Prevalence of Soil-Transmitted Helminth Infections and Associated Risk Factors Among School Children in Dembecha Town, Ethiopia

Aleka Aemiro; Sissay Menkir; Abayeneh Girma

doi:10.1177/11786302241245851

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24 April 2024 Prevalence of Soil-Transmitted Helminth Infections and Associated Risk Factors Among School Children in Dembecha Town, Ethiopia

Aleka Aemiro, Sissay Menkir, Abayeneh Girma

Author Affiliations +

Environmental Health Insights, 18(1): (2024). https://doi.org/10.1177/11786302241245851

Abstract

Soil-transmitted helminth (STH) infections are among the most common infections that affect the poorest and most deprived communities. In most developing countries, children aged 5 to 15 years are at risk for chronic helminth infection and associated morbidity. This study aimed to determine the prevalence of STH infections and associated risk factors among three government elementary schools in Dembecha town, Ethiopia. We conducted a school-based cross-sectional study involving 316 participants between November 2019 and March 2020. A systematic random sampling method was used to select study participants from the study schools. Data related to the sociodemographic characteristics of the study participants and risk factors for STH infections were collected using a pretested questionnaire survey. Parasitological examinations of stool samples were performed using the formal-ether concentration method. Study participants aged 5 to 15 years were enrolled in this study. The overall prevalence of STH infection was 21.5% (68/316). Ascaris lumbricoides ranked highest, with a prevalence of 11.4%, followed by hookworms 7.3%, Trichuris trichiura 1.9%, and Strongloides stercoralis 0.9%. Age groups of 10-15 years (AOR =3.109; 95% CI: 1.033, 9.350), residence in Kebele 2 (AOR =2.990; 95% CI: 1.082, 8.264), illiterate mothers (AOR =4.689; 95% CI: 1.410, 15.59), and a family size of 4-6 (AOR =3.286; 95% CI: 1.299, 8.313) were significantly associated with STH infections. The prevalence of STH infections remains an important health issue for study participants. Therefore, school deworming programs twice a year are crucially needed until the prevalence falls below the level of public health importance.

Introduction

Soil-transmitted helminth (STH) infections are among the most common infections across the globe that affect the poorest and most deprived communities.¹ STH parasites most commonly associated with humans include Ascaris lumbricoides, Trichuris trichiura, hookworms (Necator americanus and Ancylostoma duodenale) and Strongyloides stercoralis, all of which contribute to childhood morbidity.² A. lumbricoides and T. trichiura infections result from the ingestion of eggs and contact with fecally contaminated soil. They spread primarily through fecal transmission, usually through the ingestion of parasite eggs in feces. Whereas hookworm and S. stercoralis are spread through the skin penetration of infective larvae.

Preschool-aged children (PSAC), school-aged children (SAC), and women of reproductive age are World Health Organization (WHO)-identified risk groups.³ SAC (5-15 years) in most developing countries are at greater risk for chronic helminth infections and helminth-associated morbidities due to play with the soil and eating habits of the soil.⁴ These infections are still major health problems in developing countries, affecting millions of SAC. Therefore, in children, malnutrition and anemia, which have negative impacts on development and educational performance,⁵ as well as stunting growth, wasting, and underweight, have also been serious global public health problems in the developing world, including Ethiopia.⁶

The latest estimates indicated that more than 1.5 billion people were infected with at least one of the STH parasites,⁷ and 4 billion people were at risk for this infection.⁸ Recent estimates suggested that 819 million, 465 million and 439 million people worldwide were infected by A. lumbricoides, T. trichiura, and hookworm, respectively.⁹ Moreover, 100 million people were recorded for S. stercoralis infection.^10,11 Globally, more than 267 million PSAC and 568 million SAC live in areas where STH infections are intensively transmitted and need treatment and preventive interventions.⁷ STH infections are widely distributed in tropical and subtropical areas, with the highest burden occurring in sub-Saharan Africa (SSA), the Americas, China, and East Asia.⁷ Approximately 198, 173, and 162 million people in SSA are infected with hookworm, A. lumbricoides, and T. trichiura, respectively.¹²

In Ethiopia, the number of people living in STH-endemic areas is estimated to be 81 million, comprising 9.1 million people with PSAC, 25.3 million with SAC, and 44.6 million adults.¹³ The approximate numbers of people infected in Ethiopia with hookworm, A. lumbricoides, and T. trichiura were 11 million, 26 million, and 21 million, respectively.¹² A low prevalence of STH was reported in Debre Tabor (11.8%), where the prevalence of A. lumbricoides, hookworms, and T. trichiura was 7, 3.2, and 1.2%, respectively.¹⁴ However, the prevalence of STH was moderate in Hawassa (52.4%) with A. lumbricoides (44.4%), which was the predominant parasite, followed by T. trichiura (11.1%) and hookworm (7.7%).¹⁵ In another study conducted in Mizan Aman, the prevalence of STH was high (70.3%).¹⁶

