be enhanced
Because of the long-term onchocerciasis control programmes that have been in place (OCP, APOC, OEPA), the number of blind and visually impaired people due to onchocerciasis has decreased substantially as the incidence of infection has decreased (although prevalent cases of blindness still remain). The burden and psychosocial consequences of onchocercal skin disease have been well recognised [83, 84]. There is, however, still an important morbidity associated with onchocerciasis that has thus far been largely neglected by most health care systems, namely onchocerciasis-associated epilepsy (OAE). Onchocerciasis control programmes and burden of disease studies have not considered epilepsy among the sequelae of onchocerciasis (whose causal relationship is difficult to ascertain and thus most studies have been largely ecological [6,7,8]). This has resulted in the programmes not addressing this major public health problem and/or lacking the means of evaluating its burden and temporal/spatial evolution. Neurologists are not generally present in onchocerciasis-endemic regions and mental health initiatives only tend to consider (neuro) cysticercosis as the main parasitic disease causing epilepsy. It will become increasingly important that onchocerciasis control and mental health programmes work together. Thus both programmes should exchange surveillance data. Moreover, CDDs could play an important role in epilepsy surveillance systems, should these be established, in order to detect persons with new onset epilepsy early and refer them for treatment promptly. Even after implementing and strengthening effective onchocerciasis control programmes, those already affected will continue to suffer even after transmission has been interrupted.
OAE will potentially make the burden of onchocerciasis disease in Africa considerably greater than previously thought. Recent studies (in line with previous reports ) suggest that in onchocerciasis endemic regions, infection by O. volvulus may trigger epilepsy, with ivermectin effecting some protection against seizures [86,87,88]. This protection, however, may be only partial where ivermectin is given on an annual basis (because adult worms resume production of microfilariae after a few months). Further research needs to be conducted to ascertain the impact of ivermectin treatment on the incidence of epilepsy in prospective studies, but most likely biannual treatment will be necessary to suppress microfilarial load and potentially to have a maximal effect on the incidence of OAE. By eliminating onchocerciasis, it is anticipated that the incidence of OAE will decrease and with it, its burden of long-term disability. While technically, elimination strategies may not include OAE, it is important to document it, as it has an impact on compliance at the local level and is a major but underestimated factor of relevance for advocating the elimination of onchocerciasis.
Funding should be increased to support operational research and to help countries with weak onchocerciasis control to move towards elimination
In addition to ivermectin, the Alternative Treatment Strategies (ATS) document of APOC (2015)  also outlines the possibility of deploying other strategies (including focal vector control ) and therapies as they become available for safe use in humans (e.g. moxidectin; macrofilaricides in the pipeline) or when they are already available for other indications (e.g. doxycycline), as well as a number of test-and-treat options for areas co-endemic with loiasis, sub-optimal responses to ivermectin, or mop-up settings. In particular, co-endemicity with loiasis has represented a major impediment to the expansion and intensification of mass ivermectin treatment coverage and compliance for the reasons mentioned above. Inroads into such challenges have been made possible by recent technical advances in rapid loiasis diagnostics  for the identification of heavily microfilaraemic individuals at high risk of SAEs who would not be offered ivermectin. These, however, only represent a small fraction of the population (1–2%) . This strategy has proven safe and effective for the implementation of district-wide, community-based distribution of ivermectin in loiasis–onchocerciasis co-endemic areas in Cameroon . Large-scale implementation trials of these and other ATS require additional funding to evaluate not only their feasibility as a proof-of-concept but crucially their epidemiological impact and cost-effectiveness.
Countries and areas within countries that currently have under-performing onchocerciasis control programmes already suffer from under-staffed and under-resourced healthcare systems, and allocating scarce resources to improving onchocerciasis control may not be at the top of their public health agenda. It is imperative that OAE is well researched, its association with O. volvulus infection rigorously established and recognised, and that future burden of disease studies include its association with morbidity and mortality. We hope that recognising OAE as one of the most important onchocerciasis-associated morbidities and that assessing its burden on society will motivate public health decision makers to improve the performance and monitoring of CDTI programmes and also motivate funders to increase their support for actions towards the elimination of onchocerciasis.
