https://orcid.org/0000-0002-0597-0407
Figures
Abstract
Community-directed treatment with ivermectin (CDTi) is the primary strategy employed to control and eliminate human onchocerciasis in Ethiopia. After long-term mass distribution for onchocerciasis, ivermectin is expected to have additional benefits beyond the envisioned targets by reducing the burden of other co-endemic parasitic infections as to STHs. To date, studies focused on the collateral impact of CDTi on STH in Ethiopia are scanty. Two community-based cross-sectional surveys (baseline in 1997 and post-CDTi in 2017) were conducted to evaluate the impact of long-term CDTi employed to control and eliminate onchocerciasis on the burden of STH infections in Yeki district of southwest Ethiopia. Stool samples were collected and examined using Ritchie`s concentration and Kato-Katz techniques in the baseline and current study, respectively. Overall, 188(38.3%, 95% Confidence interval (CI) 34.1–42.7%) individuals were positive at least for any of the STH species from 491 study participants in the post-CDTi. The prevalence of A. lumbricoides, hookworms, and T. trichiura was 11.2% (95% CI 8.7–14.3%), 16.3% (95% CI 13.3–19.8%), and 29.9% (95% CI 26.1–34.1%), respectively. Individuals aged 5–9 years had a significantly higher prevalence of A. lumbricoides (Adjusted odds ratio (AOR) 6.5, 95% CI 1.7–25.4), T. trichuria (AOR 8, 95% CI 2.6–25.1), and any STH infection (AOR 5, 95% CI 1.7–14.7) than those of ≥ 51 years. Also, significantly higher prevalences of T. trichuria infection were observed in individuals aged 10–14 years (AOR 4.1, 95% CI 1.7–9.9), 15–20 years (AOR 3.1, 95% CI 1.2–8.1), 21–30 years (AOR 2.4, 95% CI 1.1–5.5), and 31–40 years (AOR 3.2, 95% CI 1.3–7.5) compared with those of ≥ 51 years. The prevalence of A. lumbricoides was significantly higher in males (AOR 0.5, 95% CI 0.3–0.9). Of the 491 study participants, only data from 400 individuals who had not been involved in a mass drug administration (MDA) with other STH anthelmintics were considered in the comparative analysis. Before CDTi, the prevalence of A. lumbricoides, T. trichiura, hookworm, and any STH infection was 47.1% (95% CI 41.6–52.7%), 3.3% (95% CI 1.8–5.9%), 37.9% (95% CI 32.7–43.5%), and 58.8% (95% CI 53.2–64.1%), respectively. Long-term CDTi considerably reduced the prevalences of A. lumbricoides and hookworm by 76.2% and 56.9%, respectively (p < 0.001). Nonetheless, CDTi did not affect the prevalence of T. trichiura infection and, in contrast, it was significantly higher in the current study (P < 0.001). Overall post-CDTi prevalence of any STH infection was considerably lower than reported in the baseline (p < 0.001). It is evidenced that long-term CDTi for onchocerciasis control and elimination had additional benefits by reducing the prevalence of STH infections specifically of A. lumbricoides and hookworm, but had no impact on infections with T. trichuria. Our finding of additional health benefits of large-scale ivermectin administration taking it will aid to increase positive engagement and sustain participation of communities during MDA campaigns, and strengthen governmental and non-governmental organizations (NGOs) support for the undergoing national onchocerciasis elimination program.