Risk factors associated with STH infections include walking barefoot, overcrowding, and poor health or nutritional status.¹⁷ Furthermore, family education level, unsafe human waste disposal systems, lack of safe water supplies, low socioeconomic status, poor personal hygiene, and poor environmental sanitation, as well as frequent outdoor exposure, favor transmission.¹⁸ According to the WHO, periodic deworming to eliminate infecting worms, health education to prevent reinfection, and improved sanitation to reduce soil contamination with infective eggs are vital for controlling STH infections.⁷ The main drugs for the control of STH infections are albendazole and mebendazole. Strategic drug administration based in the community is more important for the control of STH and other intestinal parasitic infections than school- and hospital-based drug administration. Epidemiological evaluations and reports in communities are needed as guides for choosing and instituting treatments.¹⁹

Soil-transmitted helminth infection is highly distributed in tropical and sub-tropical countries those with lack of adequate sanitary facilities, inappropriate waste disposal systems, lack of safe water supply, and low socio-economic status. School-age children are mainly at high risk of STH infections, especially in developing countries like Ethiopia. Many investigations have been carried out among these risk groups in different parts of Ethiopia to determine the prevalence of STH and its predictors; it is unknown in this study area. Hence, this study was aimed to assess the prevalence and associated risk factors of STH infection among children in three government elementary schools in Dembecha town, Ethiopia.

Materials and Methods

Study area

The study was conducted in Dembecha town, in the West Gojjam zone of the Amhara Regional State. Dembecha is located 349 kilometers north of Addis Ababa and 205 kilometers in the western direction of Bahir Dar, the regional capital city.⁶¹ It is situated at a latitude and longitude of 10°33′N 37°29′E/10.550°N 37.483°E and an elevation of 2083 meters above sea level.²⁰ The town has 1 hospital, 2 health centers, 3 health posts, 1 family guidance association clinic, and 4 private clinics. According to the 2007 Central Statistical Agency of Ethiopia (CSA),²¹ Dembecha town has a population of 15 735 (7040 males and 8695 females). The research was carried out among systematically selected children from three government elementary schools in Dembecha town. There were an adequate number of latrine and pipe water supplies for schoolchildren to use in the schools (Figure 1).

Figure 1.

Location map of Dembecha district (adopted from Addis & Mengesha, 2020) with permission.⁶¹

Study design

A school-based cross sectional study was conducted from November 21, 2019 to March 7, 2020, among three elementary school children, such as Siso Mesk, Dembecha Junior, and Addis Amba.

Study population

All schoolchildren enrolled in three elementary schools were considered to constitute the study population for this research.

Criteria for inclusion and exclusion

Schoolchildren who were willing to participate, provided sufficient stool samples, and provided informed consent and consent from their parents or legal guardians were included, while schoolchildren who were unwilling to participate and had taken helminth chemotherapy within 3 months before data collection were excluded.

Sample size determination

The sample size was calculated using the single population proportion formula. There have been no studies on the prevalence of STH infections in the study area. As a result, we used a 50% prevalence rate of soil-transmitted infections. The required sample size (n) was determined using the following statistical formula²²:

Where, n = sample size

d= margin of error (0.05)

Z = 1.96 at the 95% confidence level

P = prevalence rate of 50% = 0.5

Finally, 384 schoolchildren were consecutively enrolled in three schools, where participants were assigned proportionally from all schools.

Sampling technique

There are 6 clusters in the town of Dembecha. Using the random sampling technique, 3 clusters were selected. Each cluster contained 2 schools, and from the 3 clusters, 3 schools were randomly selected. The schoolchildren were then stratified according to their educational level (grades 1-8). Schoolchildren’s allocation to schools, grade levels, and sections was performed proportionally to the number of schoolchildren in each school, grade, and section. A systematic sampling technique was used in each study to select participants, in which thousands of children were randomly selected from readily available school lists based on unique identification codes.

Questionnaire survey

A structured questionnaire based on known risk factors was developed in English and translated into the local language (Amharic). For each schoolchild, a structured questionnaire was completed to collect demographic and associated risk factors for STH infections.

Stool sample collection and examination procedures

Each study participant provided a clean, waterproof, labeled plastic stool cup and applicator sticks to bring about 2 g of fresh stool sample. The samples collected were preserved in 10% formalin and transported to Dembecha Health Center for examination.¹ The resulting suspension was filtered through a sieve into another conical tube. After 3 to 4 mL of diethyl ether was added to the formalin solution, the mixture was centrifuged at 2000 rpm for 2 minutes.²³ The supernatant was discarded, and a thick smear was prepared from the sediment and examined under a microscope with a magnification of 400 times (40× objective and 10x ocular). Laboratory technicians examined the slides to observe the eggs and larvae of STH.

Variables

The study focused on independent variables (sociodemographic data such as age and sex); socioeconomic data such as paternal and maternal income levels; environmental factors such as latrine availability and garbage storage; types of water sources; and behavioral factors such as wearing shoes, hand washing habits after toilet, and parental education. The dependent variable was the prevalence of soil-transmitted helminth infections in the study area.

