Risk factors for moderate acute malnutrition among children with acute diarrhoea in India and Tanzania: a secondary analysis of data from a randomized trial

Background

Moderate acute malnutrition (MAM) affects over 30 million children aged < 5 years worldwide. MAM may confer a greater risk of developing severe malnutrition and even mortality in children. Assessing risk factors for MAM may allow for earlier recognition of children at risk of deleterious health outcomes.

Objective

To determine risk factors associated with the prevalence and development of MAM among children aged 6 to 59 months with acute diarrhoea who received treatment with oral rehydration solution and zinc supplementation.

Methods

We conducted a secondary analysis of data from a randomized, dose-finding trial of zinc among children with acute diarrhoea in India and Tanzania. We used regression models to assess risk factors for prevalent MAM at the start of diarrhoea treatment and to identify risk factors associated with the development of MAM at 60 days. MAM was defined as weight for length (or height) Z score ≤—2 and > -3 or mid-upper arm circumference < 12.5 and ≥ 11.5 cm.

Results

A total of 4,500 children were enrolled; 593 (13.2%) had MAM at the baseline. MAM at baseline was significantly less common among children in Tanzania than in India (adjusted risk ratio [aRR] 0.37, 95% confidence interval [CI]: 0.30, 0.44, P < 0.001), in children aged 24- < 60 months versus 6- < 12 months (aRR 0.46, 95% CI: 0.38, 0.56, P < 0.001), and in families with household wealth index higher than the median (aRR 0.79, 95% CI: 0.68, 0.92, P = 0.002). Sixty days after outpatient treatment and follow-up, 87 (2.5%) children developed MAM. When compared to children aged 6- < 12 months, children aged 24- < 60 months had a 52% lower risk of developing MAM. Every one unit increase in weight for length (or height) Z score at enrolment was associated with a 93% lower risk of developing MAM during follow-up.

Conclusions

Among children with diarrhoea, younger children and those from households with lower wealth were at greater risk of MAM. These children may benefit from targeted interventions focusing on feeding (targeted nutrition support for at-risk households) and follow up in order to reduce the occurrence of MAM and its consequences.

Undernutrition remains prevalent in low- and middle-income countries. In India 17% of young children are estimated to be wasted while in Tanzania, 5% of children aged ≤ 5 years are wasted [1]. Approximately 40% of the world’s malnourished children live in India [2, 3] and childhood malnutrition contributes to 22% of India’s total disease burden among all age groups [3,4,5,6]. Besides, about 34.4% of children below five years in Tanzania are stunted and 14% are underweight [1]. Malnutrition in children is associated with multiple health outcomes, including greater risk of mortality, infections, as well as impaired physical and cognitive development [3,4,5,6]. As a result, identifying young children at risk for malnutrition may inform targeted interventions to prevent and treat acute childhood undernutrition.

Moderate acute malnutrition (MAM), defined as weight for length (or height) Z score ≤—2 and > -3 or mid-upper arm circumference < 12.5 and ≥ 11.5 cm, affects over 30 million children aged < 5 years worldwide [7]. Prior studies suggest that MAM affects up to 21% of hospitalized children aged < 5 in India and 5% in Tanzania [7, 8]. MAM confers greater risk for the development of severe acute malnutrition (SAM) and greater risk of childhood mortality [9]. Though much attention has been paid to identifying children at risk of developing SAM in resource-limited settings [10, 11], there is a paucity of studies aimed at determining risk factors for developing MAM.

Assessing risk factors associated with the development of MAM may facilitate early recognition of children at risk of MAM, which may allow for targeted interventions to prevent the development of SAM, mortality, and other sequelae of MAM. Here, our objective was to determine factors associated with the development of MAM among children enrolled in a randomized controlled trial of different doses of zinc for diarrhoea among children in India and Tanzania.

Study design

This secondary analysis was conducted using data from the Zinc Therapeutic Dose Trial (ZTDT) (NCT03078842). ZTDT was an individually randomised, parallel-group, double-blind, controlled trial of three doses of supplemental zinc (5, 10 and 20 mg) conducted among children aged 6–59 months at sites in Delhi, India and Dar es Salaam, Tanzania. Details of the methodology of the trial, and the primary results that showed non-inferiority of lower dose zinc on diarrhoea duration and stool output, have been published elsewhere [12, 13]. Briefly, this trial was conducted from January 2017 to April 2019 and included 4,500 children with diarrhoea lasting < 72 h. After enrolment, children were followed for 60 days with initial close follow up for 15 days to ensure compliance to therapeutic zinc. Subsequently, illnesses were assessed at days 30, 45, and 60. Participant anthropometry was assessed at enrolment (baseline) and 60 days after enrolment.

Study setting

Participants were recruited from outpatient health facilities in Sangam Vihar, a resettlement colony on the outskirts of South Delhi and Harsh Vihar, a semi-urban locality in North East District, Delhi, India. In Dar es Salaam, Tanzania, recruitment sites were outpatient health facilities in a densely populated peri-urban area (Temeke Municipal Hospital, Mbagala Round Table, and Mbagala Rangi Tatu).