The long-term aim of programmes against onchocerciasis should remain the interruption of its transmission. It is likely, however, that in several African countries this goal will not be reached in the 2020–2025 timeframes proposed by WHO and APOC. In view of the challenges associated with onchocerciasis control, ESPEN’s mandate should be expanded to include the strengthening of weak onchocerciasis control programmes. However, one of the major hurdles for ESPEN will be to reconcile the need for increased activities around the other four preventive chemotherapy NTDs under its remit with the specific requirements of a Pan-African scale elimination programme. If onchocerciasis is to be eliminated in Africa, it will be crucial for ESPEN to engage promptly and collaboratively with the international scientific community and major international funders as well as with other stakeholders to harness the all-essential technical and financial support that will be necessary to address this huge endeavour, identify areas where CDTI programmes are performing less well than they should, determine the reasons for this, and find novel ways of monitoring, evaluating and supporting the programmes, as well as identifying which, where, and when ATS should be deployed, as they become part of our armoury in the fight against River Blindness.
African Programme for Onchocerciasis Control
Alternative treatment strategies
Central African Republic
Community drug distributor
Community-directed treatment with ivermectin
- CI :
Disability-adjusted life year
Democratic Republic of the Congo
Enzyme-linked immunosorbent assay
Expanded Special Project for the Elimination of Neglected Tropical Diseases
Merck Sharpe and Dohme
Neglected tropical disease
Onchocerciasis Control Programme in West Africa
Onchocerciasis Elimination Program for the Americas
Polymerase chain reaction
Provisional operational thresholds for treatment interruption and initiation of surveillance
Rapid diagnostic test
Rapid epidemiological mapping of onchocerciasis
- s.l. :
Severe adverse event
United States of America
World Health Organization
Parasites – Onchocerciasis (also known as River Blindness). Onchocerciasis FAQs. https://www.cdc.gov/parasites/onchocerciasis/gen_info/faqs.html). Accessed 21 Mar 2018.
Noma M, Zouré HG, Tekle AH, Enyong PA, Nwoke BE, Remme JH. The geographic distribution of onchocerciasis in the 20 participating countries of the African Programme for onchocerciasis control: (1) priority areas for ivermectin treatment. Parasit Vectors. 2014;7:325.
Coffeng LE, Stolk WA, Zouré HG, Veerman JL, Agblewonu KB, Murdoch ME, et al. African Programme for onchocerciasis control 1995-2015: model-estimated health impact and cost. PLoS Negl Trop Dis. 2013;7(1):e2032.
Little MP, Breitling LP, Basáñez MG, Alley ES, Boatin BA. Association between microfilarial load and excess mortality in onchocerciasis: an epidemiological study. Lancet. 2004;363(9420):1514–21.
Walker M, Little MP, Wagner KS, Soumbey-Alley EW, Boatin BA, Basáñez MG. Density-dependent mortality of the human host in onchocerciasis: relationships between microfilarial load and excess mortality. PLoS Negl Trop Dis. 2012;6(3):e1578.
Kaiser C, Pion SDS, Boussinesq M. Case-control studies on the relationship between onchocerciasis and epilepsy: systematic review and meta-analysis. PLoS Negl Trop Dis. 2013;7(3):e2147.
Pion SDS, Boussinesq M. Significant association between epilepsy and presence of onchocercal nodules: case-control study in Cameroon. Am J Trop Med Hyg. 2012;86(3):557. (Comment on Kaiser C, Rubaale T, Tukesiga E, Kipp W, Kabagambe G, Ojony JO, et al. Association between onchocerciasis and epilepsy in the Itwara hyperendemic focus, West Uganda: controlling for time and intensity of exposure). Am J Trop Med Hyg. 2011;85(2):225–8.
Pion SDS, Kaiser C, Boutros-Toni F, Cournil A, Taylor MM, Meredith SE, et al. Epilepsy in onchocerciasis endemic areas: systematic review and meta-analysis of population-based surveys. PLoS Negl Trop Dis. 2009;3(6):e461.