Data analysis

Statistical analysis was performed using the SPSS version 20.0 statistical package. Chi-square and univariate analyses were used to assess the associations between independent and dependent variables. The strength of the association between STH infections and associated risk factors was measured as the odds ratio (OR) using logistic regression. After univariate analysis, for which P < .25, a multivariate logistic regression model was used for further analysis of potential risk factors. According to our multivariate logistic regression, the associations between variables were considered to be statistically significant only if the P value was < .05 at the 95% confidence level. The results are presented in the text and tables.

Quality control

Before actual data collection began, experienced laboratory technologists pretested the questionnaire and other materials, such as the microscope, centrifuge, and chemicals used during data collection. The specimens were also checked for serial number, quality, and collection procedures. The stool samples were examined by 2 laboratory technicians, in order to avoid observer bias. For quality control, randomly selected stool samples were examined by a third person, who was blinded to previous test results.

Ethical consideration

Ethical approval was obtained from the Ethics Committee of the College of Science at Bahir Dar University. A letter describing the objective of the research was sent to the Dembecha town educational office and to the schools where the research was conducted. School authorities, teachers, parents/legal guardians, and participants were informed about the objectives, procedures, and benefits of the study. Written consent was obtained from school officials and the parents or legal guardians of the children. Informed consent was also obtained from the children at the time of specimen collection.

Results

Characteristics of the study participants

Out of the 384 participants, 316 (82.3%) were interviewed, and stool samples were submitted for the use of the formol-ether concentration technique. Of the 316 study participants, 121 were from Dembecha Junior, 107 from Addis Amba, and 88 from Siso Mesk government elementary schools. There were 169 (53.5%) female and 147 (46.5%) male schoolchildren. A total of 185 (58.5%) children aged > 10-15 years were included. 162 (51.3%) of the schoolchildren were from grades 1 to 4. About 156 (49.4%) schoolchildren fathers whose education level was secondary school and above. About 177 (56.0%) study participants had a father’s income level above 3000, whereas 155 (49.1%) of schoolchildren had their mother’s income level below 1000 Ethiopian Birr (ETB) (Table 1).

Table 1.

Sociodemographic and socioeconomic characteristics of the study participants, including schoolchildren, Dembecha town, Ethiopia November 2019 to March 2020.

The majority of the study participants (178; 56.3%) had a family size of 4 to 6. According to the study, 229 (72.5%) schoolchildren used the toilet. Around 216 (68.4%) schoolchildren regularly cut their fingers, and 175 (55.4%) schoolchildren always wash their hands before meals. A total of 253 (80.0%) study participants had garbage storage in their locality (Table 2).

Table 2.

Environmental and behavioral characteristics of the study participants, Dembecha town, Ethiopia, November 2019 to March 2020.

Prevalence of STH infections and associated risk factors

The overall prevalence of STH infection in the study area was 21.5% (68/316). Among these, 27.6% (51/185) of those participants were in the 10 to 15-year-olds and had STH, while those in the 5 to 9-years-olds had parasitic infection (13%, 17/131). Among the 3 kebeles, study participants from Kebele 2 account for 32.7% (32/98) of STH infections. According to this study, 38.4% (38/99) of the respondents had STH infections from illiterate mothers. About 34.6% (53/155) of the schoolchildren were positive for STH infections that came from mothers with an income level less than 1000 ETB, and 28.2% (22/78) of the respondents were positive for STH infections that came from their fathers with an income level of 1000 to 3000 ETB. The prevalence of STH infections in schoolchildren from family sizes 4 to 6 was 28.7% (51/178). Schoolchildren who had no practice of washing hands before meals were infected with STH infections, with a prevalence of 23.5% (8/34). About 51.6% (163/316) of schoolchildren had practiced eating raw and unwashed fruits and vegetables, and 25.8% (42/163) of them were positive for STH parasitic infections (Table 3).

Table 3.

Prevalence of STH infections and associated risk factors among three school children in Dembecha town, Ethiopia, November 2019 to March 2020.

Major STH species identified in schoolchildren

A species-specific analysis revealed that 6 species were identified. The most dominant STH was A. lumbricoides, followed by hookworm, T. trichiura, and S. stercoralis, with prevalence rates of 11.4% (36/316), 7.3% (23/316), 1.9% (6/316), and 0.9% (3/316), respectively. The distribution of STH infections among the primary school survey participants showed that the highest infection rate was recorded in the children of Dembecha Junior (44.1%), followed by Addis Ama and Siso Mesk, with prevalence rates of 30.9% and 25.0% (Table 4).

Table 4.

Identification of the main species of STH parasite among three government elementary school children in Dembecha town, Ethiopia, from November 2019 to March 2020.

