Skip to main content
Advertisement
Browse Subject Areas
?

Click through the PLOS taxonomy to find articles in your field.

For more information about PLOS Subject Areas, click here.

  • Loading metrics

Child defecation and feces management practices in rural Bangladesh: Associations with fecal contamination, observed hand cleanliness and child diarrhea

  • Mahfuza Islam ,

    Roles Conceptualization, Data curation, Formal analysis, Investigation, Methodology, Project administration, Supervision, Validation, Visualization, Writing – original draft, Writing – review & editing

    mi_sheuli@icddrb.org

    Affiliation Environmental Intervention Unit, Infectious Disease Division, icddr,b, Dhaka, Bangladesh

  • Mahbubur Rahman,

    Roles Conceptualization, Methodology, Project administration, Supervision, Validation, Visualization, Writing – original draft, Writing – review & editing

    Affiliation Environmental Intervention Unit, Infectious Disease Division, icddr,b, Dhaka, Bangladesh

  • Leanne Unicomb,

    Roles Conceptualization, Formal analysis, Methodology, Writing – original draft, Writing – review & editing

    Affiliation Environmental Intervention Unit, Infectious Disease Division, icddr,b, Dhaka, Bangladesh

  • Mohammad Abdullah Heel Kafi,

    Roles Data curation, Formal analysis, Validation, Visualization, Writing – original draft

    Affiliation Environmental Intervention Unit, Infectious Disease Division, icddr,b, Dhaka, Bangladesh

  • Mostafizur Rahman,

    Roles Data curation, Formal analysis, Methodology, Project administration, Supervision, Validation, Visualization, Writing – original draft

    Affiliation Environmental Intervention Unit, Infectious Disease Division, icddr,b, Dhaka, Bangladesh

  • Mahfuja Alam,

    Roles Data curation, Methodology, Project administration, Supervision, Writing – original draft

    Affiliation Environmental Intervention Unit, Infectious Disease Division, icddr,b, Dhaka, Bangladesh

  • Debashis Sen,

    Roles Formal analysis, Methodology, Project administration, Supervision, Validation, Visualization, Writing – original draft

    Affiliation Environmental Intervention Unit, Infectious Disease Division, icddr,b, Dhaka, Bangladesh

  • Sharmin Islam,

    Roles Formal analysis, Project administration, Supervision, Validation, Visualization, Writing – original draft

    Affiliation Environmental Intervention Unit, Infectious Disease Division, icddr,b, Dhaka, Bangladesh

  • Amy J. Pickering,

    Roles Conceptualization, Formal analysis, Validation, Visualization, Writing – original draft

    Affiliation Civil and Environmental Engineering, Tufts University, Medford, MA, United States of America

  • Alan E. Hubbard,

    Roles Formal analysis, Validation, Visualization, Writing – original draft, Writing – review & editing

    Affiliation Division of Epidemiology and Biostatistics, University of California, Berkeley, CA, United States of America

  • Stephen P. Luby,

    Roles Conceptualization, Formal analysis, Project administration, Validation, Visualization, Writing – original draft, Writing – review & editing

    Affiliation Woods Institute for the Environment, Stanford University, Stanford, CA, United States of America

  • Benjamin F. Arnold,

    Roles Conceptualization, Formal analysis, Validation, Visualization, Writing – original draft, Writing – review & editing

    Affiliation Francis I. Proctor Foundation, University of California, San Francisco, CA, United States of America

  • John M. Colford Jr.,

    Roles Conceptualization, Formal analysis, Project administration, Validation, Visualization, Writing – original draft, Writing – review & editing

    Affiliation Division of Epidemiology and Biostatistics, University of California, Berkeley, CA, United States of America

  • Ayse Ercumen

    Roles Conceptualization, Data curation, Formal analysis, Funding acquisition, Investigation, Methodology, Project administration, Supervision, Validation, Visualization, Writing – original draft, Writing – review & editing

    Affiliation Department of Forestry and Environmental Resources, North Carolina State University, Raleigh, NC, United States of America

Abstract

Child open defecation is common in low-income countries and can lead to fecal exposure in the domestic environment. We assessed associations between child feces management practices vs. measures of contamination and child diarrhea among households with children <5 years in rural Bangladesh. We visited 360 households quarterly and recorded caregiver-reported diarrhea prevalence, and defecation and feces disposal practices for children <5 years. We examined caregiver and child hands for visible dirt and enumerated E. coli in child and caregiver hand rinse and stored drinking water samples. Safe child defecation (in latrine/potty) and safe feces disposal (in latrine) was reported by 21% and 23% of households, respectively. Controlling for potential confounders, households reporting unsafe child defecation had higher E. coli prevalence on child hands (prevalence ratio [PR] = 1.12, 1.04–1.20) and in stored water (PR = 1.12,1.03–1.21). Similarly, households reporting unsafe feces disposal had higher E. coli prevalence on child hands (PR = 1.11, 1.02–1.21) and in stored water (PR = 1.10, 1.03–1.18). Effects on E. coli levels were similar. Children in households with unsafe defecation and feces disposal had higher diarrhea prevalence but the associations were not statistically significant. Our findings suggest that unsafe child feces management may present a source of fecal exposure for young children.