Citation: Gebrezgabiher G, Yewhalaw D, Ayana M, Hailu A, Mekonnen Z (2022) Impact of ivermectin mass drug administration on burden of soil-transmitted helminths in onchocerciasis control and elimination programs, Yeki district, southwest Ethiopia. PLoS ONE 17(2): e0263625. https://doi.org/10.1371/journal.pone.0263625
Editor: Alireza Badirzadeh, Iran University of Medical Sciences, ISLAMIC REPUBLIC OF IRAN
Received: September 27, 2021; Accepted: January 21, 2022; Published: February 10, 2022
Copyright: © 2022 Gebrezgabiher et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: DY, ZM, GG. The research was funded by the Institute of Health, Jimma University. The funder had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
List of abbreviations: AOR, Adjusted odds ratio; CDTi, Community-Directed Treatment Ivermectin; CI, Confidence Interval; epg, eggs per gram; ESPEN, Expanded Special Project for the Elimination of Neglected Tropical Diseases; DALYs, Disability Adjusted Life Years; MDA, Mass Drug Administration; NGO, non-governmental organization; NTDs, Neglected Tropical Diseases; OR, Odds ratio; SAC, School-aged Children; SNNPR, South Nations Nationalities Peoples Region; STH, Soil-transmitted Helminth; WHO, World Health Organization
Introduction
Soil-transmitted helminth (STH) infections, caused by a group of parasitic nematode worms commonly known as roundworms (Ascaris lumbricoides), whipworms (Trichuris trichiura), and hookworms (Ancylostoma duodenale and Necator americanus), is the most common type of infection worldwide [1]. An estimated 5.3 billion people are at risk, while 1.5 billion are infected with at least one of the STH species [2]. The most significant number of infection cases occur in tropical and sub-tropical regions of the developing world where adequate supply of water and sanitation is lacking, mainly in rural areas of sub-Sahara Africa, the Americas, Southeast Asia, and China [3]. The morbidity of STH is directly linked to the number of worms harboured by infected individuals [4]. The higher the number of worms in an infected person, the more it causes severe morbidity [5], including abdominal pain, diarrhea, blood and protein loss, rectal prolapse, and physical and cognitive growth retardation particularly in school-aged children (SAC) [6]. In 2017, the global burden of infections with STH was estimated to be 1.9 million disability-adjusted life years (DALYs) [7].
Ethiopia is one of the countries in sub-Sahara Africa where the enormous burden of STH infections is found [8]. STH infections are distributed widely throughout the country [9] with varied prevalence rates between geographical areas [10]. The nationwide mapping of STH and schistosomiasis conducted in 2014 and 2015 demonstrated that out of 833 country’s districts 741 are endemic for STHs [9, 11]. It is estimated that 79 million people live in STH endemic areas, which comprised 9.1 million pre-school-aged children, 25.3 million SAC, and 44.6 million adults [9, 11]. STHs are responsible for significant morbidity, for example, STHs caused an estimated loss of 82.7 thousand DALYs in 2015, representing 14.3% of the total DALYs lost because of all Neglected tropical diseases (NTDs) [12].
Ivermectin also known as Mectizan®, a product of Merck & Co, Inc., is a drug of choice to control human onchocerciasis [13], a skin disfiguring and blinding disease caused by infection with the filarial worm Onchocerca volvulus that affected millions of people in tropical areas [14]. Since registered for human use against onchocerciasis in 1987 the manufacturer Merck & Co Inc., donated free of charge [15] to any government or non-governmental organization (NGO) involved in onchocerciasis control. Accordingly, it has been extensively used in mass drug administration (MDA) to control the disease across Africa, where over 99% of all the onchocerciasis cases in the world were historically documented [16, 17]. Yet, it is the only drug being in use in the current World Health Organization (WHO) AFRO Region Expanded Special Project for the Elimination of Neglected Tropical Diseases (ESPEN) program for onchocerciasis elimination [18]. The primary effects of ivermectin are against skin microfilariae [19, 20]. It is a potent microfilaricidal and partially embryostatic agent after frequent application [21–23]. In fact, it is a broad-spectrum anti-helminthic drug that also impacts other co-endemic parasitic infections [14, 24]. Several authors in different parts of the world reported the impact of ivermectin against STHs [5, 25–32].
Community-wide mass ivermectin treatment (also referred to as Community-directed treatment with ivermectin: CDTi) is the primary strategy for controlling and eliminating onchocerciasis in Ethiopia. The program was launched in 2001 in 16 highly endemic districts of Kaffa-Sheka zone in South Nations Nationalities Peoples Region (SNNPR) [9, 33], later expanded to other areas and continued to the present day as part of the national efforts to interrupt transmission of O. volvulus infection [34].
An epidemiological survey carried out before the launch of CDTi in communities of Yeki revealed that STHs were highly endemic and found co-morbid with onchocerciasis [35]. We hypothesized that the ongoing mass ivermectin treatment for onchocerciasis could have an additional benefit/collateral impact to the communities taking the drug by preventing or reducing part of the burden related to STH infections. These additional benefits of ivermectin are being used to sensitize communities to participate in CDTi campaigns. To date, studies focused on the collateral impact of CDTi on STH in Ethiopia are scanty, except Taticheff and his colleagues [36] that attempted to investigate the effect of repeated ivermectin treatment in Bebeka coffee plantation in southwest Ethiopia during the early period of CDTi. The ancillary health impact of long-term mass ivermectin treatment has not been quantitatively measured till now, and its impact remains unknown. It is of interest to know whether the population living in communities of onchocerciasis endemic areas are being benefited from the ongoing long-term CDTi program by reducing the prevalence of STH infections. Therefore, this study was conducted to estimate the burden of STH and assess the impact of the long-term CDTi program in reducing the prevalence of STH in communities of Yeki district of SNNPR of southwest Ethiopia compared to STH prevalence data collected before the launch of the program.
