Summary Introduction: Diarrheal diseases are a leading cause of morbidity in Ugandan children. Despite having a 2-dose rotavirus vaccination coverage of >95% from 2019 to 2021, Obongi District consistently reported the highest incidence of acute watery diarrhea (AWD) in the country during the period January 2017-April 2022. We assessed the factors associated with AWD among children aged 0-59 months in Obongi District in the month of April 2022. Methods: We conducted a 1:2 unmatched case‒control study. We defined a case of AWD as the passage of ≥3 loose/liquid stools per day with negative malaria and pneumonia tests in a child aged 0-59 months residing in Itula or Parolinya subcounties from 1-30 April 2022. We reviewed medical records and interviewed case-persons’ caregivers. A control was a child aged 0-59 months from a neighboring household with no AWD from 1-30 April. We used logistic regression to identify factors associated with AWD. Results: Among 193 cases and 386 controls, 104 (54%) cases and 183 (47%) controls were male (p=0.14) and 58 (30%) cases and 127 (33%) controls were aged 12-23 months (p=0.56). In total, 187 (97%) cases and 369 (96%) controls had received at least one dose of rotavirus vaccine (p=0.45), and 58 (30%) cases and 120 (34%) controls (p=0.34) treated their drinking water by boiling/ using chlorine. Suffering from a comorbidity (undernutrition, diabetes mellitus, and/or HIV) (AOR=12; CI: 2.5-53), having a caregiver who did not wash hands with soap and water after visiting the toilet (AOR=3.9; CI: 1.2-13), and living in households that used borehole water versus piped water (AOR=4.0; CI: 1.7-9.6) were associated with AWD. Conclusion: Comorbidities, failure of caregivers to wash their hands with soap after visiting toilets, and use of borehole water were associated with AWD. Community sensitization on handwashing at critical times, using clean water and soap, and expanded use of piped water could reduce AWD incidence in this area.
Introduction
Acute watery diarrhea (AWD) is the second leading cause of mortality among children aged 0–59 months worldwide, causing an estimated 525,000 deaths and 1.7 billion child cases annually (1). In Uganda, acute watery diarrhea is among the top ten causes of morbidity in children aged 0–59 months, accounting for up to 8% of all outpatient visits (2). The trends and spatial distribution of acute watery diarrhea among children aged 0–59 months from 2016–2021 showed an average national incidence of 12 (±2.1) cases per 100 children (E.N., unpublished data).
Studies in Ethiopia and Zambia showed that the use of unprotected water sources, age of the child caregiver, child weaning time, family size, low maternal education, poor sanitation, contaminated water source, duration of breast feeding, failure to wash hands, absence of rotavirus vaccination, failure to dispose of feces hygienically, and adequate food hygiene were significant predictors of AWD among children aged 0–59 months (3-9). Other studies showed that child-related factors such as sex (10), age (11), and malnutrition (12) were associated with childhood diarrhea.
The World Health Organization (WHO) recommends the use of the rotavirus vaccine as part of a comprehensive strategy to control AWD in addition to treatment packages and preventive strategies such as oral rehydration salt (ORS) solution, zinc supplements, rehydration with intravenous fluids (in cases of severe dehydration or shock), promotion of early and exclusive breastfeeding, continuous breast feeding (breast milk is an excellent rehydration fluid), hand washing, supply of clean and safe water and sanitation, and provision of nutrient-rich foods (13, 14).
The majority of children (90%) who receive the rotavirus vaccine are protected from severe rotavirus diarrhea, and approximately 70% of them are completely protected from all forms (severe and mild) of rotavirus disease (15). Before the introduction of the rotavirus vaccine in 2018, rotavirus diarrhea was responsible for nearly 40% of all AWD cases and nearly 11,000 deaths among children under 5 years of age in Uganda annually (14, 16).
In addition to the WHO recommended treatment packages and preventive strategies for AWD that were already in use (17), on 26 June 2018, the government of Uganda through the Ministry of Health (MoH) introduced the rotavirus vaccine into the Uganda National Expanded Program on Immunization (UNEPI) to protect children from AWD (14, 16). The rotavirus vaccine is free and available in health facilities and through community vaccination outreaches throughout the country (18).
Uganda immunizes its children at 6 and 10 weeks of age with an interval of at least 4 weeks between doses (18).Acute watery diarrhea among children aged 0–59 months is a notifiable disease in Uganda (19). AWD surveillance is passive as part of the national integrated disease surveillance and response system (19). When an AWD case is diagnosed at a health facility, the information about that case is filled into the health facility outpatient register or inpatient register depending on whether the patient was treated as an outpatient or inpatient, respectively (19-21).