Risk factors associated with infections caused by STH

In the present study, age, residence (Kebele), maternal education level, and family size were identified as potential risk factors. The analysis revealed that individuals aged 10 to 15 years was 3 times more likely to be infected with STH infection than those aged 5 to 9 years (AOR = 3.109 (95% CI: 1.033, 9.350); additionally, participants whose residence in Kebele 2 were almost 3 folds more likely to have an infection (AOR = 2.990; 95% CI: 1.082, 8.264); and respondents who came from illiterate mothers were 4.7 (95% CI: 1.410, 15.59) times greater chance to have STH infections than educated mothers. Children with a family size of 4-6 were 3.3 (95% CI: 1.299, 8.313) times more affected than children from a family size of 1-3 (Table 5).

Table 5.

Univariate and multivariate logistic regression analyses of factors associated with STH infections among schoolchildren in Dembecha town, Ethiopia, November 2019 to March 2020.

Risk factors associated with Asacris lumbricoides, Hookworm, and Trichuris trichiura infections

A. lumbricoides infection was significantly associated with the schoolchildren from Kebele 2 with an AOR of 8.3 (95% CI: 2.317, 29.934). Study subjects from illiterate mothers were 7 (95% CI: 1.357, 34.808) times more likely to develop A. lumbricoides infection than literates. Respondents with a family size of 4 to 6 and a family size greater than 7 were 9 (95% CI: 1.724, 48.426) and 8 (95% CI: 1.245, 49.210) folds more likely to catch A. lumbricoides infection, respectively. Furthermore, T. trichiura was significantly associated with respondents who practiced open field defection, with an AOR 15 (95% CI: 2.054, 161.638) times greater than that of respondents who used latrine. During the study period, hookworm and S. stercoralis were not significantly associated with any of the potential risk factors (Table 6).

Table 6.

Univariate and multivariate logistic regression analysis of possible risk factors associated with A. lumbricoides, hookworm, and T. trichiura infection among schoolchildren in Dembecha town, Ethiopia, November 2019 to March 2020.

Discussion

The burden of intestinal parasites, particularly STH infections, is often very high in schoolchildren and pregnant women.²⁴ Parasite infections caused by STH have been the most common infection among people living in resource-depleted developing countries. Although the deworming program has progressed in most Ethiopian primary schools since 2003 in rural areas and 2009 in urban areas,²⁵ the burden of STH infection is still a public health problem, as revealed in this study.

The prevalence of STH infection was 21.5%. The result is similar to those of Butajira Town, south-central Ethiopia (23.3%),²⁶ Gamo Gofa, southern Ethiopia (23.5%)¹⁴ and Cameroon (24.1%).²⁷ However, the prevalence of STH was greater than the result in Nigeria (8.3%).²⁸ As compared with the current finding of STH infection, the result of STH infection in Rwanda was higher, with a prevalence rate of 65.8%.²⁹ This variation could be due to differences in topography and study period, during which the communities improved their living standards and personal and environmental hygiene over time.

A. lumbricoides was the most prevalent STH infection, with a prevalence rate of 11.4%, which was consistent with previous studies conducted in the Libo Kem Kem district (11.0%),³⁰ Durbete Town (13.9%),³¹ Zegie Peninsula (12.7%)³² and southwestern China (10.0%).³³ The result is greater than those findings in Jawi town (0.73%).³⁴ On the other hand, the prevalence of A. lumbricoides in the present study was lower than that in Gara Riketa (38.0%) (southern Ethiopia)³⁵ and Maytsbri/Tigray (24.9%).³⁶ The relatively high prevalence of A. lumbricoides observed in the present study may be due to the high environmental contamination resulting from the large number of infected people, the durability of A. lumbricoides eggs under varying environmental conditions, the high fertility,³⁷ and the sticky nature of the shell of A. lumbricoides eggs,³⁸ which aid in their attachment to human hands, fruits and vegetables.

In the present study, the prevalence of hookworms was 7.3%. This result was comparable with that of a study conducted in Lake Hawassa (7.7%)¹⁵ and in Birbir (5.4%).³⁹ However, the finding was greater than those of the Gamo Gofa zone in southern Ethiopia (3.1%)¹⁴ and Ambo in western Ethiopia (2.8%).⁴⁰ The result of this study was much lower than the studies in Arbaminch Zuria district (14.5%),⁴¹ Yirgacheffee, South Ethiopia (16.7%)⁴² and among schoolchildren in Mettu town, southwest Ethiopia (28.1%).⁴³ This variation might be due to differences in altitude and environmental, socioeconomic, and behavioral conditions among the residents.

The prevalence of T. trichiura infection was 1.9%, which was similar to the previous studies carried out in the Libo Kem district and Ambo City elementary school children, in which the prevalences were 1.6%³⁰ and 2.2%⁴⁰, respectively. The present result was slightly greater than those obtained in the Guragie zone (0.5%)⁴⁴ and in Medebay Zana wereda, northwestern Tigray (0.5%).⁴⁵ However, the prevalence of T. trichiura was lower than the report in the southwestern part of Ethiopia (Zemika kebele) (66.8%),¹⁶ South Asia (14%),⁴⁶ and Nigeria (31.9%).⁴⁷ This could be due to differences in environmental conditions and the study period. People living in tropical and subtropical areas of the world are at the highest risk of infection by T. trichiura. In addition, populations without reliable access to safe water and sanitation were at increased risk for this infection.⁴⁸

