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Exposure to cows is not associated with diarrhoea or impaired child growth in rural Odisha, India: a cohort study

Published online by Cambridge University Press:  04 June 2015

W.-P. SCHMIDT*
Affiliation:
Faculty of Infectious and Tropical Diseases, London School of Hygiene & Tropical Medicine, London, UK
S. BOISSON
Affiliation:
Faculty of Infectious and Tropical Diseases, London School of Hygiene & Tropical Medicine, London, UK
P. ROUTRAY
Affiliation:
Faculty of Infectious and Tropical Diseases, London School of Hygiene & Tropical Medicine, London, UK
M. BELL
Affiliation:
Faculty of Infectious and Tropical Diseases, London School of Hygiene & Tropical Medicine, London, UK
M. CAMERON
Affiliation:
Faculty of Infectious and Tropical Diseases, London School of Hygiene & Tropical Medicine, London, UK
B. TORONDEL
Affiliation:
Faculty of Infectious and Tropical Diseases, London School of Hygiene & Tropical Medicine, London, UK
T. CLASEN
Affiliation:
Faculty of Infectious and Tropical Diseases, London School of Hygiene & Tropical Medicine, London, UK Department of Environmental Health, Rollins School of Public Health, Emory University, Atlanta, GA, USA
*
*Address for correspondence: W.-P. Schmidt, Department of Disease Control, Faculty of Infectious and Tropical Diseases, London School of Hygiene and Tropical Medicine, Keppel Street, London WC1E 7HT, UK. (Email: Wolf-Peter.Schmidt@lshtm.ac.uk)
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Summary

Exposure to animal livestock has been linked to zoonotic transmission, especially of gastrointestinal pathogens. Exposure to animals may contribute to chronic asymptomatic intestinal infection, environmental enteropathy and child under-nutrition in low-income settings. We conducted a cohort study to explore the effect of exposure to cows on growth and endemic diarrhoea in children aged <5 years in a rural, low-income setting in the Indian state of Odisha. The study enrolled 1992 households with 2739 children. Height measurements were available for 824 children. Exposure to cows was measured as (1) the presence of a cowshed within or outside the compound, (2) the number of cows owned by a household, and (3) the number of cowsheds located within 50 m of a household. In a sub-study of 518 households, fly traps were used to count the number of synanthropic flies that may act as vectors for gastrointestinal pathogens. We found no evidence that environmental exposure to cows contributes to growth deficiency in children in rural India, neither directly by affecting growth, nor indirectly by increasing the risk of diarrhoea. We found no strong evidence that the presence of a cowshed increased the number synanthropic flies in households.

Type
Original Papers
Copyright
Copyright © Cambridge University Press 2015 

INTRODUCTION

The global burden of under-nutrition and stunting continues to be high. In India, despite economic growth and marked reductions in child mortality, under-nutrition and stunting remain common [1]. About 250 million Indians are classified as food-insecure [Reference Meade and Rosen2]. The reasons for the astonishingly high rates of stunting in India, if international growth standards are used, remain largely unexplained. The comparability of growth data from South Asia with the WHO standard continues to be debated [Reference Panagariya3].

While many indicators of poverty are strong predictors of stunting and under-nutrition, the pathways by which poverty and inadequate intake of macro- and micronutrients cause under-nutrition may be less obvious than previously assumed [Reference Humphrey4]. Many widely used nutrition interventions only have a small impact on child growth, and do not make up for the growth retardation earlier in life [Reference Humphrey4, Reference Dewey and Adu-Afarwuah5].

Apart from inadequate food intake, it has been suggested that children from poor families are exposed to frequent infections early in life, especially enteric infections, which are thought to impair growth and mental development. A vicious cycle has been proposed by which infection causes under-nutrition and under-nutrition in turn causes increased susceptibility to infection [Reference Guerrant6, Reference Guerrant7]. However, it has also been shown that catch-up growth after an episode of diarrhoea is fast in most children, and almost fully compensates for the growth retardation and weight loss during an episode [Reference Humphrey4].