Materials and methods
Study setting
Two community-based cross-sectional surveys were carried out in communities of Yeki district of SNNPR of southwest Ethiopia. The baseline survey before the launch of ivermectin distribution for onchocerciasis control and the second after more than 15 years of CDTi in similar communities of the study district. Yeki is located at 7°14’60’’ latitude, 35°24’60’’ longitude, and an altitude of 1200 meters above sea level representing a low altitude. Characterized by hot and humid climate, Yeki district has an average annual rainfall of 1700 millimeters and a monthly temperature ranging from a minimum of 14.7–17.7°C to a maximum of 26.2–31.4°C. A detailed geographic description of the study area is available elsewhere [37]. The CDTi program launched in Yeki district in 2001 and was administered annually until 2012. In 2013, the program shifted to biannual MDA as part of the efforts to achieve the elimination of onchocerciasis. Yeki district was selected for this study because STH prevalence data were collected before the launch of CDTi for control of onchocerciasis to be used as baseline data. Moreover, STH control program is at its early stage of implementation in Yeki district of SNNPR. The program was launched in February 2016 as a biannual MDA campaign targeting SAC. Before this study, only three rounds of MDA were conducted (two rounds in 2016 and one in 2017). It is delivered through school and community-based deworming program. Adisberhan kebele based on the presence of pre-CDTi STH prevalence data and seven other nearby kebeles with similar ecology, and socio-economic activities (Bechi, Fide, Kubito, Michi, Shosha, Selamber, and Zinki) were purposively selected for this study (Fig 1).
QGIS version 3.10, a free and open source GIS software, was used to generate the map of the study area [38]. The spatial data referring to the study sites are acquired using a handheld GPS device (Garmin’s GPSMAP 60CSx, Garmin International Inc., Olathe, Kansas, USA) during sample collection. The administrative spatial data (Open Street Map shapefile) used to prepare this study map was downloaded from GADM (https://gadm.org/download_country_v3.html), which is free and open source database of global administrative areas.
Surveys and sample processing
In May 1997, the first survey was carried out in a population aged 10 years old and above (n = 308), who lived in communities of Yeki district at least for five years [35]. Community members aged ten years and above were informed through community leaders and health workers to come to a village clinic. The purpose of the study was explained and asked to voluntarily participate in the study. After obtaining a verbal consent from each study participant (parents or guardians in case of children), slightly more than one gram of freshly excreted stool sample was collected and preserved in 10% formalin in screw-capped vials. The samples were processed by Ritchie’s concentration technique, and the concentrate was examined under a microscope for the presence of parasite eggs [35]. The detailed laboratory procedure is available elsewhere [39].
From the third week of October to the end of November 2017, another cross-sectional survey was carried out in the area where the previous survey was performed. Stool samples were collected during a CDTi coverage verification survey in the district, which included the kebeles in this study. This study used the same household sampling technique as the CDTi coverage survey. Briefly, a systematic sampling of households was carried out, with the sampling interval determined by dividing the total number of households in each kebele by the sample size assigned to each kebele. After the purpose of the study was explained to them, household members who volunteered to participate in the study gave their voluntary consent and a face-to-face interview was done to obtain socio-demographic data (sex, age, religion, and ethnicity) and their ivermectin treatment status in the last round of the CDTi campaign in 2017. Next, a clean plastic screw-cup container pre-labeled with the individual’s code was provided to all voluntary participants. The participant was instructed to scoop a thumb-sized stool sample using a provided scoop into the container. Parents and guardians were instructed to guide their children during the sample collection to ensure that children placed their stool samples into the container. The next morning, the containers with stool samples were collected and placed into a zip-locked plastic bag. Stool samples were examined with the Kato-Katz technique [40], a WHO-recommended diagnostic method for identifying and quantifying STH eggs in stools [41], which consist of a single thick smear technique with a 41.7mg template that allows a standardized amount of stool to be examined and eggs to be counted [42]. The samples were examined by a qualified laboratory technician within one hour after slides’ preparation to ensure that all STH species potentially present in the preparation should be identified. All eggs found in the preparations were identified and counted and the results were expressed as eggs per gram (EPG) of stool to express the intensity of the infection.