Among the STH infections, the prevalence of S. stercoralis was 0.9%. This finding is in agreement with previous results from the Ilie, Osun State, southwest, Nigeria¹⁸ and Zegie Peninsula (0.7%).³² Nevertheless, the prevalence of this infection was lower than the result in Mecha district, Northwest Ethiopia (6.4%)⁴⁹ and the finding in Nigeria (3.4%).⁴⁷ The low prevalence of S. stercoralis may be due to its peculiar characteristics, which require different diagnostic methods than other STH infections. For this reason, this species is often not identified,⁷ and the incidence of strongyloidiasis is greater in HIV-positive individuals than in HIV-negative individuals.⁵⁰ Moreover, environmental factors may contribute to the lower prevalence of S. stercoralis in the study area.

Age, residence (kebele), mother education level, and family size were identified as risk factors for STH infections among schoolchildren in Dembecha Town. Children in the age group of 10 to 15 were 3 times (95% CI: 1.033, 9.350) more likely to be infected with STH infections than those 5 to 9 years old. This is perhaps because children in these age groups are more engaged in outdoor activities such as farming; as a result, they have more exposure to STH infections. However, other study reported that children under the age of 6 years were more harbor STH infections than children older than 6 years.⁴⁴ Similarly, a report from Mizan-Aman Town showed that younger children were more infected with STH infections.⁵¹ This variation might be due to environmental factors such as the frequent exposure of an individual to soil, the probability of contact with fecal materials, a lack of a safe water supply, and poverty.

With regard to residence, the odds of developing STH infections were 3 times higher among study participants who reside in Kebele 2 (95% CI: 1.082, 8.264) than those who reside in other Kebeles. Similar findings were reported in Sekela Primary School, Western Ethiopia⁵² and Brazil⁵³ and they agree that rural people were more affected than people who lived in urban residences. This may be due to the fact that, though the area is part of Dembecha town, the people who live there have less access to water, a lack of environmental sanitation, poverty, and poor personal hygiene.

The odds of developing STH infections were 4.7 (95% CI: 1.410, 15.59) times higher among respondents who came from illiterate mothers as compared to their counterparts. This finding is in harmony with the results of Mecha town⁴⁹, Kenya⁵⁴ and Mexico.⁵⁵ This might be due to educated mothers who know their children to practice personal hygiene, not allow playing with soil, and hand washing practices before meals and after defecation.

Among the study participants, family size 4 to 6 was significantly associated with STH infections, with an AOR of 3.3 (95% CI = 1.299, 8.313). The report is in accordance with the results conducted in Dona Ber⁵⁰, Bahir Dar⁵¹ and outside of Ethiopia in Brazil.⁵³ This could be due to overcrowding or communal living conditions, which are risk factors for the transmission of some intestinal helminths.³⁹ In addition, people with a larger family may be unable to fulfill necessary commodities, including hygienic materials and quality food for their families. Hence, family size, along with other risk factors, plays a significant role in the transmission of STH infections.

Schoolchildren who practiced open field defection were 15 times (95% CI: 2.054, 161.638) more likely to develop T. trichiura infections than those who used latrine. This result is in line with the study done in Jimma⁵⁶ and the central American report.⁵⁷ This finding was also in agreement with the findings in Indonesia,⁵⁸ and Cameroon.⁵⁹ At the same time, a study conducted in Bangladesh reported that nonhygienic disposal of human stool was significantly associated with T. trichuris infection.⁶⁰ This may be due to the fact that open field defecation increases contamination in society, which in turn decreases environmental and personal hygiene and hence increases T. trichuris infection among schoolchildren because of the existing improper defecation system.

Conclusion and Recommendations

Soil-transmitted helminth infections are the main public health problem among the three selected government elementary schoolchildren. A. lumbricoides, hookworm T. trichuris, and S. stercoralis were identified as the most prevalent STH parasitic species among schoolchildren. In the present study, age, residence, education level of the mother, and family size were identified as risk factors significantly associated with STH infections. Therefore, we recommend community-based strategic drug administration rather than school-based drug administration. We also recommend that improved personal and environmental sanitation, health education, and good handling of affected individuals are very important for the control of STH infections.

This article is distributed under the terms of the Creative Commons Attribution-NonCommercial 4.0 License ( https://creativecommons.org/licenses/by-nc/4.0/) which permits non-commercial use, reproduction and distribution of the work without further permission provided the original work is attributed as specified on the SAGE and Open Access pages ( https://us.sagepub.com/en-us/nam/open-access-at-sage).

Author Contributions

Material preparation was performed by AA and AG; Data collection and analysis were performed by AA, SM, and AG; writing the paper was done by AA, SM, and AG. All authors reviewed and approved the manuscript.

Data Availability Statement

The data that support the findings of this study are available from the corresponding author (Abayeneh Girma), upon reasonable request.

Ethical Approval

The study was approved by the ethical committee of the College of Science of Bahir Dar University (BDU). Date 21/11/2019, Ref no. PGRCSVD/100/2019.