Children growing up in unhygienic conditions harbour a large number of pathogens [Reference Taniuchi8] even if asymptomatic, and frequently display signs and laboratory markers of environmental enteropathy (EE) [Reference Humphrey4, Reference Keusch9]. EE is thought to result from exposure to environmentally occurring pathogens in settings characterized by poor hygiene, causing chronic inflammatory changes in the intestines, malabsorption and increased permeability of harmful intestinal products into the bloodstream. The implications of EE have recently gained wider interest in public health research, particularly in respect of providing a cleaner environment for children in poor settings [Reference Humphrey4, Reference Keusch9, Reference Schmidt10].

Apart from poor access to water, sanitation and hygiene, exposure to animal livestock may increase the risk of EE and subsequently under-nutrition in low-income settings. Animal livestock may also contribute to the burden of diarrhoea and the observed vicious cycle between infection and malnutrition. Animal livestock may further increase the risk of gastrointestinal infections by attracting flies that carry pathogens to food or directly to humans. The recent GEMS study suggested a high burden of diarrhoeal disease due to Cryptosporidium which is also common in cattle [Reference Kotloff11]. In India cows play an important economic, nutritional, cultural and religious role, and are a ubiquitous feature of the Indian urban and rural landscape. If exposure to cows contributes to the high prevalence of stunting and diarrhoea in India, then the implications for public health and agricultural policy would be enormous. In this study, we explored whether exposure to cows is associated with an increased risk of diarrhoea, exposure to synanthropic flies (as vectors of gastrointestinal pathogens) and impaired child growth.

METHODS

Study design and setting

The study was conducted in the context of a cluster randomized trial to evaluate the effect of sanitation on child health between September 2010 and October 2013 in Puri, a coastal district of the state of Odisha (formerly, Orissa), India. Odisha has a population of 43 million people and is home to 12 million cows [12]. Trial design, setting and characteristics of the study population have already been described [Reference Clasen13]. The trial included 100 rural villages spread across seven of the 11 blocks (an administrative sub-district) of Puri District. The intervention (latrine construction) was rolled out during 2011 in half of the villages. Households were eligible to participate in the study if they had a child aged <4 years or a pregnant woman living there. Households with a new baby born during the surveillance phase were also enrolled. The intervention had no impact on diarrhoea or stunting [Reference Clasen14]. The present cohort study included children from all enrolled households regardless of intervention allocation.

Exposure variables

A baseline survey was conducted between September and October 2010 to collect information on household demographics, cow ownership, house structure, type of fuel used for cooking, and water and sanitation access. Between December 2012 and March 2013 a survey of all households in the study area regardless of the presence of a child aged <5 years was performed to assess compliance with the intervention, and to record the GPS location of every household. In this survey we further assessed the household size and presence and location of a cowshed in each household. Location of a cowshed belonging to a household were recorded as within the compound, or outside the compound. Outside cowsheds were usually in the immediate vicinity of the compound, rarely more than 20 m away. As a measure of human population density, we calculated the number of residents within 50 m of each household enrolled in the study. As a measure of cow population density we counted the number of cowsheds around each household. This measure included cowsheds recorded as being inside and outside a compound, even though the exact location of cowsheds outside a compound was not geo-referenced. Therefore, some of the cowsheds counted here as being within 50 m of a household may in fact lie somewhat outside the 50 m radius.

Outcome variables

Child growth

A baseline measure of recumbent length/height was taken in January 2012 of all children aged <2 years. The same children and those born during the study were measured again in October 2013. For this analysis we only included measurements from the second survey. We measured recumbent length of children aged <2 years using Seca 417 boards (Seca, USA) with 1-mm increments. Height of children aged ⩾2 years was measured using a Seca 213 stadiometer. Back-checks on weight and height measurements were conducted in about 5% of the households selected at random. Height measures were transformed into height-for-age z-scores (HAZ) using the international growth standard from WHO Anthro software (WHO, Geneva).

Diarrhoea

The analysis of the association between exposure to cows and diarrhoea included all children aged <5 years enrolled in the trial. Between June 2011 and October 2013, households with children aged <5 years were followed up at 3-month intervals, resulting in a maximum of 10 rounds of observation per household. Children were excluded from the analysis once they were aged ⩾5 years. Seven-day period prevalence of diarrhoea was recorded based on reports from the primary caregiver [Reference Schmidt15, Reference Schmidt16]. Following qualitative research and extensive piloting, three local terms for loose stools were identified and used for the questionnaire. Reported presence of any of these three conditions ⩾3 times (according to the WHO definition [17]) on at least 1 day during the past 7 days was defined as diarrhoea.