Introduction

The proportion of the world population reporting they practiced open defecation fell from 24% in 1990 to 13% in 2015 [1]. In Bangladesh, only 2% of households had no access to a toilet and 4% lacked latrine access in rural areas as of 2013 [2]. However, several recent sanitation trials have shown mixed impact from latrine provision on health outcomes [37] and studies that measured fecal contamination at potential household exposure points found little or no effect of sanitation interventions in reducing fecal indicator bacteria [810], suggesting other sources of fecal contamination that are not adequately eliminated by typical sanitation interventions. One potential source is child open defecation, which remains common in low-income countries. Despite widespread latrine access, Bangladesh has the second lowest levels of reported safe disposal of child feces in the South Central Asia region [11]. Poor child feces management could be a potential contributor to health risk as young children with poorly developed immune systems have higher incidence of enteric infections than other age groups [12] and their feces are also more likely to contain higher quantities of transmissible pathogens [13]. The presence of a latrine may therefore not necessarily minimize exposure to fecal-oral pathogens through child feces [14], especially for young children who primarily spend time in the home environment and have frequent hand contact with feces or with soil contaminated by feces [15].

Fecal-oral pathogens are transmitted through a variety of routes from one host to the next, either as a result of direct transmission through contaminated hands, or indirect transmission via contamination of drinking water, food, and fomites [16, 17]. Young children frequently place their hands in their mouths, and in Bangladesh, it is also common to eat and to be fed by hand [18]. Previous studies in Bangladesh demonstrated that caregiver’s and children’s hands can contain fecal indicator organisms at concentrations of >100 colony forming units (CFU) per two hands [19]. The presence of child feces in the household environment could be a potential contributor to fecal contamination of hands in this setting. Drinking water in rural Bangladeshi households also often contains fecal indicator bacteria. While contamination levels are often low at the source (primarily tubewells), the microbiological water quality deteriorates significantly during storage and handling at home [20, 21]. The presence of child feces in the domestic environment could contribute to fecal contamination of tubewell water through infiltration and of stored drinking water via contaminated containers, hands and fomites during collection, handling and storage.

Few studies to date [2226] have assessed how child defecation and child feces management practices affect contamination along fecal-oral transmission pathways such as drinking water and hands. Understanding the impact of child defecation and child feces management practices on fecal exposure pathways could be important to identify sources of transmission that are not interrupted by conventional sanitation programs and might benefit from targeted interventions. In this study, among households with children <5 years in rural Bangladesh, we aimed to assess the association between reported child defecation/child feces disposal practices and (1) E. coli contamination of child and caregiver hands and stored drinking water, (2) observed cleanliness of caregiver and child hands, and (3) child diarrhea.

Materials and methods

Study design

We conducted a longitudinal study within a randomized controlled trial in rural Bangladesh (WASH Benefits Bangladesh trial, ClinicalTrials.gov NCT01590095). The parent trial was conducted in the Gazipur, Kishoreganj, Mymensingh and Tangail districts of rural Bangladesh [27, 28]. The trial randomly assigned geographically pair-matched clusters of pregnant women to water, sanitation, hygiene and nutrition intervention vs. control arms and followed their birth cohort of “index children” (children of enrolled pregnant women that were in utero at the time of enrollment) for approximately two years to assess intervention impacts on child growth, diarrhea and enteric infections. Additional details of the study design and interventions have been described elsewhere [2729].

We conducted a longitudinal sub-study of environmental contamination among randomly selected households enrolled in the sanitation and control arms of the WASH Benefits trial to leverage the design and infrastructure of the large-scale randomized controlled trial. Households were eligible for enrollment in the sub-study if the index child was alive and available or if there was another child <24 months available in the household. In this analysis, we report measurements from the 360 households enrolled in the control arm of the longitudinal sub-study to assess the relationship between child feces management practices and fecal contamination in the domestic environment.

Data collection

We visited households enrolled in the sub-study approximately every three months for a total of eight visits over 2.5 years between June 2014 and December 2016. At each visit, trained field staff from the International Centre for Diarrhoeal Disease Research, Bangladesh (icddr,b) used a structured questionnaire to record caregiver-reported defecation and feces disposal practices and 2-day and 7-day prevalence of diarrhea (defined as ≥3 loose stools in 24 hours) for children <5 years. The questionnaire also included information on reported water treatment practices, and the field staff conducted spot check observations to observe drinking water storage containers, household hygiene conditions, sanitation facilities, and the presence of any human feces within the compound. At each visit, field workers also examined caregiver and index child hands (finger nails, finger pads and palms of each hand) and recorded the presence of dirt using a three-point scale (visible dirt particles, unclean appearance, clean). Visible dirt particles were defined as specks of dirt, mud, soil, ash or any other visible material; unclean appearance was defined as no visible dirt particles but general uncleanliness; and clean was defined as would appear after someone washes hands or takes a bath.

Sample collection

At each visit, field staff collected 250 mL of drinking water from household storage containers by asking participants to provide a glass of water that they would give their young children to drink and pour it into a sterile Whirlpak bag (Nasco Modesto, Salida, CA). If the caregiver provided water directly from the water source, we collected a sample from the household’s primary drinking water storage container. Index child and mother hand rinse samples were collected by massaging and shaking the hands, one at a time, in 250 mL of sterile water in a sterile Whirlpak bag. All samples were placed on ice and transported to the icddr,b field laboratory for analysis for E. coli within 12 hours of collection.

Sample processing

Samples were processed with the IDEXX Quantitray-2000 system. Stored drinking water was analyzed undiluted in 100 mL aliquots; caregiver and child hand rinse samples were diluted 1:2 by adding 50 mL of distilled water to 50 mL from hand rinse samples for a total volume of 100 mL. Colilert-18 media was added to samples, followed by incubation at 44.5 oC for 18 hours to enumerate the most probable number (MPN) of E. coli [30]. MPN values were derived from the number of fluorescent wells on the trays using the IDEXX Quantitray-2000 MPN table and reported per 100 mL for water samples and per 2 hands for caregiver and child hands. Trays exceeding the upper detection limit of 2419 MPN were classified as too numerous to count (TNTC); the Quantitray-2000 system with this high detection limit was chosen to capture a range of contamination levels.