At the end of every month, the total number of AWD cases at the health facility are added and reported to the district and the MoH through the health unit outpatient monthly report (HMIS 105) and the health unit inpatient monthly report (HMIS form 108) (19-21). These reports are then uploaded into the electronic district health information system version 2 (DHIS2), where they are easily accessed by MoH policy makers and other stakeholders (19, 22).
Despite having a 2-dose rotavirus vaccination coverage of >95% from 2019–2022, Obongi District consistently reported the highest incidence rates of AWD in Uganda, with >45 cases/100 children aged 0–59 months each year from 2017–2021 (E.N., unpublished data). Identifying factors associated with AWD among children aged 0–59 months in Uganda would provide evidence to guide the Ministry of Health (MoH), Obongi District local government, and implementing partners to control AWD in this age group. To generate this evidence, we identified the factors associated with AWD among children aged 0–59 months in Obongi District in the month of April 2022.
Methods
Study setting
Obongi District is a refugee-hosting district in Uganda, primarily hosting refugees from South Sudan. Its refugee population was estimated at 128,500 persons (23), outnumbering the host community population, estimated at 50,000 people (24). It was estimated that 12% of refugees in Obongi District were children aged 0–59 months (23).
Obongi District is in the West Nile Region of Uganda and is bordered by Moyo District in the north, Adjumani District in the east, Yumbe District in the west, and Madi-Okolo District in the south. It comprises six subcounties (Aliba, Ewafa, Gimara, Itula, Obongi Town Council, and Parolinya) (25), of which Itula and Parolinya contributed more than 75% of the AWD cases among children aged 0–59 months in the district (22).
The current safe water coverage of Itula and Parolinya subcounties is 11,379 (95%), with only 73 (57%) of all water sources, 2 (60%) of the shallow wells, 52 (49%) of the deep boreholes, 6 (86%) of the rainwater tanks, and 13 (100%) of the tap stands in a functional state as of September 2022 (26). The household latrine coverage of Itula and Parolinya subcounties was 93.4% as of September 2022 (27).
Study design and population
We conducted an unmatched case–control study in Itula and Parolinya subcounties to assess the factors associated with AWD among children aged 0–59 months. The study respondents were child caregivers living in Itula and Parolinya subcounties of Obongi District in Uganda.
We defined a case of AWD as the passage of ≥3 loose or liquid stools per day with negative malaria and pneumonia tests in a child aged 0–59 months residing in Itula or Parolinya subcounties, Obongi District, from 1–30 April 2022.
A control was a child aged 0–59 months who did not suffer from AWD from 1–30 April 2022 and was from households that had no case in them residing in Itula or Parolinya Subcounties, Obongi District, from 1–30 April 2022. Overall, we studied children aged 6–59 months residing in Itula and Parolinya subcounties, Obongi District, from 1–30 April 2022.
Sample size
The sample size was determined using the Fleiss formula, which is one of the double population proportion formulas. The required sample size was calculated using the Fleiss formula in Epi Info software version 7 with the following assumptions: the prevalence of childhood diarrhea derived from a study performed by Asfaha K.F. et al in Zana District of Ethiopia in 2015 (28) with 18% and 34% proportions of controls and cases, respectively, using untreated drinking water as one of the determinant factors of acute watery diarrhea morbidity, a ratio of case to control of 1:2, 95% confidence level, 5% margin of error and 80% power to generate a sample size of 549. The final sample size for this study after considering a nonresponse rate of 5% was 579 (193 cases and 386 controls).
Case finding, sampling procedures, and exclusion criteria
We line listed 298 AWD cases among children aged 0–59 months documented in April 2022 in the 10 health facilities of Itula and Parolinya subcounties, which contributed more than 75% of the AWD cases in the district. Two hundred forty-one (81%) of the line listed case-patients were refugees from South Sudan.
The line list included the child’s name, nationality status, next of kin, age, date of visit to the health facility, diagnosis at discharge, laboratory investigations that were done and their results, village, and subcounty of residence. Once we listed all the cases from the outpatient and inpatient registers of the 10 health facilities, we selected the 193 cases from the line list by simple random sampling. Controls of the same age range as the cases were used.
Controls were randomly selected from the Community Health Workers’ list of households with children aged 0–59 months without any case during the study period (1–30 April 2022). One control was randomly selected from each control household. Cases and controls whose caregivers did not verbally consent to participate in the study and those whose caregivers were not available after two follow-up visits were excluded from the study.
Study variables and data collection
Using a pretested structured electronic questionnaire, we interviewed the mothers or caregivers of the cases and controls. The questionnaire had inbuilt skips, validations, and mandatory fields that ensured high-quality data collection. Variables considered for the case control study were identified after conducting an extensive literature review (3-12, 28).