Hougard JM, Alley ES, Yaméogo L, Dadzie KY, Boatin BA. Eliminating onchocerciasis after 14 years of vector control: a proved strategy. J Infect Dis. 2001;184(4):497–503.
Boatin BA, Richards FO Jr. Control of onchocerciasis. Adv Parasitol. 2006;61:349–94.
Boatin B. The Onchocerciasis Control Programme in West Africa (OCP). Ann Trop Med Parasitol. 2008;102(Suppl 1):13–7.
Diawara L, Traoré MO, Badji A, Bissan Y, Doumbia K, Goita SF, et al. Feasibility of onchocerciasis elimination with ivermectin treatment in endemic foci in Africa: first evidence from studies in Mali and Senegal. PLoS Negl Trop Dis. 2009;3(7):e497.
Traore MO, Sarr MD, Badji A, Bissan Y, Diawara L, Doumbia K, et al. Proof-of-principle of onchocerciasis elimination with ivermectin treatment in endemic foci in Africa: final results of a study in Mali and Senegal. PLoS Negl Trop Dis. 2012;6(9):e1825.
Colatrella B. The Mectizan donation program: 20 years of successful collaboration - a retrospective. Ann Trop Med Parasitol. 2008;102(Suppl 1):7–11.
Haddad D, Cross C, Thylefors B, Richards FO Jr, Bush S, Hopkins AD, et al. Health care at the end of the road: opportunities from 20 years of partnership in onchocerciasis control. Glob Public Health. 2008;3(2):187–96.
Drameh PS, Richards FO, Cross C, Etya’ale DE, Kassalow JS. Ten years of NGDO action against river blindness. Trends Parasitol. 2002;18(9):378–80.
World Health Organization. African Programme for onchocerciasis control: progress report, 2014-2015. Wkly Epidemiol Rec. 2015;90(49):661–74.
African Programme for Onchocerciasis Control. Conceptual and Operational Framework of Onchocerciasis Elimination with Ivermectin Treatment. World Health Organization; WHO/APOC/MG/10.1. 2010 http://www.who.int/apoc/oncho_elimination_report_english.pdf. Accessed 21 Mar 2018.
World Health Organization. Accelerating work to overcome the global impact of neglected tropical diseases. A roadmap for implementation. Geneva: World Health Organization; WHO/HTM/NTD/PCT/20121; 2012. http://www.who.int/neglected_diseases/NTD_RoadMap_2012_Fullversion.pdf. Accessed 21 Mar 2018.
African Programme for Onchocerciasis Control (APOC). Eighteenth Session of the Joint Action Forum. Bujumbura, Burundi. Final Communique. 2012. http://www.who.int/apoc/about/structure/jaf/Final_Communique_JAF_18_English_final_with_annexes.pdf. Accessed 21 Mar 2018.
World Health Organization/African Programme for Onchocerciasis Control. Report of the Consultative Meetings on Strategic Options and Alternative Treatment Strategies for Accelerating Onchocerciasis Elimination in Africa; WHO/MG/1520 2015 http://www.who.int/apoc/ATS_Report_2015.12.pdf. Accessed 21 Mar 2018.
Hopkins AD. Neglected tropical diseases in Africa: a new paradigm. Int Health. 2016;8(Suppl 1):i28–33.
Kim YE, Sicuri E, Tediosi F. Financial and economic costs of the elimination and eradication of onchocerciasis (River Blindness) in Africa. PLoS Negl Trop Dis. 2015;9(9):e0004056.
The Carter Center. Elimination committees. https://www.cartercenter.org/news/publications/health/river_blindness_elimination_committees.html. Accessed 21 Mar 2018.
World Health Organization. Report of the external mid-term evaluation of the African Programme for Onchocerciasis Control; JAF 16.8. 2010. http://who.int/apoc/MidtermEvaluation_29Oct2010_final_printed.pdf. Accessed 21 Mar 2018.
Basáñez MG, Walker M, Turner HC, Coffeng LE, de Vlas SJ, Stolk WA. River Blindness: Mathematical models for control and elimination. Adv Parasitol. 2016;94:247–341.