Synanthropic flies

We measured the number of synanthropic flies (Musca domestica and M. sorbens) by installing 24-h fly traps in a random subsample of 572 households (nine households per village) from a random sample of 64/100 study villages (32 control, 32 intervention villages). Following extensive piloting of different trapping methods, blue sticky cards (Agrisense BCS Ltd, UK), with both sticky surfaces exposed and each measuring 20 × 24·5 cm, were placed at a 45° angle on the floor inside the kitchen, or cooking area, at a minimum of 0·5 m from an open source of flame. Sampling was conducted over three consecutive days in each selected household. Fly counts were averaged at household level over the 3 days of observation. Of the households, 518/572 (90·6%) could be linked to the data on cowshed ownership and were used in the analysis.

Statistical analyses

The association between socioeconomic variables and cow ownership (Table 1) was calculated using linear regression analysis. Linear regression was also used to estimate the effect of exposure variables on HAZ (Table 2). Since multiple children were enrolled in some households, we specified household as a random effect in the model. The models displayed normality of residuals and approximate homoscedasticity.

Table 1. Socio-demographic characteristics of the study households and cow ownership

HH, Household; CI, confidence interval.

* Linear regression analysis.

Table 2. Association between socioeconomic indicators, exposure to cows and height-for-age z score

HAZ, Height-for-age z score; HH, household; CI, confidence interval.

* Linear regression with random effect to adjust for multiple observations within households.

House structure omitted from model due to collinearity.

The association between exposure variables and prevalence of diarrhoea was estimated using log-binomial models (binomial distribution, log-link). Household-level clustering was accounted for by generalized estimating equations (GEE) with robust standard errors.

Due to right skew, fly counts were log10-transformed which resulted in a near normal distribution with some zero-inflation. A count of 1 was added to all counts to remove zero values prior to log transformation, and subtracted after calculating the geometric mean (Williams mean) [Reference Alexander18]. The association between presence of a cowshed in the household and log10 counts of synanthropic flies caught was estimated using the t test.

Because of the large potential for confounding due to the inherent association between stunting, diarrhoea and poverty, all models were adjusted for a range of socioeconomic variables: house structure (dichotomized as concrete/pucca vs. mud and semi-pucca), education of the head of the household and carer (dichotomized as completed primary school vs. not completed), latrine ownership at baseline, water source in the compound, landownership (any vs. none), and membership of a scheduled caste/scheduled tribe (SC/ST), a classification used by the Indian Government to identify socially and economically disadvantaged communities. An asset index including ownership of phone, watch, TV, chair, mattress, bed, table, fan and/or bike was constructed using principal component analysis (Kaiser–Meyer–Olkin index 91%). The first component, explaining 46% of the variation of the items was used in the analysis. This percentage compares favourably with many other asset indices [Reference Howe19]. Latrines constructed during the intervention phase were disregarded in this analysis as they were rarely used and not shown to affect health outcomes [Reference Clasen14]. All analyses were conducted in Stata v. 12 (Stata Corporation, USA).

Ethics

The study was conducted in the context of a trial which was approved by the Ethics Committee of the London School of Hygiene and Tropical Medicine, and in India by Xavier Institute of Management, Bhubaneswar (XIMB), and Kalinga Institute of Medical Sciences, KIIT University, Bhubaneswar. The trial was registered with ClinicalTrials.gov (registration no. NCT01214785). Written informed consent was obtained from the male and/or female head of household prior to baseline data collection. No additional data collection was done specifically for the purposes of this study.

RESULTS

The demographic characteristics of the study households in relation to the number of cows owned are shown in Table 1. Population density was not associated with the number of cows owned. Smaller households had fewer cows. Higher education level of the mother/carer was associated with more cows owned, education of the head of the household with fewer cows owned. Households using dung as the main fuel source had more cows. Other than that, indicators of higher socioeconomic status (not SC/ST, land ownership, house structure, water source in compound, latrine ownership) were largely associated with higher cow numbers owned. Forty-four percent of the study households did not own cows (Fig. 1a ). The number of cowsheds located within a 50 m radius of a house was highly correlated with population density (r = 0·93, Fig. 1b ).