These included child status (case/control), sociodemographic characteristics (nationality of household members; child’s sex, age, birth order, and subcounty of residence; household location in a refugee settlement or not, child caregiver’s category, age, marital status, and highest level of education attained; sex and occupation of the household head; number of household members and children 0–59 months in the household), child-caring practices (child received rotavirus vaccine, number of rotavirus vaccine doses received, child received measles vaccine, number of measles vaccine doses received, Vitamin A received in the 6 months, time the child spent on exclusive breastfeeding, child’s weaning age, age at which the child stopped breastfeeding, caregiver’s history of diarrhea, family member’s history of diarrhea, and child comorbidity status), and water, sanitation, and hygiene/WASH characteristics (main source of water in the home, roundtrip distance to fetch water, home drinking water treatment, separate storage container for drinking water, toilet facility at home, method of handwashing, caregiver hand washing after visiting the toilet, before feeding the child, after cleaning the child’s buttocks, after disposal of child’s stool/urine, and before preparing food, hand washing facility at home, hand washing facility near toilet, child stool disposal method, presence of child stool in compound, and presence of refuse in compound).
Data analysis
An Excel dataset from the electronic database server was exported to STATA version 14 for cleaning and subsequent descriptive and statistical analysis. The outcome variable was child status, which was dichotomized by assigning ‘1’ for the cases and ‘2’ for the controls. Descriptive statistics, such as frequencies with percentages, were computed for the different variables.
Logistic regression analysis was used at both the bivariate and multivariate levels to generate crude odds ratios (CORs) and adjusted odds ratios (AORs) with 95% confidence intervals (CIs), respectively. Crude associations were determined at bivariate analysis, and a cutoff point of p≤0.1 was used to consider variables for the logistical regression model using a backward stepwise method where confounders were controlled.
If variables included in the multivariate model resulted in a loss of significance, they were removed. Covariates with p<0.05 were considered factors associated with the incidence of AWD among children aged 0–59 months in Obongi District. We tested the model using the Hosmer–Lemeshow goodness of fit test.
We conducted additional common reference group analysis for the factors that were statistically significantly associated with AWD among children aged 0–59 months in Obongi District using MedCalc’s software (29). We also conducted a supplementary analysis of the main source of water in the household and drinking water treatment in the household using a common reference group.
Ethical considerations
The Ministry of Health of Uganda gave the directive and approval to carry out this investigation. In agreement with the International Guidelines for Ethical Review of Epidemiological Studies by the Council for International Organizations of Medical Sciences (1991) and the Office of the Associate Director for Science, CDC/Uganda, it was determined that this activity was not human subject research and that its primary intent was public health practice or disease control activity (specifically, epidemic or endemic disease control activity).
This activity was reviewed by the CDC and was conducted consistent with applicable federal law and CDC policy. All experimental protocols were approved by the US CDC human subjects review board and the Uganda Ministry of Health and were performed in accordance with the Declaration of Helsinki. Parental/legal guardian verbal informed consent was obtained on behalf of all the children before the start of each interview since they were aged less than 5 years.
Results
Sociodemographic characteristics of children aged 0–59 months, child caregivers, households, and household heads, Obongi District, Uganda, April 2022
A total of 193 cases and 386 controls with their respective mothers or caregivers were sampled for this study, with a response rate of 100% in both study groups. One hundred seventy-seven (91.7%) cases and 335 (86.8%) controls were refugees, 104 (53.9%) cases and 183 (47.4%) controls were male, 73 (37.8%) cases were aged 6–11 months and 127 (32.9%) controls were aged 24–35 months, 178 (92.2%) cases and 337 (87.3%) controls were living in refugee settlements, and 142 (73.6%) cases and 267 (69.2%) controls were from Itula Subcounty (Table 1).
Regarding child caregivers, 173 (89.6%) cases and 363 (94.0%) controls were cared for by their biological parents, 133 (68.9%) cases and 284 (73.6%) controls had caregivers aged 20–34 years, 142 (73.6%) cases, and 263 (68.1%) controls had caregivers who had attained primary education as their highest level of education (Table 1).
In this study, 117 (60.6%) cases and 243 (63.0%) controls were from households headed by males, and 133 (68.9%) cases and 243 (63.0%) controls were from households in which the households were mainly farmers. One hundred eight (56.0%) cases and 263 (68.1%) controls came from large households having 5–9 members, 128 (66.3%) cases and 240 (62.2%) controls came from households having 2–3 children aged 0–59 months, and 79 (40.9%) cases were second or third borne as 168 (43.5%) controls were fourth borne or more (Table 1).