Quality control

Ten percent field blanks (one blank for every 10 samples) and 5% replicates (repeat aliquots from the same sample) were processed for quality control. Field workers collected field blanks by asking respondents to pour distilled water from a sterile bottle into a Whirlpak as if collecting a stored water sample and by opening and messaging a Whirlpak prefilled with distilled water as if sampling a hand. One laboratory blank was processed per lab technician per day.

Data analysis

For our exposure variables, we defined safe child defecation as reported defecation in a potty or latrine, and unsafe defecation as defecation on a piece of cloth, on the floor/bed inside the house, on the ground in the compound/front yard, or in bushes/fields for the child’s last reported defecation event; defecation in a cloth was considered unsafe defecation as this does not sufficiently isolate child feces from the environment. We defined safe child feces disposal as caregivers reporting that feces were put/rinsed into latrine or specific pit or buried, and unsafe child feces disposal as feces put/rinsed into a drain, ditch, bush or garbage heap or left on the ground for the child’s last reported defecation event. For our outcome variables, we defined E. coli prevalence as the detection of ≥1 MPN E. coli per 100 mL of drinking water and per 2 hands, and we also calculated log10-transformed E. coli counts. We replaced E. coli counts over the detection limit with 2420 MPN and counts for non-detects with 0.5 MPN before calculating the logarithm. We defined dirty hands as those with visible dirt particles on palms, pads or nails of one or both hands.

We compared the prevalence and log10-transformed concentration of E. coli in stored water and hand rinse samples, the prevalence of caregiver and child hands with visible dirt, and the prevalence of diarrhea with 2-day and 7-day symptom recall periods between households with unsafe vs. safe child defecation and child feces disposal practices. We estimated the prevalence ratio (PR) for the binary outcomes and the difference in log-transformed E. coli counts, using pooled data from all follow-up visits. We conducted bivariate and multivariable analyses using generalized linear models (GLM) with robust standard errors to account for the geographical clustering of WASH Benefits households and for repeated measures within the same individual. For each outcome we investigated, we identified potential confounders as factors that are predictive of the dependent variable and also likely to be associated with the independent variables of interest. We considered the following covariates as potential confounders: age of index child, education of mother/caregiver, education of father, household wealth index based on principle components analysis [31, 32], and season. In the multivariable model we included all covariates that were associated with the dependent variable at the p<0.2 level in bivariate analyses.

We also assessed if the associations between child feces management and our study outcomes vary by season. We pre-specified three distinct seasons before examining outcomes: a hot, humid summer (mid-March to mid-June), a cool, rainy monsoon season (mid-June to mid-October) and a cool, dry winter (mid-October to mid-March) to reflect the typical temperature and rainfall patterns of the region [33]. Bangladesh receives over >80% of its rainfall during the monsoon season [34]. Summers and winters are dry, with summer temperatures ranging between 30–40°C and winter temperatures ranging between 10–30°C [33]. For each outcome we investigated, we assessed effect modification by season by including interaction terms between the exposure variable and season in the models. We examined the statistical significance of the interaction terms with a Wald test comparing the models with and without the interaction terms, and we interpreted a p-value <0.2 as evidence of effect modification by season.

Ethical considerations

All households provided written informed consent. The study protocol was reviewed and approved by human subjects review committees at icddr,b (PR-11063), University of California, Berkeley (2011-09-3652), and Stanford University (25863).

Results

Household characteristics

Among the 360 households enrolled in this study, mean age of the children at enrollment was 13 months (SD = 2.9). Mean age of the mothers was 24 years (SD = 5), and about 43% of mothers had secondary and above education. The mean number of children <5 years in the compound was 2 (SD = 1.1). About 34% of the households had natural walls (jute, bamboo or mud), 57% of households had electricity and about 86% of households had a cell phone (Table 1).

thumbnail
Table 1. Enrollment characteristics of study households with at least one child <5 years in rural Bangladesh (N = 360).

https://doi.org/10.1371/journal.pone.0236163.t001

The most frequently observed drinking water storage containers were pitchers (55%) and kalash (a lidless aluminum vessel with a narrow mouth but a wide brim that is typically covered using a plate) (38%). Among these, 81% of pitchers and 77% of kalash were observed to be uncovered (Table 2). About 98% of the households had access to a latrine and 64% of households had an improved primary latrine (Table 2). Among the 360 households visited eight times over the study period, there were 2655 reported last child defecation and 2611 reported last child feces disposal events. Among these, 21% (n = 548) reported safe defecation and 23% (n = 607) reported safe feces disposal. Fewer than 1% of households (n = 21) had human feces observed in the compound area. The caregiver-reported prevalence of diarrhea among children <5 years was 7.1% for a 2-day recall window and 11.8% for a 7-day recall window (Table 2).

thumbnail
Table 2. Water, sanitation and hygiene conditions among enrolled households and reported diarrhea for children <5 yearsa.

https://doi.org/10.1371/journal.pone.0236163.t002

Hand and drinking water contamination

A total of 2662 caregivers hand rinse samples, 2623 child hand rinse samples and 2319 stored drinking water samples were collected from 360 household over eight visits. Among these, 75% (n = 1988) of caregiver hand rinse samples, 75% (n = 1963) of child hand rinse samples and 81% (n = 1870) of stored drinking water samples were E. coli positive. The geometric mean E. coli count on caregiver and child hands was 1.15 (SD = 0.92) and 1.17 (SD = 0.91) log10 MPN per 2 hands, respectively, and 1.34 (SD = 0.93) per 100 mL for stored drinking water (Table 3). We observed visible dirt on 67% (n = 1775) of child hands and 79% (n = 2083) of caregiver hands (Table 2).

thumbnail
Table 3. Presence and concentration of E. coli in caregiver and child hand rinse and stored drinking water samples among households with child <5 years in rural Bangladesh.