Ethical consideration
The study obtained ethical approval from the Institutional Review Board of the Institute of Health Jimma University (RPGC/170/06). The aim of the study was explained to the study participants, and they were informed that they are free to participate. Informed written consent was obtained for those age 18 and above, or from parents or guardians for participants less than 18 years. Permission was obtained from the Zonal Health Bureau, District Health Bureau, and Kebele Authorities. The collected information was kept confidential in compliance with established Human Subject Protection guidelines.
Statistical analysis
All data were checked, cleared, and entered in Microsoft Excel Sheet (2013 Microsoft Corporation). Statistical analyses were performed using RStudio version 3.2.3 software. Descriptive statistics were used to summarize the socio-demographic characteristics of study participants. Prevalence of STH infection was expressed as the mean proportion of individuals testing positive out of total examined with a 95% confidence interval (CI). The quantity of STH eggs was counted and calculated following WHO [43], and the infection intensity of each species was stratified into three categories (light, moderate, and heavy) [43]. The prevalence of STH infections was determined following disaggregated by sex and age group. Multivariate logistic regression analysis was used to calculate the odds ratio and the 95% CI to observe the risk associations between STH infections and the variables used. The difference in the prevalence of STH infections between baseline and post-CDTi studies was calculated, means were compared using the Chi-Square test and p-value ≤ 0.05 was considered significant during the analysis.
Results
Socio-demographic characteristics of study participants
Of 512 study participants who agreed to participate, 495 (96.7%) provided stool samples. The samples from four participants were not adequate and were not processed. Stool samples from 491individuals were processed. Of these, 55.4% (272/491) were females. The study participants’ age ranged from 5–80 years. It was shown that 30.5% (150/491) of the study participants were in the age range of 21–40 years. As per interviewees’ declarations, 90.6% (445/491) of the study participants reported they took ivermectin in the last rounds of the CDTi campaign in 2017. Table 1 shows the socio-demographic characteristics of the study participants.
Trend of reported CDTi coverage
Community drug distributors (health extension workers) report CDTi coverage rates to the district health office following every ivermectin distribution campaign. Consecutive registers of community drug distributors show high CDTi coverage rates (above 80%, which is the minimum threshold for the elimination of onchocerciasis) were achieved in most of the MDA rounds in Yeki district of SNNPR. Fig 2 depicts the trend of reported CDTi coverage rate in Yeki District since the launch of the program in 2001.
(Source: Yeki district health office).
Prevalence and intensity of STH infections
Overall, 188(38.3%, 95% CI: 34.1–42.7%) individuals were at least positive for any of STH species (Table 2). The presence of three species of STH: A. lumbricoides, hookworm and T. trichiura was 55(11.2%, 95% CI: 8.7–14.3%), 80(16.3%, 95% CI: 13.3–19.8%), and 147 (29.9%, 95% CI: 26.1–34.1%), respectively. Moreover, 112 (22.8%, 95% CI: 19.3–26.7%) and 76 (15.5%, 95% CI: 12.6–18.9%) of the infected individuals had single and mixed infections, respectively. Among the study participants with mixed infections, double and triple STH infections were detected in 58(3.4%; 95% CI: 2.3–5.7%) and 18(3.7%; 95% CI: 2.3–5.7%), respectively (Table 2).
Results of multivariate logistic regression analysis showed that study participants aged 5–9 years had a significantly higher prevalence of A. lumbricoides (Adjusted odds ratio (AOR) 6.5, 95% CI 1.7–25.4, p = 0.007), T. trichuria (AOR 8, 95% CI 2.6–25.1, p<0.001), and any STH infection (AOR 5, 95% CI 1.7–14.7, p = 0.003) than the older counterparts (≥ 51 years). Similarly, a significantly higher prevalence of T. trichuria infection was observed in individuals in the age ranges of 10–14 years (AOR 4.1, 95% CI 1.7–9.9, p = 0.002), 15–20 years (AOR 3.1, 95% CI 1.2–8.1, p = 0.021), 21–30 years (AOR 2.4, 95% CI 1.1–5.5, p = 0.037), and 31–40 years (AOR 3.2, 95% CI 1.3–7.5, p = 0.009) compared with ≥ 51 years old. There was no significant association between sex and infection rates of either specific species of STH or any STH infection, except A. lumbricoides, where the prevalence of infection was significantly lower in females than in males (AOR 0.5, 95% CI 0.3–0.9, p = 0.022) (Table 3).