REFERENCES

1.

Organization WH. Prevention and control of schistosomiasis and soil-transmitted helminthiasis: report of a WHO expert committee: World Health Organization; 2002. Google Scholar

2.

Bethony J , Brooker S , Albonico M , et al. Soil-transmitted helminth infections: ascariasis, trichuriasis, and hookworm. Lancet. 2006;367:1521–1532. Google Scholar

3.

WHO. Guideline: preventive chemotherapy to control soil-transmitted helminth infections in at-risk population groups: World Health Organization; 2017. Google Scholar

4.

Gyorkos TW , Gilbert NL. Blood drain: soil-transmitted helminths and anemia in pregnant women. PLoS Negl Trop Dis. 2014;8:e2912. Google Scholar

5.

Dickson R , Awasthi S , Williamson P , Demellweek C , Garner P. Effects of treatment for intestinal helminth infection on growth and cognitive performance in children: systematic review of randomised trials. BMJ. 2000;320:1697–1701. Google Scholar

6.

Tariku A , Woldie H , Fekadu A , et al. Nearly half of preschool children are stunted in Dembia district, Northwest Ethiopia: a community based cross-sectional study. Arch Public Health. 2016;74:1–9. Google Scholar

7.

WHO. Soil-Transmitted Helminth Infections. World Health Organization Geneva; 2020. Google Scholar

8.

WHO. Soil-Transmitted Helminthiases: Eliminating Soil Transmitted Helminthiases as a Public Health Problem in Children. Progress Report 2001-010 and Strategic Plan 2011-2020. World Health Organization; 2012. Google Scholar

9.

Pullan RL , Smith JL , Jasrasaria R , Brooker SJ. Global numbers of infection and disease burden of soil transmitted helminth infections in 2010. Parasit Vectors. 2014;7:37-19. Google Scholar

10.

Krolewiecki AJ , Lammie P , Jacobson J , et al. A public health response against Strongyloides stercoralis: time to look at soil-transmitted helminthiasis in full. PLoS Negl Trop Dis. 2013;7:e2165. Google Scholar

11.

Hotez PJ , Alvarado M , Basáñez M-G , et al. The global burden of disease study 2010: interpretation and implications for the neglected tropical diseases. PLoS Negl Trop Dis. 2014;8:e2865. Google Scholar

12.

Hotez P , Aksoy S , . PLoS Neglected Tropical Diseases: Two Years of Providing Access to Innovation for the World's Poor. . . and Counting. Public Library of Science San Francisco, USA; 2009. p. e494. https://doi.org/10.1371/journal.pntd.0000494 Google Scholar

13.

Ababa A. , Federal Democratic Republic of Ethiopia Ministry of Health. Postnatal Care; 2003. Google Scholar

14.

Asfaw MA , Gezmu T , Wegayehu T , et al. Soil-transmitted helminth infections among pre-school aged children in Gamo Gofa zone, southern Ethiopia: prevalence, intensity and intervention status. PLoS One. 2020;15:e0243946. Google Scholar

15.

Tadege B , Shimelis T. Infections with Schistosoma mansoni and geohelminths among school children dwelling along the shore of the Lake Hawassa, southern Ethiopia. PLoS One. 2017;12:e0181547. Google Scholar

16.

Tekalign E , Bajiro M , Ayana M , Tiruneh A , Belay T. Prevalence and intensity of soil-transmitted helminth infection among rural community of Southwest Ethiopia: a community-based study. Biomed Res Int. 2019;2019:Article ID 3687873. Google Scholar

17.

Alemu A , Atnafu A , Addis Z , et al. Soil transmitted helminths and Schistosoma mansoni infections among school children in Zarima town, Northwest Ethiopia. BMC Infect Dis. 2011;11:189–197. Google Scholar

18.

Adefioye O , Efunshile A , Ojurongbe O , et al. Intestinal helminthiasis among school children in Ilie, Osun state, Southwest, Nigeria. Sierra Leone J Biomed Res. 2011;3:43–48. Google Scholar

19.

Albonico M , Montresor A , Crompton D , Savioli L. Intervention for the control of soil-transmitted helminthiasis in the community. Adv Parasitol. 2006;61:311–348. Google Scholar

20.

Report DDc. Dembecha Woreda communication office Profile Manual Document. Unpublished source, Dembecha. 2017. Google Scholar

21.

Population E , Commission H , . Summary and statistical report of the 2007 population and housing census: population size by age and sex: Federal Democratic Republic of Ethiopia, Population Census Commission; 2008. Google Scholar

22.

Naing L , Winn T , Rusli B. Practical issues in calculating the sample size for prevalence studies. Arch Orofac Sci. 2006;1:9–14. Google Scholar

23.

Blatt JM , Cantos GA. Evaluation of techniques for the diagnosis of Strongyloides stercoralis in human immunodeficiency virus (HIV) positive and HIV negative individuals in the city of Itajaí, Brazil. Braz J Infect Dis. 2003;7:402–408. Google Scholar

24.