Table 1.1: Sociodemographic characteristics of respondents in a study assessing the factors associated with acute watery diarrhea among children aged 0–59 months, Obongi District, Uganda, April 2022
Characteristic | Cases (N=193) | Controls (N=386) | ||
Frequency (n) | Percent (%) | n | % | |
Nationality of household members | ||||
Nationals | 16 | 8.3 | 51 | 13.2 |
Refugee | 177 | 91.7 | 335 | 86.8 |
Child sex | ||||
Female | 89 | 46.1 | 203 | 52.6 |
Male | 104 | 53.9 | 183 | 47.4 |
Child age group (Months) | ||||
0-5 | 25 | 13.0 | 46 | 11.9 |
6–11 | 73 | 37.8 | 69 | 17.9 |
12–23 | 58 | 30.0 | 127 | 32.9 |
24–35 | 28 | 14.5 | 81 | 21.0 |
36–47 | 3 | 1.6 | 38 | 9.8 |
48–59 | 6 | 3.1 | 25 | 6.5 |
Household in settlement | ||||
Yes | 178 | 92.2 | 337 | 87.3 |
No | 15 | 7.8 | 49 | 12.7 |
Subcounty | ||||
Itula | 142 | 73.6 | 267 | 69.2 |
Parolinya | 51 | 26.4 | 119 | 30.8 |
Caregiver category | ||||
Parent | 173 | 89.6 | 363 | 94.0 |
Grandmother | 15 | 7.8 | 19 | 4.9 |
Older siblings | 5 | 2.6 | 4 | 1.0 |
Marital status of caregiver | ||||
Married/Cohabiting | 165 | 85.5 | 358 | 92.7 |
Single | 14 | 7.3 | 19 | 4.9 |
Divorced/Separated | 14 | 7.3 | 9 | 2.3 |
Caregiver age group (yrs) | ||||
16–19 | 27 | 14.0 | 22 | 5.7 |
20–34 | 133 | 68.9 | 284 | 73.6 |
≥35 | 33 | 17.1 | 80 | 20.7 |
Highest education level caregiver | ||||
No formal education | 26 | 13.5 | 55 | 14.2 |
Primary | 142 | 73.6 | 263 | 68.1 |
Secondary | 22 | 11.4 | 63 | 16.3 |
Tertiary/University | 3 | 1.6 | 5 | 1.3 |
Table 1.2: Sociodemographic characteristics of respondents in a study assessing the factors associated with acute watery diarrhea among children aged 0–59 months, Obongi District, Uganda, April 2022
Characteristic | Cases (N=193) | Controls (N=386) | ||
Frequency (n) | Percent (%) | n | % | |
Sex household head | ||||
Male | 117 | 60.6 | 243 | 63.0 |
Female | 76 | 39.4 | 143 | 37.0 |
Occupation household head | ||||
Farmer | 133 | 68.9 | 243 | 63.0 |
Unemployed | 38 | 19.7 | 61 | 15.8 |
Business person | 16 | 8.3 | 54 | 14.0 |
Others | 6 | 3.1 | 28 | 7.3 |
HH size | ||||
Small (2–4) | 64 | 33.2 | 74 | 19.2 |
Large (5–9) | 108 | 56.0 | 263 | 68.1 |
Very Large (≥10) | 21 | 10.9 | 49 | 12.7 |
No. of children<5 years | ||||
One | 40 | 20.7 | 130 | 33.7 |
2–3 | 128 | 66.3 | 240 | 62.2 |
≥4 | 25 | 13.0 | 16 | 4.1 |
Child’s birth order | ||||
1st born | 44 | 22.8 | 70 | 18.1 |
2nd–3rd born | 79 | 40.9 | 148 | 38.3 |
≥4th born | 70 | 36.3 | 168 | 43.5 |
Child caring practices of respondents in a study assessing the factors associated with acute watery diarrhea among children aged 0–59 months, Obongi District, Uganda, April 2022
Among the children included in this study, 187 (96.9%) cases and 369 (95.6%) controls had received rotavirus vaccine, of which 159 (85%) cases and 311 (84.3%) controls had received two or more doses.
One hundred seventeen (60.6%) cases and 287 (74.4%) controls had received measles vaccines, of which 96 (82.1%) cases and 222 (77.4%) controls had only received one measles vaccine dose.
One hundred twenty-nine (66.8%) cases and 252 (65.3%) controls had received vitamin A supplementation in the six months before April 2022, 113 (58.5%) cases and 224 (58.0%) controls were exclusively breastfed for six months or more, 43 (22.3%) cases and 53 (13.7%) controls had caregivers who suffered from diarrhea during the study period, and 85 (44.0%) cases and 89 (23.1%) controls came from households that had another family member who suffered from diarrhea during the study period (Table 2).