Most of the study participants (79.8%, 95%CI 73.5–84.9%) had light STH infection, while the remaining 38(20.2%, 95%CI 15.7–27.5%) had a moderate infection. Light intensity of infection was detected in 50(90.9%, 95%CI 80.4–96.1%), 120(81.6%, 95%CI 74.6–87.1%), and 68(85%, 95%CI 75.6–91.2%) for A. lumbricoides, T. trichuria, and hookworms, respectively, while moderate infection intensity for A. lumbricoides, T. trichuria, and hookworm was observed in 5(9.1%,95%CI 3.9–19.6%), 27(18.4%, 95%CI 12.9–25.4%) and 12(15%, 95%CI 8.8–24.4%), respectively. None was infected with heavy infection.
Impact of CDTi on prevalences of STH infections
Table 4 compares the baseline and post-CDTi STH prevalence data based on the age of the study participants. SAC are involved in the recently launched MDA program against STH in Yeki. For comparison of the current prevalence rates of any helminth infection with the baseline prevalence, study participants younger than 15 years were excluded and only data from 400 individuals were considered for analysis. Before the launch of CDTi, the overall prevalence of any STHs was 58.8% (95% CI 53.2–64.1%) (181/308) [35]. Overall, a decline in the prevalence of any STH infection was observed in the current study compared to the baseline within all age groups, however, the decline in the prevalence of any STH infection was significant only in the age group of 21–30 years (p = 0.03).
Before CDTi, 145(47.1%, 95% CI 41.6–52.7%), 10(3.3%, 95% CI 1.8–5.9%), and 117(37.9%, 95% CI 32.7–43.5%) individuals had A. lumbricoides, T. trichiura, and hookworms, respectively [35]. Long-term CDTi considerably reduced the prevalences of A. lumbricoides and hookworm infections by 76.2% and 56.9%, respectively (p < 0.001). However, one most interesting observation was the CDTi did not appear to reduce the prevalence of T. trichiura infection and, in contrast, it was significantly higher in the current study (p < 0.001). Overall, the prevalence of any STH infection was considerably lower than reported in the baseline (p < 0.001). Fig 3 shows the baseline and post-CDTi prevalences of STHs in the study district.
Discussion
STH infection is the most common and persistent parasitic infection worldwide mainly in tropical and sub-tropical areas of the developing world where adequate water supply and sanitation are lacking [3]. Ethiopia is among the countries in sub-Sahara Africa having the highest burden of STH [44] and have enormous consequences on the health and educational performance of SAC [9]. The WHO`s STH control strategy emphasizes controlling STH morbidity through periodic MDA with a single dose of albendazole or mebendazole to the population at risk of infection [45]. The frequency of MDA is based on the overall prevalence of STH, annual when the prevalence is 20–50%, and biannual when the prevalence is above 50% [46].
The success of the onchocerciasis control and elimination program is evaluated by its impact on O. volvulus prevalence and intensity. In Yeki district of SNNPR, where CDTi has been running from 2001–2017, the program has noticeably reduced O. volvulus prevalence to zero [37]. Data collected before the launch of CDTi from this area showed that STH were highly endemic and many individuals were detected concomitantly infected with both STH and onchocerciasis [35]. After the long-term mass ivermectin distribution for onchocerciasis, the health benefits of CDTi beyond the envisioned targets for example to STH can be confirmed. Thus, evaluating the collateral public benefits of CDTi in reducing the prevalence of co-endemic STH infections is crucial for implementing further interventions and investments from donor organizations and strengthening governmental and community support for the undergoing national onchocerciasis elimination program.
The present study revealed the prevalence of A. lumbricoides, T. trichiura, and hookworm infections were 11.2%, 29.9%, and 16.3%, respectively. The overall prevalence of any STH infection was 38.3%, indicating that STH infection is still a public health problem in the study area. This was considerably lower than findings reported from nearby areas where annual/biannual CDTi is also being implemented [47, 48]. We observed a significantly higher prevalence of A. lumbricoides, T. trichiura, and any STH infection among individuals of age range 5–9 years compared with infection in study participants aged 51 years and above. Commonly, children (especially SAC) are at high risk of STH infections [43]. Moreover, a significantly higher proportion of adults in the study district harbour T. trichiura infection, therefore, might be contributing to ongoing transmission of infection in the area. In agreement with previous findings [32, 49], we did not observe a significant difference in any STH infection between males and females. This could be because both males and females might have similar exposure to STH [32, 49].