Winnen M, Plaisier AP, Alley ES, Nagelkerke NJ, van Oortmarssen G, Boatin BA, et al. Can ivermectin mass treatments eliminate onchocerciasis in Africa? Bull World Health Organ. 2002;80(5):384–91.
Stolk WA, Walker M, Coffeng LE, Basáñez MG, de Vlas SJ. Required duration of mass ivermectin treatment for onchocerciasis elimination in Africa: a comparative modelling analysis. Parasit Vectors. 2015;8:552.
O'Hanlon SJ, Slater HC, Cheke RA, Boatin BA, Coffeng LE, Pion SDS, et al. Model-based geostatistical mapping of the prevalence of Onchocerca volvulus in West Africa. PLoS Negl Trop Dis. 2016;10(1):e0004328.
Cheke RA. Factors affecting onchocerciasis transmission: lessons for infection control. Expert Rev Anti-Infect Ther. 2017;15(4):377–86.
Wanji S, Kengne-Ouafo JA, Esum ME, Chounna PW, Adzemye BF, Eyong JE, et al. Relationship between oral declaration on adherence to ivermectin treatment and parasitological indicators of onchocerciasis in an area of persistent transmission despite a decade of mass drug administration in Cameroon. Parasit Vectors. 2015;8:667.
Senyonjo L, Oye J, Bakajika D, Biholong B, Tekle A, Boakye D, et al. Factors associated with ivermectin non-compliance and its potential role in sustaining Onchocerca volvulus transmission in the west region of Cameroon. PLoS Negl Trop Dis. 2016;10(8):e0004905.
Turner HC, Walker M, Churcher TS, Osei-Atweneboana MY, Biritwum NK, Hopkins A, et al. Reaching the London declaration on neglected tropical diseases goals for onchocerciasis: an economic evaluation of increasing the frequency of ivermectin treatment in Africa. Clin Infect Dis. 2014;59(7):923–32.
World Health Organization/Department of Control of Neglected Tropical Diseases. Guidelines for stopping mass drug administration and verifying elimination of human onchocerciasis. Criteria and procedures. 2016; WHO/HTM/NTD/PCT/2016.1. http://apps.who.int/iris/bitstream/10665/204180/1/9789241510011_eng.pdf?ua=1. Accessed 21 Mar 2018.
Dadzie Y, Neira M, Hopkins D. Final report of the conference on the Eradicability of onchocerciasis. Filaria J. 2003;2(1):2.
Borsboom GJ, Boatin BA, Nagelkerke NJ, Agoua H, Akpoboua KL, Alley EW, et al. Impact of ivermectin on onchocerciasis transmission: assessing the empirical evidence that repeated ivermectin mass treatments may lead to elimination/eradication in West-Africa. Filaria J. 2003;2(1):8.
Basáñez MG, Churcher TS, Grillet ME. Onchocerca-Simulium interactions and the population and evolutionary biology of Onchocerca volvulus. Adv Parasitol. 2009;68:263–313.
World Health Organization. Progress towards eliminating onchocerciasis in the WHO region of the Americas: verification of elimination of transmission in Guatemala. Wkly Epidemiol Rec. 2016;91(43):501–5.
Rodríguez-Pérez MA, Lutzow-Steiner MA, Segura-Cabrera A, Lizarazo-Ortega C, Domínguez-Vázquez A, Sauerbrey M, et al. Rapid suppression of Onchocerca volvulus transmission in two communities of the southern Chiapas focus, Mexico, achieved by quarterly treatments with Mectizan. Am J Trop Med Hyg. 2008;79(2):239–44.
Wilson NO, Badara Ly A, Cama VA, Cantey PT, Cohn D, Diawara L, et al. Evaluation of lymphatic filariasis and onchocerciasis in three Senegalese districts treated for onchocerciasis with ivermectin. PLoS Negl Trop Dis. 2016;10(12):e0005198.
Walker M, Stolk WA, Dixon MA, Bottomley C, Diawara L, Traoré MO, et al. Modelling the elimination of river blindness using long-term epidemiological and programmatic data from Mali and Senegal. Epidemics. 2017;18:4–15.