Table 2: Child caring practices of respondents in a study assessing the factors associated with acute watery diarrhea among children aged 0–59 months, Obongi District, Uganda, April 2022
Characteristic | Cases (N=193) | Controls (N=386) | ||
Frequency (n) | Percent (%) | n | % | |
Rotavirus vaccine | ||||
Yes | 187 | 96.9 | 369 | 95.6 |
No | 6 | 3.1 | 17 | 4.4 |
Doses of rotavirus vaccine* | ||||
One | 28 | 15 | 58 | 15.7 |
≥Two | 159 | 85 | 311 | 84.3 |
Measles vaccine | ||||
Yes | 117 | 60.6 | 287 | 74.4 |
No | 66 | 34.2 | 89 | 23.1 |
Don’t know | 10 | 5.2 | 10 | 2.6 |
Doses of measles vaccine† | ||||
One | 96 | 82.1 | 222 | 77.4 |
≥Two | 21 | 17.9 | 65 | 22.6 |
Vitamin in previous 6 months | ||||
Yes | 129 | 66.8 | 252 | 65.3 |
No | 53 | 27.5 | 121 | 31.3 |
Don’t know | 11 | 5.7 | 13 | 3.4 |
Time exclusively breastfed | ||||
<6 months | 80 | 41.5 | 162 | 42.0 |
≥6 months | 113 | 58.5 | 224 | 58.0 |
Weaning age | ||||
<6 months | 80 | 41.5 | 162 | 42.0 |
At 6 months | 46 | 23.8 | 88 | 22.8 |
>6 months | 67 | 34.7 | 136 | 35.2 |
Age stopped breastfeeding (month) | ||||
0–6 | 87 | 45.1 | 124 | 32.1 |
7–18 | 39 | 20.2 | 71 | 18.4 |
≥18 | 67 | 34.7 | 191 | 49.5 |
Caregiver suffered from Diarrhea | ||||
Yes | 43 | 22.3 | 53 | 13.7 |
No | 150 | 77.7 | 333 | 86.3 |
Family member suffered from Diarrhea | ||||
Yes | 85 | 44.0 | 89 | 23.1 |
No | 108 | 56.0 | 297 | 76.9 |
Child had a comorbidity | ||||
Yes | 31 | 16.1 | 9 | 2.3 |
No | 162 | 83.9 | 377 | 97.7 |
Child had malnutrition | ||||
Yes | 28 | 14.5 | 8 | 2.1 |
Child had Diabetes Mellitus (DM) | ||||
Yes | 4 | 2.1 | 1 | 0.3 |
Child had HIV | ||||
Yes | 2 | 1.0 | 0 | 0 |
* Among 187 cases and 369 controls that received rotavirus vaccine, †Among 117 cases and 287 controls that received measles vaccine
Water, sanitation, and hygiene characteristics of respondents in Itula and Parolinya Subcounties, Obongi District, Uganda, April 2022
Concerning the water, 114 (59.1%) case and 160 (41.5%%) control households used pipped water as the main source of water, 135 (69.9%) case and 289 (74.9%) control households did not subject drinking water to any form of treatment, and 109 (56.5%) case and 251 (65.0%) control households had separate containers for drinking and domestic water.
All case and control households had toilets, 24 (12.4%) case and 97 (25.1%) control caregivers used water and soap to wash their hands, 106 (54.9%) case and 245 (63.5%) control caregivers did not wash their hands after visiting the toilet, and 43 (22.3%) case and 56 (14.5%) control households had child stool in their compounds (Table 3).