https://doi.org/10.1371/journal.pone.0236163.t003

Unadjusted analyses

Prevalence of E. coli in stored drinking water and caregiver and child hand rinse samples was significantly higher among households where unsafe (vs. safe) defecation and unsafe (vs. safe) child feces disposal was reported for children <5 years (Table 4). Levels of E. coli in child hand rinse samples were significantly higher among households with unsafe child defecation (Table 5). Levels of E. coli in stored water samples were significantly higher among households with unsafe child defecation and feces disposal (Table 5). There was no association between E. coli levels in caregiver hand rinse samples and reported child defecation child feces disposal practices (Table 5). In households where unsafe child defecation and feces disposal was reported, children were more likely to have visible dirt on their hands but there was also no statistically significant association between the prevalence of visible dirt on caregiver hands and reported child defecation or feces disposal practices (Table 6). Children in households with unsafe child defecation and feces disposal had higher prevalence of diarrhoea measured both with 2-day and 7-day recall but the only statistically significant association was the one between unsafe child feces disposal and 7-day diarrhea prevalence (Table 7).

thumbnail
Table 4. Reported child defecation and child feces disposal practices vs. prevalence of E. coli on caregiver and child hands and in stored drinking water.

https://doi.org/10.1371/journal.pone.0236163.t004

thumbnail
Table 5. Reported child defecation and child feces disposal practices vs. level of E. coli on caregiver and child hands and in stored drinking water.

https://doi.org/10.1371/journal.pone.0236163.t005

thumbnail
Table 6. Reported child defecation and child feces disposal practices vs. observed cleanliness of caregiver and child hands.

https://doi.org/10.1371/journal.pone.0236163.t006

thumbnail
Table 7. Reported child defecation and child feces disposal practices vs. caregiver-reported diarrhea prevalence among children <5 years.

https://doi.org/10.1371/journal.pone.0236163.t007

Adjusted analyses

In multivariable models controlling for child age, household wealth and mothers’ education, the prevalence of E. coli in caregiver hand rinse samples was no longer associated with reported child defecation and child feces disposal practices. E. coli prevalence in child hand rinse samples remained significantly higher among households reporting unsafe child defecation (PR: 1.12, 1.04–1.20) and unsafe child feces disposal (PR: 1.11, 1.02–1.21). E. coli prevalence in stored drinking water was also significantly higher in households reporting unsafe child defecation (PR: 1.12, 1.03–1.21) and unsafe child feces disposal (PR: 1.10, 1.03–1.18) (Table 4). E. coli levels on child hand rinse samples were no longer associated with reported child defecation and child feces disposal practices while levels of E. coli in stored drinking water remained significantly higher in households reporting unsafe child defecation (Δlog10: 0.15, 0.03–0.27) and unsafe child feces disposal (Δlog10: 0.11, 0.01–0.23) (Table 5). Similarly, the prevalence of visible dirt on child hands remained significantly higher among households with unsafe defecation and feces disposal (Table 6). The magnitude of effect estimates suggested higher 2-day prevalence of child diarrhea in households with unsafe defecation (PR: 1.39, 0.61–3.16) and unsafe feces disposal (PR: 1.69, 0.70–4.10) but these associations remained statistically non-significant (Table 7). Effects were similar for 7-day prevalence of diarrhea (Table 7).

Effect modification by season

The prevalence of E. coli on caregiver hands was 69% in the summer, 76% during the monsoon and 77% in the winter, while the prevalence of E. coli on child hands was 65% in the summer, 77% during the monsoon and 79% in the winter. The prevalence of E. coli in stored drinking water samples in the summer, monsoon and winter seasons was 69%, 76% and 77%, respectively (S1 Table). The prevalence of visible dirt on caregiver hands was similar (66–67%) across the seasons as was the prevalence of visible dirt on child hands (78–80%) (S1 Table). The caregiver-reported 2-day prevalence of diarrhea among children <5 years was 8.1% in the summer, 6.8% in the monsoon and 7.9% in the winter, while the 7-day prevalence of diarrhoea was 12% in the summer, 11% in the monsoon and 13% in the winter (S1 Table).

Subgroup analyses suggested that the association between unsafe child feces management and E. coli contamination of caregiver hands and stored water was more pronounced during the summer season than during the monsoon or winter seasons (interaction p-values <0.05) (S2 Table).

Discussion

The nationwide estimate for open defecation, as defined by lack of latrine access, is 2% in Bangladesh [2]. In our study, 98% of households had access to a latrine, consistent with these estimates. However, the majority of households reported unsafe child defecation and unsafe disposal of child feces, suggesting that open defecation by young children is common in this setting despite widespread access to on-site sanitation. Our findings are consistent with other studies in rural Bangladesh that found 74% unsafe child defecation and 80% unsafe child feces disposal reported by caregivers [9, 35], as well as three studies in India [23, 24, 36] and one study in Ethiopia reporting unsafe child defecation in 54–80% and unsafe child feces disposal in 67–81% of households [37]. Taken together, these studies suggest that, among households with young children, three quarters could be at risk of pathogen exposure from child feces in the home environment even when a latrine is present.

Our findings of increased fecal contamination associated with unsafe child feces management are consistent with evidence from other settings. A study in India found that E. coli counts on household floors and in soil increased by up to an order of magnitude following child defecation on these surfaces after the feces were removed [23]. A study in Kenya using microbial source tracking methods to distinguish the feces of young children from the feces of older children and adults found that fecal contamination from young children dominated samples collected within the domestic environment, such as hands and surfaces [38].