Ashenafi Abossie A , Mohammed Seid M , . Assessment of the prevalence of intestinal parasitosis and associated risk factors among primary school children in Chencha town, Southern Ethiopia. 2014. https://doi.org/10.1186/1471-2458-14-166 Google Scholar

25.

Mize L , Miles R , Kaba M , Dejene M , Berhanu K. USAID/Ethiopia: End of project evaluation for the Urban health extension program. GH Tech Bridge Urban health–Catching up on the future for Ethiopia. 2012;3. Google Scholar

26.

Shumbej T , Belay T , Mekonnen Z , Tefera T , Zemene E. Soil-transmitted helminths and associated factors among pre-school children in butajira town, south-central Ethiopia: a community-based cross-sectional study. PLoS One. 2015;10:e0136342. Google Scholar

27.

Tchuem Tchuenté L-A , Kamwa Ngassam RI , Sumo L , et al. Mapping of schistosomiasis and soil-transmitted helminthiasis in the regions of centre, east and west Cameroon. PLoS Negl Trop Dis. 2012;6:e1553. Google Scholar

28.

Adewale B , Rahaman O , Aina O , Sulyman MA. Schistosoma mansoni and soil transmitted helminth (STH) infections among pregnant women attending primary health care facilities in Lagos mainland, Nigeria. J Biosci Med. 2018;06:64–70. Google Scholar

29.

Rujeni N , Morona D , Ruberanziza E , Mazigo HD. Schistosomiasis and soil-transmitted helminthiasis in Rwanda: an update on their epidemiology and control. Infect Dis Poverty. 2017;6:8–11. Google Scholar

30.

Addisu T , Asmamaw A. A survey of soil-transmitted helminths infections and schistosomiasis mansoni among school children in Libo-Kemkem district, Northwest Ethiopia: Cross Sectional study. Am J Health Res. 2015;3:57–62. Google Scholar

31.

Alelign T , Degarege A , Erko B. Soil-transmitted helminth infections and associated risk factors among schoolchildren in Durbete town, northwestern Ethiopia. J Parasitol Res. 2015;2015:1–5. Google Scholar

32.

Abdi M , Nibret E , Munshea A. Prevalence of intestinal helminthic infections and malnutrition among schoolchildren of the Zegie Peninsula, northwestern Ethiopia. J Infect Public Health. 2017;10:84–92. Google Scholar

33.

Yang D , Yang Y , Wang Y , et al. Prevalence and risk factors of Ascaris lumbricoides, Trichuris trichiura and Cryptosporidium infections in elementary school children in southwestern China: a school-based cross-sectional study. Int J Environ Res Public Health. 2018;15:1809. Google Scholar

34.

Sitotaw B , Mekuriaw H , Damtie D. Prevalence of intestinal parasitic infections and associated risk factors among Jawi primary school children, Jawi town, north-west Ethiopia. BMC Infect Dis. 2019;19:341–410. Google Scholar

35.

Eyamo T , Girma M , Alemayehu T , Bedewi Z. Soil-transmitted helminths and other intestinal parasites among schoolchildren in southern Ethiopia. Res Rep Trop Med. 2019;10:137–143. Google Scholar

36.

Gebrehiwet MG , Medhaniye AA , Alema HB. Prevalence and associated factors of soil transmitted helminthes among pregnant women attending antenatal care in Maytsebri primary hospital, North Ethiopia. BMC Res Notes. 2019;12:644–646. Google Scholar

37.

O'Lorcain P , Holland CV , . The public health importance of Ascaris lumbricoides. Parasitology. 2000;121 Suppl:S51-S71. Google Scholar

38.

Quilès F , Balandier J-Y , Capizzi-Banas S. In situ characterisation of a microorganism surface by Raman microspectroscopy: the shell of Ascaris eggs. Anal Bioanal Chem. 2006;386:249–255. Google Scholar

39.

Alemu G , Abossie A , Yohannes Z. Current status of intestinal parasitic infections and associated factors among primary school children in Birbir town, southern Ethiopia. BMC Infect Dis. 2019;19:270–278. Google Scholar

40.

Samuel F , Demsew A , Alem Y , Hailesilassie Y. Soil transmitted helminthiasis and associated risk factors among elementary school children in Ambo town, Western Ethiopia. BMC Public Health. 2017;17:791–797. Google Scholar

41.

Alemu G , Aschalew Z , Zerihun E. Burden of intestinal helminths and associated factors three years after initiation of mass drug administration in Arbaminch Zuria district, southern Ethiopia. BMC Infect Dis. 2018;18:1–8. Google Scholar

42.

Molla E , Mamo H. Soil-transmitted helminth infections, anemia and undernutrition among schoolchildren in Yirgacheffee, South Ethiopia. BMC Res Notes. 2018;11:585–587. Google Scholar

43.

Yeshanew S , Bekana T , Truneh Z , et al. Soil-transmitted helminthiasis and undernutrition among schoolchildren in Mettu town, Southwest Ethiopia. Sci Rep. 2022;12:3614. Google Scholar

44.