Fig. 1. (a) Number of cows owned per household, (b) association between population density (number of residents within 50 m of a house) and number of cowsheds within 50 m (r = 0·93).

The mean HAZ was −1·41 (s.d. = 1·19, Table 1). Boys (n = 433) were 0·19 z scores taller than girls (n = 391) [HAZ −1·32 vs. −1·52, 95% confidence interval (CI) of the difference 0·03–0·36]. The effect of exposure to cows and child growth (HAZ) is shown in Table 2. After adjusting for socioeconomic indicators, SC/ST status and carer not having completed primary school were strongly associated with lower HAZ scores. By contrast, after adjusting for socioeconomic indicators, there was no evidence that the number of cows owned, a cowshed within the compound, the number of cowsheds within 50 m, or cow dung used as main fuel for cooking were associated with lower HAZ scores.

There was a steady decline in HAZ with age (Fig. 2). On average, children lost about 0·25 z scores per year in the first 4 years of life (95% CI −0·32 to −0·18). Children in households surrounded by fewer than 10, 10–19 and >20 cowsheds within 50 m lost on average 0·21, 0·19 and 0·26 z scores per year, respectively (test for interaction between age and number of cows: P = 0·59). There was also no evidence for an interaction affecting HAZ between age and in-compound presence of a cowshed (P = 0·69) and between age and the number of cows owned (P = 0·99). Thus, there was no evidence that exposure to cows led to a more rapid decrease in HAZ with age.

Fig. 2. Association between age and height-for-age z score (HAZ). Age was rounded to full months. Individual HAZ values were averaged within month.

Adjusting for socioeconomic factors, there was some evidence that high human population density was associated with a higher prevalence of diarrhoea. A lower prevalence of diarrhoea was reported for children with SC/ST background. A water source in the compound was protective against diarrhoea.

In crude and adjusted analysis, there was no evidence that cow ownership, cowshed density within 50 m of a household or use of cow dung for cooking increased the prevalence of diarrhoea (Table 3). There was no evidence for an interaction between exposure to cows and season: neither during the rainy nor the dry seasons were cow ownership, cowshed density within 50 m of a household or use of cow dung for cooking associated with an increased prevalence of diarrhoea (data not shown).

Table 3. Association between socioeconomic indicators, exposure to cows and diarrhoea in children aged <5 years

RR, Risk ratio; CI, confidence interval; HH, household.

* Log-binomial regression with generalized estimating equations to adjust for multiple observations within households.

House structure omitted from model due to collinearity.

The Williams mean of fly counts was 14·7 in households without a cowshed (n = 143), 18·9 in households with a cowshed outside the compound (n = 93) and 19·5 in households with a cowshed in the compound (n = 282). There was suggestive evidence that fly counts were higher in households with a cowshed within the compound compared to households without a cowshed (+0·12 log10, 95% CI −0·02 to 0·25). The difference between households with a cowshed outside the compound compared to households without a cowshed was inconclusive due to a wide confidence interval (+0·10 log10, 95% CI −0·08 to 0·28).

DISCUSSION

We found no evidence that environmental exposure to cows contributes to growth deficiency in children in rural India, neither directly by affecting growth, nor indirectly by increasing the risk of diarrhoea.

Environmental exposure to cows has been shown to increase the risk of infection and disease outbreaks of many gastrointestinal pathogens such as rotavirus [Reference Martella20], E. coli (including O157) [Reference Moller-Stray21, Reference Majalija22], Schistosoma japonicum [Reference Hong23, Reference Gray24], Cryptosporidium spp., and Giardia intestinalis. For example, a study of asymptomatic infection with G. intestinalis and Cryptosporidium conducted in Ethiopia revealed exposure to cattle as a risk factor for both [Reference Wegayehu, Adamu and Petros25], A further study from Ethiopia found evidence for zoonotic transmission of Cryptosporidium to HIV-positive individuals [Reference Adamu26]. One study from Egypt found that animal contact increased the risk of Cryptosporidium infection [Reference Helmy27]. However, further analysis in the same study suggested different transmission dynamics of human and cattle and little spatial overlap [Reference Helmy27]. Using sequence typing, the same study indicated a predominant anthropogenic cycle of infection of G. intestinalis in children with diarrhoea, despite the high prevalence of G. intestinalis in ruminants in the study area [Reference Helmy28].