We did not find an association between reported child defecation or feces disposal practices and E. coli contamination or visual cleanliness of caregiver hands, while child hands in households with unsafe child defecation and feces disposal were more likely to be contaminated by E. coli and be visibly dirty. One possible explanation for the lack of association between contamination of mothers’ hands and child feces management could be that E. coli levels on caregiver hands are highly temporally variable and fluctuate in response to various domestic tasks, which could mask any effect of exposure to child feces [39]. A study in India found an increase in E. coli counts on hands of caregivers after they handled child feces with unsafe methods but not with safe methods [23]. This study measured caregiver hand contamination immediately following feces handling events while we collected hand rinses at an arbitrary time during the interview. Our sampling method likely missed spikes in caregiver hand contamination associated with unsafe feces handling due to temporal variability. In contrast, our findings suggest that open child feces in the domestic environment increase the risk of fecal exposure among young children through contaminated hands. This could be because children spend time exploring the home environment and have frequent hand contact with feces or with soil contaminated by feces. Children’s interactions with the environment increase their risk of exposure to highly contaminated reservoirs like soil contaminated with lead [40], pesticides in agricultural communities [41], arsenic in water [42] or animal feces or animal manure used as cooking fuel [43]. A study in rural Bangladesh found that, in 5% of eating events, children’s hands contacted soil that may be highly contaminated by feces [15]. A study in Tanzania found that children placing contaminated hands in their mouths accounted for 97% of the total quantity of ingested fecal matter whereas only 3% was due to direct consumption of contaminated drinking water [44].

There is mixed evidence on the effect of overall sanitation improvements on hand cleanliness. A systematic review found that sanitation programs did not reduce fecal contamination on most transmission pathways including hands [10]. An observational study in Tanzania showed that improved sanitation was associated with reduction of fecal indicator bacteria on mothers’ hands [45] whereas a school-based randomized controlled trial in Kenya found that provision of latrines was associated with increased hand contamination among students [46], suggesting child hand contamination may be insensitive to sanitation improvements without accompanying improvements in hygiene. It is possible that sanitation programs, which typically focus on the feces of adults and older children, are insufficient to reduce fecal contamination in the home environment without measures for hygienic defecation and feces disposal for young children. The WASH Benefits Bangladesh trial, whose control arm for this study was nested in, had a sanitation intervention arm that received latrine upgrades, as well as child potties and scoops for removal of child and animal feces. The trial found borderline reductions in visible cleanliness of caregiver finger pads and palms, and no reductions in visible cleanliness or E. coli contamination of child hands among participants of the sanitation arm compared to control participants receiving no intervention [9]. This could have occurred because child feces management practices remained poor among recipients of the sanitation intervention despite access to hardware; respondents reported that <20% of children defecated safely in the latrine/potty, <30% of households disposed of child feces in the latrine and <10% of households used the scoop to handle child feces [9].

Our findings also suggest higher levels of E. coli contamination in stored drinking water in households with unsafe child feces management. Our study was not designed to differentiate contamination occurring at the source from contamination introduced during storage at home. The increased contamination we observed could be due to child feces in the compound environment entering the tubewell by subsurface infiltration or through unsealed head works [47, 48], or due to contact with hands and utensils during storage that have been contaminated by exposure to child feces [49, 50]. Several previous randomized control trials that assessed the association between sanitation and drinking water quality found no effect from sanitation [57], while a trial in Tanzania found reduced E. coli in drinking water associated with sanitation improvements [51]. In addition, several observational studies found no association between sanitation and drinking water quality [26, 52, 53], while an observational study in Indonesia found reduced fecal contamination of drinking water associated with improved sanitation [54].

Our findings suggest that unsafe child defecation and unsafe child feces disposal are associated with increased E. coli contamination of child hands and stored drinking water, suggesting the possibility of an increased risk of child gastrointestinal illness. The evidence to date on the association between child feces management and child diarrhea is mixed. Two randomized controlled trials conducted in rural Bangladesh found 27–30% reduction in pediatric diarrhea associated with disposing of child feces in a latrine and no visible feces being present in the household compound [55, 56]. In addition, unsafe child defecation and feces disposal behaviors were found to be associated with an increased risk of diarrheal diseases in an observational study conducted in Indonesia [57]. In contrast, a study in rural Bangladesh did not find any association between unsafe defecation and unsafe feces disposal and child gastrointestinal illness [35]. A recent meta-analysis that assessed the health impact of safe defecation and safe feces disposal showed that, out of five studies reviewed, only two found a reduction in diarrhea while the others did not find an association [58]. A study of Demographic and Health Survey (DHS) data from 34 countries also showed improved child growth associated with safe disposal of child feces [22]. The magnitude of effect estimates in our study suggested higher risk of diarrhea associated with unsafe child feces management; however, we could not rule out chance as the explanation for these associations. This could be because the analysis using diarrhea as the outcome had lower statistical power than those focused on the E. coli outcomes as the prevalence of diarrhea was low compared to the prevalence of E. coli in our samples.

Limitations

Our study had some limitations in terms of exposure and outcome measurements. We recorded caregiver-reported child defecation and child feces management practices which could be subject to courtesy bias and underestimate true levels by underreporting socially undesirable behaviors. Further, E. coli measurements do not distinguish between human vs. animal fecal sources [59] or between E. coli of fecal vs. natural origin [60]; this complicates interpretation of E. coli contamination detected along different pathways. Additionally, we relied on caregiver-reported diarrhea symptoms which can have inaccurate recall and also do not capture asymptomatic sub-clinical infections, which are common in low-income country settings [61].

Our analysis was observational and therefore susceptible to confounding. While we controlled for potential confounding factors in our analysis, it is possible that residual confounding remains from unmeasured factors. For example, households that practice unsafe child feces management could also have poorer hand hygiene and water handling practices. However, we did not find an association between child feces management and contamination of caregiver hands, suggesting no blanket confounding in our findings from unmeasured factors.