Table 3: Water, sanitation, and hygiene characteristics of respondents in Itula and Parolinya Subcounties, Obongi District, Uganda, April 2022
Characteristic | Cases (N=193) | Controls (N=386) | ||
Frequency (n) | Percent (%) | n | % | |
Main source of water | ||||
Pipped | 114 | 59.1 | 160 | 41.5 |
Borehole | 79 | 40.9 | 226 | 58.5 |
Roundtrip distance to fetch water | ||||
≤30 minutes | 98 | 50.8 | 200 | 51.8 |
>30 minutes | 95 | 49.2 | 186 | 48.2 |
Home water treatment* | ||||
Yes | 58 | 30.1 | 120 | 34.1 |
Separate container for drinking water | ||||
Yes | 109 | 56.5 | 251 | 65.0 |
Toilet facility at home (Yes) | 193 | 100.0 | 386 | 100.0 |
Method of handwashing | ||||
Water only | 129 | 66.8 | 218 | 56.5 |
Water and soap | 24 | 12.4 | 97 | 25.1 |
Don’t wash hands | 40 | 20.7 | 71 | 18.4 |
Wash hands after visiting the toilet | ||||
Yes | 87 | 45.1 | 141 | 36.5 |
Wash hands before feeding the child | ||||
Yes | 161 | 83.4 | 317 | 82.1 |
Wash hands after cleaning child’s buttock | ||||
Yes | 143 | 74.1 | 301 | 78.0 |
Wash hands after disposal of child’s stool/urine | 0.0 | 0.0 | ||
Yes | 149 | 77.2 | 303 | 78.5 |
Wash hands before preparing food | ||||
Yes | 146 | 75.6 | 289 | 74.9 |
Hand washing facility at home | ||||
Yes | 45 | 23.3 | 131 | 33.9 |
Hand washing facility near toilet† | ||||
Yes | 23 | 51.1 | 45 | 34.4 |
Child stool disposal method | ||||
Toilet | 170 | 88.1 | 350 | 90.7 |
Covered by soil | 18 | 9.3 | 28 | 7.3 |
Open space | 5 | 2.6 | 8 | 2.1 |
Child stool in compound | ||||
Yes | 43 | 22.3 | 56 | 14.5 |
Refuse in compound | ||||
Yes | 61 | 31.6 | 90 | 23.3 |
*Among 352 controls that responded to home water treatment, †Among 45 cases and 131 controls that received rotavirus vaccine
Factors associated with acute watery diarrhea among children aged 0–59 months in Obongi District, Uganda, April 2022
At the bivariate logistic regression analysis stage, children living in households with 5–9 people and more than 10 people had two times the odds of suffering from AWD than those from households with 1–4 people (COR: 2.1; CI: 1.4–3.2 and COR: 2 CI: 1.1–3.7, respectively).
Children suffering from a comorbidity such as HIV, malnutrition, and diabetes mellitus (DM) had eight times the odds of suffering from acute watery diarrhea than those who did not have a comorbidity (COR: 8.0; CI: 3.7–17).
Children living in households that had no hand washing facility near the toilet had two times the odds of suffering from acute watery diarrhea than those who lived in households that had a hand washing facility near the toilet (COR: 2.0; CI: 1.1–4).
Children living in households that had caregivers who did not wash their hands with soap after visiting the toilet had 40 percent more odds of suffering from acute watery diarrhea than those who lived in households that had caregivers who washed their hands with soap after visiting the toilet (COR: 1.4; CI: 1.1–2.0).
Children living in households that used borehole water had two times the odds of suffering from AWD than those who lived in households that used pipped water (COR: 2.1; CI: 1.4–2.9) (Table 4).
In the logistic regression model, after controlling for nationality of household members, child birth order, number of household occupants, child sex, household in settlement, and hand washing facility near the toilet, children suffering from a comorbidity such as diabetes and HIV had 12 times the odds of suffering from AWD than those who did not suffer from any comorbidity (AOR: 12; CI: 2.5–53), children whose caregivers did not wash hands with soap and water after visiting the toilet had four times the odds of suffering from acute watery diarrhea than those whose caregivers washed their hands after visiting the toilets (AOR: 3.9; CI: 1.2–13), and children living in households that used borehole water had four times the odds of suffering from acute watery diarrhea than those who lived in households that used pipped water (AOR: 4.0; CI: 1.7–9.6) (Table 4).