Cow products and excreta have long been used in traditional Indian medicine [Reference Dhama29]. Cow dung is regarded as an important antiseptic. In our study area, it is used by households with mud floors for cleaning purposes and to improve the appearance of mud surfaces. Applying cow dung to the umbilical stump post-delivery is not an uncommon practice in parts of Africa and South Asia that, however, is associated with neonatal tetanus [Reference Idema30].

While it seems clear that exposure to cows can lead to symptomatic human infection and occasional outbreaks of gastrointestinal disease, the contribution of cow exposure to the overall burden of endemic (as opposed to epidemic) diarrhoea is less clear, given that diarrhoea is caused by a large number of pathogens most of which are easily transmitted among humans without requiring an animal reservoir. Our study suggests that the importance of direct exposure to cows for disease transmission may be small relative to other sources of infection. These results mirror those from a similar large-scale analysis from Vietnam that found no association between household or neighbourhood exposure to different types of livestock (e.g. poultry, cows, buffalos, pigs) and hospital admission for diarrhoea in children aged <5 years [Reference Thiem31].

The concept of EE suggests that most environmentally transmitted gastrointestinal pathogens lead to under-nutrition in children by causing a chronic inflammatory state in the intestines, and only to a lesser extent by causing diarrhoea [Reference Humphrey4, Reference Keusch9]. While EE has been found to be associated with both unhygienic conditions and stunting, we found no evidence that exposure to cows contributes to this assumed causal pathway. In our study, socioeconomic, caste and educational factors were most strongly associated with under-nutrition. However, education of the head of the household and carer, water access, house structure, assets, land ownership and caste combined only explained 12% (R 2) of the variation in HAZ in our study population. EE from unhygienic conditions, but perhaps not from exposure to cows, may explain a share of the variability in HAZ unaccounted for by the factors measured in our study.

Households with a cowshed in the compound had slightly higher fly counts than households without a cowshed. Further analysis of the fly counts will be published in a separate paper. Preliminary analysis revealed no clear trends towards presence of cows increasing the number of flies in a household (data not shown). This finding suggests that attraction of synanthropic flies to the human environment may largely be due to inadequacies in waste management or lack of barriers to keep flies away from spaces used for cooking rather than presence of cows or cow dung.

Our analysis has two major limitations. First, unmeasured and imprecisely measured confounders could explain the lack of association between exposure to cows and the study outcomes. Under-nutrition and diarrhoea are likely to be strongly associated with poverty, while in our study area cow ownership was more common in wealthier households. In multivariate regression analysis, these two associations may have cancelled each other out, resulting in no effect. Multivariate adjustment can only partially address confounding as, conceivably, many true confounders were not measured in our study while those that were could not be measured with perfect accuracy [Reference Kaufman, Cooper and McGee32].

The second major limitation of our study lies in the absence of a true control group. Similar to public health risks such as passive smoking or air pollution, few participants in our study population may have had no exposure to cows at all in their daily life. While the magnitude of cow exposure across different measures varied considerably within the study area (Fig. 1b ), the analysis would have benefitted from including fully unexposed households. Cowsheds and cows are proxy markers of exposure to cow dung as the most obvious potential source of infection from cattle. Families without cows may collect cow dung elsewhere for use in the household. We did not collect data on the presence of cow dung in and around each household which may have provided a more accurate estimate of exposure to cow dung as opposed to cow ownership or the presence of a cowshed. In the Vietnamese study that similarly found no effect of cow exposure on child health, exposure to livestock animals was very common. Unlike in our study, the kinds of animals differed greatly within the study area, i.e. there were many households with little or no cows in their neighbourhood. The absence of a protective effect in this group of households in Vietnam suggests that the lack of effect found in both studies may not alone be due households in the low exposure categories still being sufficiently exposed to experience a health risk.

Other limitations include imprecision in constructing the variable for the number of cowsheds located within 50 m of a house as the exact location of cowsheds outside the compound was not recorded (see Methods section). Further, the baseline measure assessing socioeconomic status and the number of cows owned was conducted 2 years before the collection of the geospatial data that included variables on the size of all households in the study area and presence of a cowshed. Child growth was recorded nearly 3 years after the baseline survey. Some of the study households may have undergone changes in socioeconomic status and number of cows owned during that time. Diarrhoea measurements were on self- or carer-reported symptoms. No attempts were made to identify severe episodes (e.g. those leading to hospital admission).