Tekle AH, Elhassan E, Isiyaku S, Amazigo UV, Bush S, Noma M, et al. Impact of long-term treatment of onchocerciasis with ivermectin in Kaduna State, Nigeria: first evidence of the potential for elimination in the operational area of the African Programme for onchocerciasis control. Parasit Vectors. 2012;5:28.
Higazi TB, Zarroug IM, Mohamed HA, Elmubark WA, Deran TC, Aziz N, et al. Interruption of Onchocerca volvulus transmission in the Abu Hamed focus, Sudan. Am J Trop Med Hyg. 2013;89(1):51–7.
Tekle AH, Zouré HGM, Noma M, Boussinesq M, Coffeng LE, Stolk WA, et al. Progress towards onchocerciasis elimination in the participating countries of the African Programme for onchocerciasis control: epidemiological evaluation results. Infect Dis Poverty. 2016;5(1):66.
Katabarwa MN, Katamanywa J, Lakwo T, Habomugisha P, Byamukama E, Oguttu D, et al. The Imaramagambo onchocerciasis focus in southwestern Uganda: interruption of transmission after disappearance of the vector Simulium neavei and its associated freshwater crabs. Am J Trop Med Hyg. 2016;95(2):417–25.
Lakwo T, Garms R, Wamani J, Tukahebwa EM, Byamukama E, Onapa AW, et al. Interruption of the transmission of Onchocerca volvulus in the Kashoya-Kitomi focus, western Uganda by long-term ivermectin treatment and elimination of the vector Simulium neavei by larviciding. Acta Trop. 2017;167:128–36.
Kamga GR, Dissak-Delon FN, Nana-Djeunga HC, Biholong BD, Mbigha-Ghogomu S, Souopgui J, et al. Still mesoendemic onchocerciasis in two Cameroonian community-directed treatment with ivermectin projects despite more than 15 years of mass treatment. Parasit Vectors. 2016;9(1):581.
Njim T, Aminde LN. An appraisal of the neglected tropical diseases control program in Cameroon: the case of the national program against onchocerciasis. BMC Public Health. 2017;17(1):103.
Makenga Bof JC, Maketa V, Bakajika DK, Ntumba F, Mpunga D, Murdoch ME, et al. Onchocerciasis control in the Democratic Republic of Congo (DRC): challenges in a post-war environment. Tropical Med Int Health. 2015;20(1):48–62.
Akogun OB, Akogun MK, Audu Z. Community-perceived benefits of ivermectin treatment in northeastern Nigeria. Soc Sci Med. 2000;50(10):1451–6.
York KJ, Kabole I, Mrisho M, Berry DM, Schmidt E. Factors affecting community participation in the CDTI program in Morogoro, Tanzania. J Nurs Scholarsh. 2015;47(1):96–104.
Njim T, Ngum JM, Aminde LN. Cutaneous onchocerciasis in Dumbu, a pastoral area in the North-West region of Cameroon: diagnostic challenge and socio-economic implications. Pan Afr Med J. 2015;22:298.
Brieger WR, Okeibunor JC, Abiose AO, Ndyomugyenyi R, Wanji S, Elhassan E, et al. Characteristics of persons who complied with and failed to comply with annual ivermectin treatment. Tropical Med Int Health. 2012;17(7):920–30.
Lakwo TL, Gasarasi DB. Non-adherence to community directed treatment with ivermectin for onchocerciasis control in Rungwe district, Southwest Tanzania. East Afr Med J. 2006;83(6):326–32.
Nuwaha F, Okware J, Ndyomugyenyi R. Predictors for compliance with community directed ivermectin treatment in Bushenyi district of Uganda: qualitative results. East Afr Med J. 2004;81(2):92–6.
Yirga D, Deribe K, Woldemichael K, Wondafrash M, Kassahun W. Factors associated with compliance with community directed treatment with ivermectin for onchocerciasis control in Southwestern Ethiopia. Parasit Vectors. 2010;3:48.