Our study documented that long-term CDTi is significantly associated with a decreased prevalence of A. lumbricoides and hookworm infections. An earlier study that evaluated the long-term impact of annual CDTi for onchocerciasis on the prevalence of STH infections in pre-school-aged children and SAC in Imo state of eastern Nigeria also reported the same findings indicating that the prevalence of A. lumbricoides was significantly lower in children living in areas treated with 13 years of annual ivermectin treatment than children living in untreated areas [31]. In another similar study that assessed the prevalences of STH in three communities in northern Nigeria with contrasting treatment history (ivermectin only, ivermectin plus albendazole, and no MDA history) showed the lowest prevalence of each species of STH in the communities treated only with ivermectin for the control and elimination of onchocerciasis in northern Nigeria [32]. The most unusual finding of their study was the lowest prevalences of STH species in communities treated with ivermectin only even compared to the areas treated with a combination of ivermectin and albendazole [32]. Moreover, our results are consistent with previous follow-up studies that investigated the effect of repeated treatments with ivermectin against STH and shown the reduced prevalence of A. lumbricoides infection [27–29, 36, 50]. This finding also supports evidence from observations of previous field-based studies and community trials [25, 26, 51–53] that reported a reduction in the prevalence of A. lumbricoides after single-dose ivermectin treatment. Meanwhile, this finding is contrary to a previous study which has shown no important effect of up to 17 years of biannual mass ivermectin treatments on the prevalence of A. lumbricoides [30]. For hookworm infection, similar effects to our finding have been observed from a previous study that compared prevalence rates of STH before and after mass treatments with ivermectin in northeast Brazil [28]. In contrast, long-term periodic mass ivermectin treatment had little impact on the prevalence of hookworm infection [30, 31].
Our findings also showed that 15 years of continuous CDTi did not reduce the prevalence of T. trichuria infection. On the contrary, the prevalence of T. trichuria infection was high, and even significantly higher than the baseline prevalence reported in 2002, revealing T. trichuria is a public health problem in the area. The current evidence that long-term mass ivermectin treatment had no effect on T. trichiura complements the results of earlier studies [27, 50, 53, 54]. However, it is reported that regular mass biannual ivermectin treatment of communities for a period up to 17 years had a more significant impact on T. trichuria infection [30].
As far as we know, no study has investigated the long-term collateral impact of CDTi on STH epidemiology in Ethiopia. This is the first study that CDTi for onchocerciasis also led to significant reductions in A. lumbricoides, hookworm, and any STH infection prevalence at the population level. The strength of our study was the baseline level of STH infection in this area was obtained before initiating mass ivermectin distribution for onchocerciasis control. Thus, we were able to estimate the burden of STH and measure the impact of CDTi in the study area.
Limitation of the study
The present study had the following limitations. First, the prevalence and intensity of infection estimates of STH were based on a single specimen. There is temporal variation in egg excretion over hours and days so that it is probable that this might affect the accuracy of the egg count and affect the estimated prevalence and intensity of infection in the area. Second, we have not measured the decline in the intensity of STH infection because there was no baseline data on the intensity of infection. Third, there is a large gap between the two studies. Thus, we cannot rule out a decline in the prevalence of infections due to other interventions like better access to water, sanitation and hygiene improvements, and health education programs that are thought to bring behavioural changes [55]. Hence, further investigation of predictive factors of the observed infections other than those included in this study is needed.
Conclusions
We have assessed the prevalence and intensity of STH and evaluated the impact of long-term mass ivermectin administration employed to control and eliminate onchocerciasis on the epidemiology of STH infections in Yeki district of southwest Ethiopia. Moreover, we determined the prevalence and intensity of STH infection. Our study evidenced that the long-term CDTi program for onchocerciasis control and elimination had collateral benefits by reducing the burden of STH infections, specifically on A. lumbricoides and hookworm, but had no impact on T. trichuria infections. We believe that the finding of additional health benefits of large-scale ivermectin administration will aid to increase positive engagement and sustain participation of communities during MDA campaigns, and strengthen governmental and NGOs support for the undergoing national onchocerciasis elimination program.
Supporting information
S1 Table. Prevalence of any STH infection by kebele, religion and ethnicity of study participants from Yeki district of southwest Ethiopia (2017).
https://doi.org/10.1371/journal.pone.0263625.s001
(DOCX)
Acknowledgments
We would like also to thank Bechi Health Center Laboratory for allowing the laboratory space for parasitological investigation. We are also thankful to the communities for their active participation and collaboration in the study. The support of health extension workers, kebele and community leaders, onchocerciasis/NTD focal person, and health officials of the respective districts is greatly acknowledged.
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