To conclude, the children in this study were at a high risk of stunting and diarrhoea. Exposure to cows did not appear to contribute to this disease burden. Our findings are compatible with the notion that most transmission of gastrointestinal disease occurs among humans. If EE critically contributes to stunting in rural India, then exposure to human excreta rather than cow dung may be the primary cause of chronic gut inflammation. However, corroborating this hypothesis may require further research including in-depth analysis of transmission pathways of gastrointestinal pathogens in low-income settings. Molecular methods including microbial source tracking able to distinguish between animal and human faecal exposure is being applied in this trial [Reference Clasen14] and in other studies [Reference Pickering33], and may contribute to our understanding of the causes of diarrhoea and stunting.

ACKNOWLEDGEMENTS

We are grateful to the following for their cooperation and support in this research: the Department of Rural Development of the State of Odisha and the Puri District Water and Sanitation Mission; WaterAid, United Artists Association and their collaborating partners; Loyola Hospital and the Asian Institute of Public Health, Bhubaneswar.

Funding was received from the Bill & Melinda Gates Foundation, the International Initiative for Impact Evaluation (3ie), and the DFID-backed SHARE Research Consortium at LSHTM.

DECLARATION OF INTEREST

None.

References

REFERENCES

1. HungaMa. The HUNGaMA Survey Report. HungaMa, 2011.Google Scholar
2. Meade, B, Rosen, S. International Food Security Assessment, 2013–2023. U.S. Department of Agriculture, Economic Research Service, 2013.Google Scholar
3. Panagariya, A. The myth of child malnutrition in India. In: India: Reforms, Economic Transformation and the Socially Disadvantaged. Columbia University, 2012.Google Scholar
4. Humphrey, JH. Child undernutrition, tropical enteropathy, toilets, and handwashing. Lancet 2009; 374: 10321035.Google Scholar
5. Dewey, KG, Adu-Afarwuah, S. Systematic review of the efficacy and effectiveness of complementary feeding interventions in developing countries. Maternal and Child Nutrition 2008; 4 (Suppl. 1): 2485.Google Scholar
6. Guerrant, RL, et al. The impoverished gut – a triple burden of diarrhoea, stunting and chronic disease. Nature Reviews Gastroenterology and Hepatology 2013; 10: 220229.Google Scholar
7. Guerrant, RL, et al. Diarrhea as a cause and an effect of malnutrition: diarrhea prevents catch-up growth and malnutrition increases diarrhea frequency and duration. American Journal of Tropical Medicine and Hygiene 1992; 47: 2835.Google Scholar
8. Taniuchi, M, et al. Etiology of diarrhea in Bangladeshi infants in the first year of life analyzed using molecular methods. Journal of Infectious Diseases 2013; 208: 17941802.CrossRefGoogle ScholarPubMed
9. Keusch, GT, et al. Implications of acquired environmental enteric dysfunction for growth and stunting in infants and children living in low- and middle-income countries. Food Nutrition Bulletin 201; 34: 357364.Google Scholar
10. Schmidt, CW. Beyond malnutrition: the role of sanitation in stunted growth. Environmental Health Perspectives 2014; 122: A298303.CrossRefGoogle ScholarPubMed
11. Kotloff, KL, et al. Burden and aetiology of diarrhoeal disease in infants and young children in developing countries (the Global Enteric Multicenter Study, GEMS): a prospective, case-control study. Lancet 2013; 382: 209222.CrossRefGoogle ScholarPubMed
12. Government of India. 19th Livestock census 2012. Department of Animal Husbandry. Delhi: Ministry Of Agriculture, 2012.Google Scholar
13. Clasen, T, et al. The effect of improved rural sanitation on diarrhoea and helminth infection: design of a cluster-randomized trial in Orissa, India. Emerging Themes in Epidemiology 2012; 9: 7.CrossRefGoogle ScholarPubMed
14. Clasen, T, et al. Effectiveness of a rural sanitation programme on diarrhoea, soil-transmitted helminth infection, and child malnutrition in Odisha, India: a cluster-randomised trial. Lancet Global Health 2014; 2: e645653.Google Scholar