Gardon J, Gardon-Wendel N, Demanga-Ngangue, Kamgno J, Chippaux JP, Boussinesq M. Serious reactions after mass treatment of onchocerciasis with ivermectin in an area endemic for Loa loa infection. Lancet. 1997;350(9070):18–22.
Osei-Atweneboana MY, Awadzi K, Attah SK, Boakye DA, Gyapong JO, Prichard RK. Phenotypic evidence of emerging ivermectin resistance in Onchocerca volvulus. PLoS Negl Trop Dis. 2011;5(3):e998.
Frempong KK, Walker M, Cheke RA, Tetevi EJ, Gyan ET, Owusu EO, et al. Does increasing treatment frequency address suboptimal responses to ivermectin for the control and elimination of river blindness? Clin Infect Dis. 2016;62(11):1338–47.
Doyle SR, Bourguinat C, Nana-Djeunga HC, Kengne-Ouafo JA, Pion SDS, Bopda J, et al. Genome-wide analysis of ivermectin response by Onchocerca volvulus reveals that genetic drift and soft selective sweeps contribute to loss of drug sensitivity. PLoS Negl Trop Dis. 2017;11(7):e0005816.
Vouking MZ, Tamo VC, Tadenfok CN. Contribution and performance of female community-directed distributors in the treatment of onchocerciasis with ivermectin in Sub-Saharan Africa: a systematic review. Pan Afr Med J. 2015;20:188.
Katabarwa MN, Habomugisha P, Agunyo S. Involvement and performance of women in community-directed treatment with ivermectin for onchocerciasis control in Rukungiri District, Uganda. Health Soc Care Community. 2002;10(5):382–93.
Katabarwa MN, Habomugisha P, Agunyo S, McKelvey AC, Ogweng N, Kwebiiha S, et al. Traditional kinship system enhanced classic community-directed treatment with ivermectin (CDTI) for onchocerciasis control in Uganda. Trans R Soc Trop Med Hyg. 2010;104(4):265–72.
Katabarwa NM, Richards FO Jr, Ndyomugyenyi R. In rural Ugandan communities the traditional kinship/clan system is vital to the success and sustainment of the African Programme for Onchocerciasis Control. Ann Trop Med Parasitol. 2000;94(5):485–95.
Katabarwa MN, Habomugisha P, Richards FO Jr. Implementing community-directed treatment with ivermectin for the control of onchocerciasis in Uganda (1997-2000): an evaluation. Ann Trop Med Parasitol. 2002;96(1):61–73.
Emukah EC, Enyinnaya U, Olaniran NS, Akpan EA, Hopkins DR, Miri ES, et al. Factors affecting the attrition of community-directed distributors of ivermectin, in an onchocerciasis-control programme in the Imo and Abia states of South-Eastern Nigeria. Ann Trop Med Parasitol. 2008;102(1):45–51.
Richards F Jr, Gonzales-Peralta C, Jallah E, Miri E. Community-based ivermectin distributors: onchocerciasis control at the village level in Plateau State, Nigeria. Acta Trop. 1996;61(2):137–44.
Kipp W, Burnham G, Bamuhiiga J, Weis P, Büttner DW. Ivermectin distribution using community volunteers in Kabarole district, Uganda. Health Policy Plan. 1998;13(2):167–73.
Katabarwa MN, Habomugisha P, Eyamba A, Byamukama E, Nwane P, Arinaitwe A, et al. Community-directed interventions are practical and effective in low-resource communities: experience of ivermectin treatment for onchocerciasis control in Cameroon and Uganda, 2004-2010. Int Health. 2016;8(2):116–23.
Lont YL, Coffeng LE, de Vlas SJ, Golden A, de Los Santos T, Domingo GJ, et al. Modelling anti-Ov16 IgG4 antibody prevalence as an indicator for evaluation and decision making in onchocerciasis elimination programmes. PLoS Negl Trop Dis. 2017;11(1):e0005314.