Conclusion

Unsafe child defecation and child feces disposal was reported by the majority of households in a rural Bangladeshi setting with widespread access to on-site sanitation. These practices were associated with increased E. coli contamination of child hands and stored drinking water, increased likelihood of visible dirt on child hands, and potentially increased risk of diarrhea. Our findings suggest that child open defecation and poor child feces management may be sources of fecal exposure for young children. Studies should assess if targeted interventions to improve child feces management practices reduce fecal contamination in the domestic environment and child diarrhea.

Supporting information

S1 Table. Mean E. coli prevalence and log10 MPN count by season (summer vs. monsoon vs. winter season).

https://doi.org/10.1371/journal.pone.0236163.s001

(DOCX)

S2 Table. Subgroup analysis by summer vs. monsoon/wet vs. winter/dry season on E. coli prevalence.

https://doi.org/10.1371/journal.pone.0236163.s002

(DOCX)

Acknowledgments

The authors would like to thank the participants for donating their time and the field team for collecting the data. We also thank all the collaborators engaged in the study.

References

  1. 1. World Health Organization. Guidelines for Drinking-Water Quality, 4th edn. WHO, Geneva, Switzerland. 2011.
  2. 2. Alam M, Halder A, Horng L. Bangladesh National Hygiene Baseline Survey Preliminary Report. Dhaka, Bangladesh2014. 2014.
  3. 3. Arnold BF, Khush RS, Ramaswamy P, London AG, Rajkumar P, Ramaprabha P, et al. Causal inference methods to study nonrandomized, preexisting development interventions. Proceedings of the National Academy of Sciences. 2010:201008944.
  4. 4. Briceño B, Coville A, Martinez S. Promoting handwashing and sanitation: evidence from a large-scale randomized trial in rural Tanzania: The World Bank; 2015.
  5. 5. Clasen T, Boisson S, Routray P, Torondel B, Jenkins M, Freeman M. The effectiveness of a rural sanitation intervention on health and Orissa, India: A clusterrandomized, controlled trial. American Journal of Tropical Medicine and Hygiene. 2014;5(suppl 1):215.
  6. 6. Patil SR, Arnold BF, Salvatore AL, Briceno B, Ganguly S, Colford JM Jr, et al. The effect of India's total sanitation campaign on defecation behaviors and child health in rural Madhya Pradesh: a cluster randomized controlled trial. PLoS medicine. 2014;11(8):e1001709. pmid:25157929
  7. 7. Pickering AJ, Djebbari H, Lopez C, Coulibaly M, Alzua ML. Effect of a community-led sanitation intervention on child diarrhoea and child growth in rural Mali: a cluster-randomised controlled trial. The Lancet Global Health. 2015;3(11):e701–e11. pmid:26475017
  8. 8. Ercumen A, Mertens A, Arnold BF, Benjamin-Chung J, Hubbard AE, Ahmed MA, et al. Effects of single and combined water, sanitation and handwashing interventions on fecal contamination in the domestic environment: a cluster-randomized controlled trial in rural Bangladesh. Environmental science & technology. 2018;52(21):12078–88.
  9. 9. Ercumen A, Pickering AJ, Kwong LH, Mertens A, Arnold BF, Benjamin-Chung J, et al. Do Sanitation Improvements Reduce Fecal Contamination of Water, Hands, Food, Soil, and Flies? Evidence from a Cluster-Randomized Controlled Trial in Rural Bangladesh. Environmental science & technology. 2018;52(21):12089–97.
  10. 10. Sclar GD, Penakalapati G, Amato HK, Garn JV, Alexander K, Freeman MC, et al. Assessing the impact of sanitation on indicators of fecal exposure along principal transmission pathways: a systematic review. International journal of hygiene and environmental health. 2016;219(8):709–23. pmid:27720133
  11. 11. UNICEF. Multiple Indicator Cluster Survey (MICS). https://www.unicef.org/statistics/index_24302.html. 2015.
  12. 12. Walker CLF, Perin J, Aryee MJ, Boschi-Pinto C, Black RE. Diarrhea incidence in low-and middle-income countries in 1990 and 2010: a systematic review. BMC public health. 2012;12(1):220.
  13. 13. Feachem RG, Bradley DJ, Garelick H, Mara DD. Sanitation and disease: health aspects of excreta and wastewater management: John Wiley and Sons; 1983.
  14. 14. Banda K, Sarkar R, Gopal S, Govindarajan J, Harijan BB, Jeyakumar MB, et al. Water handling, sanitation and defecation practices in rural southern India: a knowledge, attitudes and practices study. Transactions of the royal society of tropical medicine and hygiene. 2007;101(11):1124–30. pmid:17765275
  15. 15. Kwong LH, Ercumen A, Pickering AJ, Unicomb L, Davis J, Luby SP. Hand-and object-mouthing of rural Bangladeshi children 3–18 months old. International journal of environmental research and public health. 2016;13(6):563.
  16. 16. Esrey SA, Potash JB, Roberts L, Shiff C. Effects of improved water supply and sanitation on ascariasis, diarrhoea, dracunculiasis, hookworm infection, schistosomiasis, and trachoma. Bulletin of the World Health organization. 1991;69(5):609. pmid:1835675
  17. 17. Esrey SA. Water, waste, and well-being: a multicountry study. American journal of epidemiology. 1996;143(6):608–23. pmid:8610678
  18. 18. Ram PK, Jahid I, Halder AK, Nygren B, Islam MS, Granger SP, et al. Variability in hand contamination based on serial measurements: implications for assessment of hand-cleansing behavior and disease risk. The American journal of tropical medicine and hygiene. 2011;84(4):510–6. pmid:21460002