15. Schmidt, WP, et al. Sampling strategies to measure the prevalence of common recurrent infections in longitudinal studies. Emerging Themes in Epidemiology 2010; 7: 5.Google Scholar
16. Schmidt, WP, et al. Epidemiological methods in diarrhoea studies – an update. International Journal of Epidemiology 2011; 40: 16781692.CrossRefGoogle ScholarPubMed
17. Joint Monitoring Committee - Water and Sanitation. (http://www.who.int/water_sanitation_health/monitoring/jmp2004/en/). 2005.Google Scholar
18. Alexander, N. Review: analysis of parasite and other skewed counts. Tropical Medicine International Health 2012; 17: 684693.Google Scholar
19. Howe, LD, 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: 871886.Google Scholar
20. Martella, V, et al. Zoonotic aspects of rotaviruses. Veterinary Microbiology 2010; 140: 246255.Google Scholar
21. Moller-Stray, J, et al. Two outbreaks of diarrhoea in nurseries in Norway after farm visits, April to May 2009. Eurosurveillance 2012; 17.CrossRefGoogle ScholarPubMed
22. Majalija, S, et al. Shiga toxin gene-containing Escherichia coli from cattle and diarrheic children in the pastoral systems of southwestern Uganda. Journal of Clinical Microbiology 2008; 46: 352354.Google Scholar
23. Hong, XC, et al. Assessing the effect of an integrated control strategy for schistosomiasis japonica emphasizing bovines in a marshland area of Hubei Province, China: a cluster randomized trial. PLoS Neglected Tropical Diseases 2013; 7: e2122.Google Scholar
24. Gray, DJ, et al. A cluster-randomized bovine intervention trial against Schistosoma japonicum in the People's Republic of China: design and baseline results. American Journal of Tropical Medicine and Hygiene 2007; 77: 866874.Google Scholar
25. Wegayehu, T, Adamu, H, Petros, B. Prevalence of Giardia duodenalis and Cryptosporidium species infections among children and cattle in North Shewa Zone, Ethiopia. BMC Infectious Diseases 2013; 13: 419.Google Scholar
26. Adamu, H, et al. Distribution and clinical manifestations of Cryptosporidium species and subtypes in HIV/AIDS patients in Ethiopia. PLoS Neglected Tropical Diseases 2014; 8: e2831.Google Scholar
27. Helmy, YA, et al. Frequencies and spatial distributions of Cryptosporidium in livestock animals and children in the Ismailia province of Egypt. Epidemiology and Infection 2015; 143: 12081218.Google Scholar
28. Helmy, YA, et al. Epidemiology of Giardia duodenalis infection in ruminant livestock and children in the Ismailia province of Egypt: insights by genetic characterization. Parasit Vectors 2014; 7: 321.CrossRefGoogle ScholarPubMed
29. Dhama, K, et al. Cowpathy: an overview. The Indian Cow: The Scientific and Economic Journal 2008; 5: 24.Google Scholar
30. Idema, CD, et al. Neonatal tetanus elimination in Mpumalanga Province, South Africa. Tropical Medicine International Health 2002; 7: 622624.Google Scholar
31. Thiem, VD, et al. Animal livestock and the risk of hospitalized diarrhoea in children under 5 years in Vietnam. Tropical Medicine International Health 2012; 17: 613621.Google Scholar
32. Kaufman, JS, Cooper, RS, McGee, DL. Socioeconomic status and health in blacks and whites: the problem of residual confounding and the resiliency of race. Epidemiology 1997; 8: 621628.Google Scholar
33. Pickering, AJ, et al. Hands, water, and health: fecal contamination in Tanzanian communities with improved, non-networked water supplies. Environmental Science and Technology 2010; 44: 32673272.Google Scholar
Figure 0

Table 1. Socio-demographic characteristics of the study households and cow ownership

Figure 1

Table 2. Association between socioeconomic indicators, exposure to cows and height-for-age z score

Figure 2

Fig. 1. (a) Number of cows owned per household, (b) association between population density (number of residents within 50 m of a house) and number of cowsheds within 50 m (r = 0·93).

Figure 3

Fig. 2. Association between age and height-for-age z score (HAZ). Age was rounded to full months. Individual HAZ values were averaged within month.

Figure 4

Table 3. Association between socioeconomic indicators, exposure to cows and diarrhoea in children aged <5 years