Weldesenbet H , Worku A , Shumbej T. Prevalence, infection intensity and associated factors of soil transmitted helminths among primary school children in Gurage zone, South Central Ethiopia: a cross-sectional study design. BMC Res Notes. 2019;12:231. Google Scholar

45.

Teshale T , Belay S , Tadesse D , Awala A , Teklay G. Prevalence of intestinal helminths and associated factors among school children of Medebay Zana wereda; North Western Tigray, Ethiopia 2017. BMC Res Notes. 2018;11:444–446. Google Scholar

46.

Silver ZA , Kaliappan SP , Samuel P , et al. Geographical distribution of soil transmitted helminths and the effects of community type in South Asia and South East Asia – A systematic review. PLoS Negl Trop Dis. 2018;12:e0006153. Google Scholar

47.

Karshima SN. Prevalence and distribution of soil-transmitted helminth infections in Nigerian children: a systematic review and meta-analysis. Infect Dis Poverty. 2018;7:69-14. Google Scholar

48.

Guerrant RL , Walker DH , Weller PF. , Tropical Infectious Diseases: Principles, Pathogens and Practice e-book. Elsevier Health Sciences; 2011. Google Scholar

49.

Feleke BE. Epidemiology of hookworm infection in the school-age children: a comparative cross-sectional study. Iran J Parasitol. 2018;13:560–566. Google Scholar

50.

Hailegebriel T , Petros B , Endeshaw T. Evaluation of parasitological methods for the detection of Strongyloides stercoralis among individuals in selected health institutions in Addis Ababa, Ethiopia. Ethiop J Health Sci. 2017;27:515–522. Google Scholar

51.

Jejaw A , Zemene E , Alemu Y , Mengistie Z. High prevalence of Schistosoma mansoni and other intestinal parasites among elementary school children in Southwest Ethiopia: a cross-sectional study. BMC Public Health. 2015;15:600–607. Google Scholar

52.

Tolera A , Dufera M. The prevalence of soil-transmitted helminths and associated risk factors among school children at Sekela Primary School, Western Ethiopia. J Parasitol Res. 2020;2020:1–7. Google Scholar

53.

Carneiro FF , Cifuentes E , Tellez-Rojo MM , Romieu I. The risk of Ascaris lumbricoides infection in children as an environmental health indicator to guide preventive activities in Caparaó and Alto Caparaó, Brazil. Bull World Health Organ. 2002;80:40–46. Google Scholar

54.

McClure EM , Meshnick SR , Mungai P , et al. The association of parasitic infections in pregnancy and maternal and fetal anemia: a cohort study in coastal Kenya. PLoS Negl Trop Dis. 2014;8:e2724. Google Scholar

55.

Quihui L , Valencia ME , Crompton DW , et al. Role of the employment status and education of mothers in the prevalence of intestinal parasitic infections in Mexican rural schoolchildren. BMC Public Health. 2006;6:225–228. Google Scholar

56.

Ephrem T , Tariku B , Kebede MS , Ahmed Z , Tefera B. Prevalence and intensity of soil transmitted helminths among school children of Mendera Elementary School, Jimma, Southwest Ethiopia. Pan Afr Med J. 2017;27:88. Google Scholar

57.

Smith H , DeKaminsky R , Niwas S , Soto R , Jolly P. Prevalence and intensity of infections of Ascaris lumbricoides and Trichuris trichiura and associated socio-demographic variables in four rural honduran communities. Mem Inst Oswaldo Cruz. 2001;96:303–314. Google Scholar

58.

Pasaribu AP , Alam A , Sembiring K , Pasaribu S , Setiabudi D. Prevalence and risk factors of soil-transmitted helminthiasis among school children living in an agricultural area of North Sumatera, Indonesia. BMC Public Health. 2019;19:1–8. Google Scholar

59.

Tabi ESB , Eyong EM , Akum EA , Löve J , Cumber SN , . Soil-transmitted helminth infection in the Tiko Health District, South West Region of Cameroon: a post-intervention survey on prevalence and intensity of infection among primary school children. Pan Afr Med J. 2018;30:74. Google Scholar

60.

Hossain M , Bhuiyan J. Prevalence and intensity of Trichuris trichiura infection and associated determinants in rural tea garden areas of sylhet, Bangladesh. J Bacteriol Mycol Open Access. 2018;6:130–137. Google Scholar

61.

Addis Y , Mengesha W. Value chain analysis of wheat (Triticum aestivum) in Dembecha District, Ethiopia. World J Agric Res. 2020;8:121–128. Google Scholar

Citation Download Citation

Aleka Aemiro, Sissay Menkir, and Abayeneh Girma "Prevalence of Soil-Transmitted Helminth Infections and Associated Risk Factors Among School Children in Dembecha Town, Ethiopia," Environmental Health Insights 18(1), (24 April 2024). https://doi.org/10.1177/11786302241245851

Received: 29 January 2024; Accepted: 20 March 2024; Published: 24 April 2024

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