Table 4: Bivariate and multivariate logistic regression analysis results of factors associated with acute watery diarrhea among children aged 0–59 months, Obongi District, Uganda, April 2022
Characteristic | Case (N=193) | Control(N=386) | COR (95% CI) | AOR (95% CI) | ||
n | % | n | % | |||
Nationality of HH members | ||||||
Nationals | 16 | 8.3 | 335 | 86.8 | 1.00 | 1.00 |
Refugee | 177 | 91.7 | 51 | 13.2 | 0.6 (0.33–1.1) | 1.4 (0.23–7.9) |
Child’s birth order | ||||||
1st born | 44 | 22.8 | 70 | 18.1 | 1.00 | 1.00 |
2nd–3rd born | 79 | 40.9 | 148 | 38.3 | 1.2 (0.74–1.9) | 0.6 (0.17–1.9) |
≥4th born | 70 | 36.3 | 168 | 43.5 | 1.5 (0.94–2.4) | 0.9 (0.26–2.9) |
HH size | ||||||
Small (2–4) | 64 | 33.2 | 74 | 19.2 | 1.00 | 1.00 |
Large (5–9) | 108 | 56.0 | 263 | 68.1 | 2.1 (1.4–3.2) | 1.3 (0.44–3.9) |
Very large (≥10) | 21 | 10.9 | 49 | 12.7 | 2.0 (1.1–3.7) | 0.9 (0.18–4.6) |
Child sex | ||||||
Female | 89 | 46.1 | 203 | 52.6 | 1.00 | 1.00 |
Male | 104 | 53.9 | 183 | 47.4 | 0.8 (0.55–1.1) | 0.5 (0.22–1.2) |
Child had a comorbidity | ||||||
No | 162 | 83.9 | 377 | 97.7 | 1.00 | 1.00 |
Yes | 31 | 16.1 | 9 | 2.3 | 8.0 (3.7–17) | 12 (2.5–53) |
Household in settlement | ||||||
No | 15 | 7.8 | 49 | 12.7 | 1.00 | 1.00 |
Yes | 178 | 92.2 | 337 | 87.3 | 0.6 (0.32–1.1) | 0.3 (0.04–2.1) |
Hand washing facility near toilet† | ||||||
Yes | 23 | 51.1 | 45 | 34.4 | 1.00 | 1.00 |
No | 22 | 48.9 | 86 | 65.6 | 2.0 (1.1–4) | 1.1 (0.48–2.7) |
Wash hands with soap after visiting the toilet | ||||||
Yes | 87 | 45.1 | 141 | 36.5 | 1.00 | 1.00 |
No | 106 | 54.9 | 245 | 63.5 | 1.4 (1.1–2.0) | 3.9 (1.2–13) |
Main source of water | ||||||
Pipped | 114 | 59.1 | 160 | 41.5 | 1.00 | 1.00 |
Borehole | 79 | 40.9 | 226 | 58.5 | 2.1 (1.4–2.9) | 4.0 (1.7–9.6) |
* Significant association at p value < 0.05, †Among 45 cases and 131 controls that received rotavirus vaccine
Additional analysis of the three factors associated with AWD in this study (suffering from comorbidities such as HIV, caregiver’s failure to wash hands with soap after visiting the toilet and using borehole water) using a common reference group yielded the following: child comorbidity alone was associated with increased odds of AWD among children (OR: 10, CI: 1.4–93) (Table 5).
The odds of AWD among children having a caregiver who did not wash their hands after visiting the toilet and belonging to households that used borehole water were reduced by absence of a comorbidity (OR: 0.3, CI: 0.16–0.54).
The odds of AWD among children under the care of caregivers who did not wash their hands after visiting the toilet were increased by suffering from a comorbidity (OR: 4.6, CI: 1.2–18) (Table 5).
The odds of AWD among children belonging to households that used borehole water were reduced if their caregivers washed their hands after visiting the toilet and absence of a comorbidity (OR: 0.5; CI: 0.27–0.89) (Table 5).
Table 5: Common reference group analysis of factors associated with acute watery diarrhea among children aged 0–59 months, Obongi District, Uganda, April 2022
Main source of water | Washed hands with soap after visiting the toilet | Child had a comorbidity | Case (N=192) | Control (N=386) | OR (95% CI) | ||
n | % | n | % | ||||
Pipped (-) | Yes (-) | No (-) | 36 | 44 | 45 | 56 | 1.0 |
Borehole (+) | No (+) | Yes (+) | 6 | 55 | 5 | 45 | 1.5 (0.42–5.3) |
+ | + | – | 30 | 19 | 126 | 81 | 0.3 (0.16–0.54) |
+ | – | + | 6 | 100 | 0 | 0 | 16 (0.88–297) |
– | + | + | 11 | 79 | 3 | 21 | 4.6 (1.2–18) |
– | – | + | 8 | 89 | 1 | 11 | 11 (1.4–93) |
– | + | – | 59 | 35 | 111 | 65 | 0.7 (0.39–1.1) |
+ | – | – | 37 | 28 | 95 | 72 | 0.5 (0.26–0.85) |
* Significant association at p value <0.05
Discussion
Acute watery diarrhea has remained a major cause of morbidity and mortality among children 0–59 months in Uganda despite several interventions that have been put in place to address it. We set out to identify factors associated with AWD among children aged 0–59 months in Obongi District during April 2022.
This study showed that suffering from comorbidities such as HIV, caregiver’s failure to wash hands with soap after visiting the toilet and using borehole water were the factors associated with acute watery diarrhea among children aged 0–59 months in Obongi District.
In this study, children suffering from comorbidities such as HIV, malnutrition, and DM had higher odds of suffering from acute watery diarrhea than those who did not suffer from any comorbidity. These comorbidities lower the child’s immunity, and as a result, the child is predisposed to frequent infections such as AWD from agents and sources from which they would not have been infected (30).