  19. 19. Huda TMN, Schmidt W-P, Pickering AJ, Unicomb L, Mahmud ZH, Luby SP, et al. Effect of Neighborhood Sanitation Coverage on Fecal Contamination of the Household Environment in Rural Bangladesh. The American Journal of Tropical Medicine and Hygiene. 2019:tpmd160996.
  20. 20. Hoque BA, Hallman K, Levy J, Bouis H, Ali N, Khan F, et al. Rural drinking water at supply and household levels: Quality and management. International journal of hygiene and environmental health. 2006;209(5):451–60. pmid:16765086
  21. 21. Shears P, Hussein M, Chowdhury A, Mamun K. Water sources and environmental transmission of multiply resistant enteric bacteria in rural Bangladesh. Annals of Tropical Medicine & Parasitology. 1995;89(3):297–303.
  22. 22. Bauza V, Guest JS. The effect of young children's faeces disposal practices on child growth: evidence from 34 countries. Tropical Medicine & International Health. 2017;22(10):1233–48.
  23. 23. Bauza V, Majorin F, Routray P, Sclar GD, Caruso BA, Clasen T. Child feces management practices and fecal contamination: A cross-sectional study in rural Odisha, India. Science of The Total Environment. 2020;709:136169. pmid:31905545
  24. 24. Bauza V, Reese H, Routray P, Clasen T. Child Defecation and Feces Disposal Practices and Determinants among Households after a Combined Household-Level Piped Water and Sanitation Intervention in Rural Odisha, India. The American journal of tropical medicine and hygiene. 2019;100(4):1013–21. pmid:30793682
  25. 25. Ercumen A, Naser AM, Unicomb L, Arnold BF, Colford JM Jr, Luby SP. Effects of source-versus household contamination of tubewell water on child diarrhea in rural Bangladesh: a randomized controlled trial. PloS one. 2015;10(3):e0121907. pmid:25816342
  26. 26. Eshcol J, Mahapatra P, Keshapagu S. Is fecal contamination of drinking water after collection associated with household water handling and hygiene practices? A study of urban slum households in Hyderabad, India. Journal of water and health. 2009;7(1):145–54. pmid:18957783
  27. 27. Arnold BF, Null C, Luby SP, Unicomb L, Stewart CP, Dewey KG, et al. Cluster-randomised controlled trials of individual and combined water, sanitation, hygiene and nutritional interventions in rural Bangladesh and Kenya: the WASH Benefits study design and rationale. BMJ open. 2013;3(8):e003476. pmid:23996605
  28. 28. Luby SP, Rahman M, Arnold BF, Unicomb L, Ashraf S, Winch PJ, et al. Effects of water quality, sanitation, handwashing, and nutritional interventions on diarrhoea and child growth in rural Bangladesh: a cluster randomised controlled trial. The Lancet Global Health. 2018;6(3):e302–e15. pmid:29396217
  29. 29. Parvez SM, Azad R, Rahman M, Unicomb L, Ram PK, Naser AM, et al. Achieving optimal technology and behavioral uptake of single and combined interventions of water, sanitation hygiene and nutrition, in an efficacy trial (WASH benefits) in rural Bangladesh. Trials. 2018;19(1):358. pmid:29976251
  30. 30. Yakub GP, Castric DA, Stadterman-Knauer KL, Tobin MJ, Blazina M, Heineman TN, et al. Evaluation of Colilert and Enterolert defined substrate methodology for wastewater applications. Water Environment Research. 2002;74(2):131–5. pmid:12043969
  31. 31. Vyas S, Kumaranayake L. Constructing socio-economic status indices: how to use principal components analysis. Health policy and planning. 2006;21(6):459–68. pmid:17030551
  32. 32. Howe LD, Galobardes B, Matijasevich A, Gordon D, Johnston D, Onwujekwe O, et al. Measuring socio-economic position for epidemiological studies in low-and middle-income countries: a methods of measurement in epidemiology paper. International journal of epidemiology. 2012;41(3):871–86. pmid:22438428
  33. 33. Climate of the world: Bangladesh | weatheronline.co.uk [Internet]. [cited 8 May, 2019].
  34. 34. Ahmed KM, Bhattacharya P, Hasan MA, Akhter SH, Alam SM, Bhuyian MH, et al. Arsenic enrichment in groundwater of the alluvial aquifers in Bangladesh: an overview. Applied Geochemistry. 2004;19(2):181–200.
  35. 35. Islam M, Ercumen A, Ashraf S, Rahman M, Shoab AK, Luby SP, et al. Unsafe disposal of feces of children< 3 years among households with latrine access in rural Bangladesh: Association with household characteristics, fly presence and child diarrhea. PloS one. 2018;13(4):e0195218. pmid:29621289
  36. 36. Majorin F, Freeman MC, Barnard S, Routray P, Boisson S, Clasen T. Child feces disposal practices in rural Orissa: a cross sectional study. PloS one. 2014;9(2):e89551. pmid:24586864
  37. 37. Azage M, Haile D. Factors associated with safe child feces disposal practices in Ethiopia: evidence from demographic and health survey. Archives of Public Health. 2015;73(1):40.
  38. 38. Bauza V, Madadi V, Ocharo RM, Nguyen TH, Guest JS. Microbial source tracking using 16S rRNA amplicon sequencing identifies evidence of widespread contamination from young children’s feces in an urban slum of Nairobi, Kenya. Environmental science & technology. 2019;53(14):8271–81.
  39. 39. Pickering AJ, Julian TR, Mamuya S, Boehm AB, Davis J. Bacterial hand contamination among Tanzanian mothers varies temporally and following household activities. Tropical medicine & international health. 2011;16(2):233–9.