Verver S, Walker M, Kim YE, Fobi G, Wanji S, Boakye DA, et al. How can onchocerciasis elimination in Africa be accelerated? Modelling the impact of increased ivermectin treatment frequency and complementary vector control. Clin Infect Dis. (in press)
Golden A, Stevens EJ, Yokobe L, Faulx D, Kalnoky M, Peck R, et al. A recombinant positive control for serology diagnostic tests supporting elimination of Onchocerca volvulus. PLoS Negl Trop Dis. 2016;10(1):e0004292.
Lamberton PHL, Cheke RA, Winskill P, Tirados I, Walker M, Osei-Atweneboana MY, et al. Onchocerciasis transmission in Ghana: persistence under different control strategies and the role of the simuliid vectors. PLoS Negl Trop Dis. 2015;9(4):e0003688.
Botto C, Basáñez MG, Escalona M, Villamizar NJ, Noya-Alarcón O, Cortez J, et al. Evidence of suppression of onchocerciasis transmission in the Venezuelan Amazonian focus. Parasit Vectors. 2016;9:40.
Lamberton PHL, Cheke RA, Walker M, Winskill P, Osei-Atweneboana MY, Tirados I, et al. Onchocerciasis transmission in Ghana: biting and parous rates of host-seeking sibling species of the Simulium damnosum complex. Parasit Vectors. 2014;7:511.
Toé LD, Koala L, Burkett-Cadena ND, Traoré BM, Sanfo M, Kambiré SR, et al. Optimization of the Esperanza window trap for the collection of the African onchocerciasis vector Simulium damnosum sensu lato. Acta Trop. 2014;137:39–43.
Hendy A, Sluydts V, Tushar T, De Witte J, Odonga P, Loum D, et al. Esperanza window traps for the collection of anthropophilic blackflies (Diptera: Simuliidae) in Uganda and Tanzania. PLoS Negl Trop Dis. 2017;11(6):e0005688.
Walsh JF, Davies JB, Le Berre R, Grams R. Standardization of criteria for assessing the effect of Simulium control in onchocerciasis control programmes. Trans R Soc Trop Med Hyg. 1978;72(6):675–6.
Loum D, Katholi CR, Lakwo T, Habomugisha P, Tukahebwa EM, Unnasch TR. Evaluation of community-directed operation of black fly traps for entomological surveillance of Onchocerca volvulus transmission in the Madi-Mid North focus of onchocerciasis in northern Uganda. Am J Trop Med Hyg. 2017; https://doi.org/10.5465/ajtmh.17-0244. [Epub ahead of print]
Cupp EW, Mackenzie CD, Unnasch TR. Importance of ivermectin to human onchocerciasis: past, present and the future. Res Rep Trop Med. 2011;2:81–92.
Nana-Djeunga H, Bourguinat C, Pion SDS, Kamgno J, Gardon J, Njiokou F, et al. Single nucleotide polymorphisms in β-tubulin selected in Onchocerca volvulus following repeated ivermectin treatment: possible indication of resistance selection. Mol Biochem Parasitol. 2012;185(1):10–8.
Churcher TS, Basáñez MG. Density dependence and the spread of anthelmintic resistance. Evolution. 2008;62(3):528–37.
Wagbatsoma VA, Okojie OH. Psychosocial effects of river blindness in a rural community in Nigeria. J R Soc Promot Heal. 2004;124(3):134–6.
Ubachukwu PO. Socio-economic impact of onchocerciasis with particular reference to females and children: a review. Anim Res Int. 2006;3(2):494–504.
Kipp W, Burnham G, Kamugisha J. Improvement in seizures after ivermectin. Lancet. 1992;340(8822):789–90.
Colebunders R, Mandro M, Mokili JL, Mucinya G, Mambandu G, Pfarr K, et al. Risk factors for epilepsy in Bas-Uele Province, Democratic Republic of the Congo: a case-control study. Int J Infect Dis. 2016;49:1–8.
Colebunders R, Titulaer MJ. Nodding syndrome: preventable and treatable. Sci Transl Med. 2017;9(377)
Levick B, Laudisoit A, Tepage F, Ensoy-Musoro C, Mandro M, Bonareri Osoro C, et al. High prevalence of epilepsy in onchocerciasis endemic regions in the Democratic Republic of the Congo. PLoS Negl Trop Dis. 2017;11(7):e0005732.