Our findings are similar to findings from other studies in Zambia, Ethiopia, and Sudan that showed that comorbidities such as HIV and malnutrition were associated with recurrent AWD among children aged 0–59 months (9, 31, 32).
In this study, we also found that children whose caregivers did not wash their hands with clean water and soap after visiting the toilet had more odds of suffering from AWD than those whose caregivers washed their hands using clean water and soap after visiting the toilet.
This is not surprising since hand washing using clean water and soap kills diarrhea-causing organisms and hence reduces its transmission from one person to the other (33). Dirty hands serve as gateways for carrying infectious pathogens to the child’s food during feeding of the child, thereby predisposing the child to diarrhea-causing agents (33).
Similar findings were also reported in studies carried out in Ethiopia, Zambia, Botswana, Uganda, Tanzania, and Nepal, which also reported that caregivers’ hand washing habits, especially of washing hands with clean water and soap at critical times, such as after visiting the toilet, were protective against AWD among children 0–59 months (8, 9, 34-39).
However, a study carried out in Ethiopia among children aged 0–59 months did not find any significant association between washing hands at critical times, such as after visiting the toilet, and AWD (28).
This might be because that study was carried out among nationals of a fairly stable socioeconomic status compared to the current study, which was conducted primarily among refugees of a low socioeconomic status.
This study showed that children living in households that used borehole water had higher odds of suffering from AWD than those who lived in households that mainly used pipped water that was chlorinated. The chlorine in pipped water disinfects (kills) or inactivates diarrhea-causing organisms, hence rendering it safe for home use (40).
Itula and Parolinya subcounties of Obongi District are bounded by the River Nile and have high water tables, implying that toilets in the settlements could have easily contaminated the borehole water since the boreholes are not so deep.
A study in Tanzania reported that borehole water was contaminated by fecal material attributed to the entry of sewage (human wastes) into underground water and recommended the treatment or boiling of borehole water before consumption (41).
Although boreholes and other ground water sources are classified as improved and safe water sources(42), several microbiological studies of groundwater sources, including boreholes, have reported high rates of Escherichia coli, indicating fecal contamination of those sources (43-45).
The high population densities in the settlements where these boreholes are located could have exposed them to contamination by children who touch the spouts (water outlets) when fetching water.
A study conducted in Zimbabwe reported that although improved sources of water, such as boreholes, generally deliver ‘safe’ water, a proportion of those sources can easily be contaminated at the point of collection (46).
Findings from our study are similar to findings in another study carried out in Nigeria that showed that protected groundwater sources such as boreholes were associated with a high risk of contracting diarrhea (47).
However, our findings are contrary to findings in another study conducted in Uganda that showed that children from homes that mainly used borehole water were at reduced risk of AWD than those that mainly used piped water (48).
The major difference between that study and the current study is that it was a cross-sectional study using the 2000/2001 Uganda Demographic and Health Survey dataset (48), yet ours is a case control study.
That study never gave reasons why children aged 0–59 months from households that used borehole water were at a lower risk of contracting diarrhea compared to those who used pipped water.
Study limitations
This investigation had some limitations. Cases and controls were obtained for the month of April 2022; therefore, the seasonal variations in AWD during the year were not considered. Recall and social desirability bias might have influenced responses to some of the questions that were asked as they depended on the respondent’s own memory, and findings from this study are based on self-reported data, although several measures, such as quality control and observation checks, were incorporated into the questionnaire to ensure the accuracy of the data collected.
Conclusions and recommendations
Suffering from a long-term illness such as HIV, malnutrition, and DM, caregivers’ failure to wash their hands with soap after visiting toilets, and households using borehole water were associated with AWD among children aged 0–59 months in Obongi District. We recommended health facility management for all children with AWD. We also recommended education of communities on hand washing at critical times using clean water and soap and expanded use of boreholes and piped water.
Conflict of interest
The authors declare that they had no conflict of interest.
Acknowledgments
The authors would like to thank the Obongi District leadership, including the district health team for their permission to conduct the study, the health facility in charges and records assistants of the ten health facilities in Itula and Parolinya subcounties for their permission to review their health facility medical records, and the seven research assistants (Hope Suzan, Charles Amanzuru, Jane Piyo, Denis Obulejo, Abiko Gertrude, Abdulmalik Mahad, and Marupia Dorothy) that helped in data collection.
Copyright and licensing
All materials in the Uganda National Institute of Public Health Quarterly Epidemiological Bulletin is in the public domain and may be used and reprinted without permission; citation as to source; however, is appreciated. Any article can be reprinted or published. If cited as a reprint, it should be referenced in the original form.
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