  40. 40. Haefliger P, Mathieu-Nolf M, Lociciro S, Ndiaye C, Coly M, Diouf A, et al. Mass lead intoxication from informal used lead-acid battery recycling in Dakar, Senegal. Environmental Health Perspectives. 2009;117(10):1535–40. pmid:20019903
  41. 41. Cantu-Soto E, Meza-Montenegro MM, Valenzuela-Quintanar A, Félix-Fuentes A, Grajeda-Cota P, Balderas-Cortes J, et al. Residues of organochlorine pesticides in soils from the southern Sonora, Mexico. Bulletin of environmental contamination and toxicology. 2011;87(5):556. pmid:21761173
  42. 42. Mukherjee A, Sengupta MK, Hossain MA, Ahamed S, Das B, Nayak B, et al. Arsenic contamination in groundwater: a global perspective with emphasis on the Asian scenario. Journal of Health, Population and Nutrition. 2006:142–63.
  43. 43. Ercumen A, Pickering AJ, Kwong LH, Arnold BF, Parvez SM, Alam M, et al. Animal feces contribute to domestic fecal contamination: evidence from E. coli measured in water, hands, food, flies, and soil in Bangladesh. Environmental science & technology. 2017;51(15):8725–34.
  44. 44. Mattioli MCM, Davis J, Boehm AB. Hand-to-mouth contacts result in greater ingestion of feces than dietary water consumption in Tanzania: a quantitative fecal exposure assessment model. Environmental science & technology. 2015;49(3):1912–20.
  45. 45. Pickering AJ, Davis J, Walters SP, Horak HM, Keymer DP, Mushi D, et al. Hands, water, and health: fecal contamination in Tanzanian communities with improved, non-networked water supplies. Environmental science & technology. 2010;44(9):3267–72.
  46. 46. Greene LE, Freeman MC, Akoko D, Saboori S, Moe C, Rheingans R. Impact of a school-based hygiene promotion and sanitation intervention on pupil hand contamination in Western Kenya: a cluster randomized trial. The American journal of tropical medicine and hygiene. 2012;87(3):385–93. pmid:22802437
  47. 47. Knappett PS, McKay LD, Layton A, Williams DE, Alam MJ, Huq MR, et al. Implications of fecal bacteria input from latrine-polluted ponds for wells in sandy aquifers. Environmental science & technology. 2012;46(3):1361–70.
  48. 48. Knappett PS, McKay LD, Layton A, Williams DE, Alam MJ, Mailloux BJ, et al. Unsealed tubewells lead to increased fecal contamination of drinking water. Journal of water and health. 2012;10(4):565–78. pmid:23165714
  49. 49. Trevett AF, Carter RC, Tyrrel SF. Mechanisms leading to post-supply water quality deterioration in rural Honduran communities. International journal of hygiene and environmental health. 2005;208(3):153–61. pmid:15971854
  50. 50. Hammad ZH, Dirar HA. Microbiological examination of sebeel water. Appl Environ Microbiol. 1982;43(6):1238–43. pmid:7103483
  51. 51. Mattioli MC, Boehm AB, Davis J, Harris AR, Mrisho M, Pickering AJ. Enteric pathogens in stored drinking water and on caregiver’s hands in Tanzanian households with and without reported cases of child diarrhea. PloS one. 2014;9(1):e84939. pmid:24392161
  52. 52. Heijnen M, Routray P, Torondel B, Clasen T. Shared sanitation versus individual household latrines in urban slums: a cross-sectional study in Orissa, India. The American journal of tropical medicine and hygiene. 2015;93(2):263–8. pmid:26123953
  53. 53. Wedgworth JC, Brown J. Limited access to safe drinking water and sanitation in Alabama’s Black Belt: A cross-sectional case study. Water Quality, Exposure and Health. 2013;5(2):69–74.
  54. 54. Park M, Laksono B, Sadler R, Clements A, Stewart DE. Household latrines to control environmental contamination and helminthiasis: an exploratory study in Indonesia. International Journal of Social Science and Humanity. 2015;5(5):429.
  55. 55. Aziz K, Hoque BA, Hasan KZ, Patwary M, Huttly SR, Rahaman MM, et al. Reduction in diarrhoeal diseases in children in rural Bangladesh by environmental and behavioural modifications. Trans R Soc Trop Med Hyg. 1990;84(3):433–8. pmid:2260182
  56. 56. Alam N, Wojtyniak B, Henry FJ, Rahaman MM. Mothers' personal and domestic hygiene and diarrhoea incidence in young children in rural Bangladesh. Int J Epidemiol. 1989;18(1):242–7. pmid:2722372
  57. 57. Gil A, Lanata C, Kleinau E, Penny M. Children’s feces disposal practices in developing countries and interventions to prevent diarrheal diseases; A literature review. Strategic report 11, Bureau for Global Health. Washington, DC 20523 2004.
  58. 58. Morita T, Godfrey S, George CM. Systematic review of evidence on the effectiveness of safe child faeces disposal interventions. Trop Med Int Health. 2016;21(11):1403–19. pmid:27546207
  59. 59. Sinton L, Finlay R, Hannah D. Distinguishing human from animal faecal contamination in water: a review. New Zealand Journal of Marine and Freshwater Research. 1998;32(2):323–48.
  60. 60. Hardina C, Fujioka R. Soil: the environmental source of Escherichia coli and enterococci in Hawaii's streams. Environmental toxicology and water quality. 1991;6(2):185–95.
  61. 61. Taniuchi M, Sobuz SU, Begum S, Platts-Mills JA, Liu J, Yang Z, et al. Etiology of diarrhea in Bangladeshi infants in the first year of life analyzed using molecular methods. The Journal of infectious diseases. 2013;208(11):1794–802. pmid:24041797