Pion S, Kamgno J, Bakalar M, Bopda J, Chesnais C, D’Ambrosio M, et al. Cellscope-Loa: district-wide deployment of a point of care tool for the prevention of post ivermectin serious adverse events in Loa loa endemic areas. Am J Trop Med Hyg. 2016;95(5 Suppl):349–50.
Barbre KA, Kamgno J, Atsame J, Biholong BD, Rebollo MP, Zouré H. Asessing an important barrier to onchocerciasis elimination: determinants and characteristics of Loa loa infection and intensity in Cameroon and Gabon. Am J Trop Med Hyg. 2016;95(5 Suppl):347.
Kamgno J, Pion S, Bakalar M, Chesnais C, D’Ambrosio M, Kamkumo RG, et al. Test and not treat (TNT): a safe strategy to provide community-based treatment with ivermectin in Loa loa endemic areas. Am J Trop Med Hyg. 2016;95(5 Suppl):599.
Wilson N, Cantey PT, Likwela J, Feeser K, Gyamba NN, Muzinga J, et al. Epidemiological, clinical, and laboratory evaluation of onchocerciasis in an area of high prevalence - Tshopo project area, Democratic Republic of the Congo, 2014. Am Soc Trop Med Hyg 64th annual meeting. Philadelphia; 2015. http://www.abstractsonline.com/Plan/ViewAbstract.aspx?sKey=62c2e33c-2c63-415b-b560-92fbc42ea9f6&cKey=6b11f815-82ab-4f91-afea-b1dd5bcbd1f5&mKey=%7bAB652FDF-0111-45C7-A5E5-0BA9D4AF5E12%7d. Accessed 21 Mar 2018.
We thank Michel Mandro for providing information concerning the onchocerciasis situation in Ituri, DRC; Stephen Doyle for deliberations on the potential role of O. volvulus genomics in investigating transmission zones, Luc E. Coffeng for considerations on the role of modelling in assessing the potential impact of decreased ivermectin efficacy on the feasibility of onchocerciasis elimination, and John R. Williams for editorial comments on the revised version.
RC received funding for his work from the European Research Council (ERC grant No. 671055). MGB thanks the Wellcome Trust (grants Nos. 085133/Z/08/Z and 092677/Z/10/Z). The funders had no role in the writing of the manuscript or the decision to publish.
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Robert Colebunders is Professor of Infectious Diseases at the Global Health Institute, University of Antwerp, Belgium, with current research focussing on identifying the cause of nodding disease syndrome and epilepsy in onchocerciasis endemic regions. Maria-Gloria Basáñez is Professor of Neglected Tropical Diseases at the School of Public Health, Imperial College London, currently focussing on the development of NTD mathematical models and their application in public health policy and practice. At the time of contributing to this paper, Katja Siling was a research assistant at the Institute of Tropical Medicine of the University of Antwerp for a multi-disciplinary project investigating the link between onchocerciasis and epilepsy in Cameroon, Tanzania, and Uganda; she is currently pursuing a doctorate in public health at the London School of Hygiene and Tropical Medicine (LSHTM). Rory J Post is an expert on onchocerciasis vectors and their genetics, and member of a number of onchocerciasis elimination committees, with affiliations at the Liverpool John Moores University and the LSHTM. Anke Rotsaert is studying under the supervision of Prof Colebunders at the University of Antwerp. Bruno Mmbando is at the National Institute for Medical Research (NIMR), Tanzania, with research interests in vector-borne and infectious diseases of poverty. Patrick Suykerbuyk is a post-doctoral researcher at the Global Health Institute, University of Antwerp, working on the epidemiology and disease burden of NTDs. Adrian Hopkins was the director of the Mectizan Donation Program until 2016 and is now a consultant on neglected and disabling diseases of poverty.
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Colebunders, R., Basáñez, M., Siling, K. et al. From river blindness control to elimination: bridge over troubled water. Infect Dis Poverty 7, 21 (2018) doi:10.1186/s40249-018-0406-7
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