Anthropometry

Body weight, length/height, and mid-upper arm circumference (MUAC) were measured during screening and 60 days later during a scheduled clinic visit with study staff. Body weight was measured using an electronic baby scale (ADE, ADE GmbH & Co, Hamburg, Germany) or weighing machine (SECA, SECA GmbH & Co, Hamburg, Germany) with reading increment of ± 10 g. If the child was dehydrated, the weight was obtained after rehydration. Length/height was measured by a stadiometer with reading increment of ± 0.1 cm. MUAC was measured in participants’ left upper arm, midway between the olecranon and acromion processes using standard WHO/UNICEF measuring tapes with a reading increment of ± 0.1 cm. Daily calibrations of the anthropometry equipment were conducted to ensure that the equipment produced accurate measurements. Weight measurement tools were calibrated with known weights of 3, 5, 10, and 15 kg. Stadiometers were calibrated using measuring rods of known length measuring 50 cm and 75 cm. Readings of all anthropometric measurements were made in triplicate and the mean of the three readings was used.

Outcomes and exposures

The primary outcome measure, MAM, was defined as weight-for-height Z score ≤ -2 and > -3 or mid-upper arm circumference < 12.5 and ≥ 11.5 cm according to WHO standards [7]. We performed separate analyses for the presence of MAM at baseline (prevalent MAM) and the development of MAM during follow-up (incident MAM). Assessment of the continuous variable weight-for-length Z scores (WHZ) at baseline and during follow-up was also assessed.

We included variables collected in the parent trial to conduct an exploratory analysis of factors theoretically associated with the development of MAM, both prevalent and incident. In addition, we excluded prevalent MAM and SAM at baseline from analyses of risk factors for incident MAM. Improved water was defined as water from sources like piped water that, by nature of their construction or through active intervention, are protected from outside contamination. Improved sanitation facilities were defined as those that hygienically separate human waste from human contact and include flush or pour-flush [14]. Dysentery was defined as acute diarrhoea with blood or mucous in stool. Household wealth index was defined as a measure of a household’s standard of living. A country-specific household wealth index was constructed by means of a principal components analysis of these factors: household ownership, household assets, drinking water source, and sanitation.

Statistical analysis

Descriptive statistics were used to summarize baseline characteristics of caregivers and children who participated in the trial. Frequencies were presented for categorical variables and mean ± standard deviation (SD) for continuous variables. Univariable log-binomial regression analyses were used to estimate risk ratios (RRs) and 95% confidence intervals (CIs) for predictors of the outcome of interest to produce relative risks. Variables significant at the P < 0.20 were retained in a multivariable log-binomial regression analysis model to calculate adjusted RRs. P values < 0.05 were considered statistically significant. Analyses were performed using SAS software Version 9.3 (SAS Institute, Cary, NC, USA).

There were 4,500 children enrolled in the trial (2,250 at each site). The mean age of enrolled children was 5.0 (± 26.8) years. A total of 593 (13.2%) children had prevalent MAM, 47 (1%) children had severe acute malnutrition (SAM), and 1,188 (26.4%) children were stunted at enrolment (Table 1).

At baseline and adjusting for the following variables; study site, maternal age > 25, child age in months, household wealth index above median, duration of diarrhoea before enrolment, observed respiratory rate > 40 breaths/min, cough or difficulty breathing and plasma zinc concentration at enrolment < 65 µg/dl, MAM was significantly less common among children in Tanzania than those in India (adjusted risk ratio [aRR] 0.37, 95% CI: 0.30, 0.44, P < 0.001) (Table 2). Compared with children 6– < 12 months of age, children ages 12– < 24 months (aRR 0.83, 95% CI: 0.70, 0.99, P < 0.04) and children aged ≥ 2 years (aRR 0.46, 95% CI: 0.38, 0.56, P < 0.001) had a significantly lower risk of prevalent MAM. Children who lived in a household with a wealth index above the median (aRR 0.79, 95% CI: 0.68, 0.92, P = 0.002) also had lower risk of prevalent MAM.

For the analysis of incident MAM, after excluding children who were lost to follow-up or developed SAM, 3,537 children were included in the analysis (Table 3). Of these, 87 (2.5%) developed MAM during follow-up. Despite excluding prevalent cases of MAM and SAM at baseline from analyses of risk factors for incident MAM, when compared to children in India, those in Tanzania had a 33% lower risk of developing incident MAM during the 60-day follow-up (P = 0.06). When compared to children aged 6- < 12 months, those aged 24- < 60 months old had a 52% lower risk (aRR 0.48, 95% CI: 0.27, 0.85, P < 0.01) of developing incident MAM. Moreover, every one unit increase in weight for length (or height) Z score at enrolment was associated with a 93% lower risk (aRR 0.07 95% CI: 0.04, 0.11, P < 0.001) of developing incident MAM. Further, in unadjusted analyses, maternal education, child sex, dysentery, fever, prior antibiotic use, improved water or improved sanitation were not associated with the development of moderate acute malnutrition.

In this secondary analysis of a randomized trial including 4,500 children at sites in India and Tanzania, MAM was common at enrolment. Among children with diarrhoea, younger children, those living in India, and those from households with less wealth were at greater risk of prevalent MAM. The high rate of prevalent a MAM in this study highlights the fact that insufficient nutritional status in children aged < 5 years in Tanzania and India may be an important risk factor for diarrhoea. Greater fluid losses through diarrhoea and reduced oral intake during these illnesses may contribute to worsening nutritional status [13,14,15]. At enrolment, MAM was less common among children at the site in Tanzania compared to children in India, which may be indicative of differences in study locations, populations, and underlying health and nutritional factors.

Household wealth played an important role in lowering the risk of prevalent MAM in our study, which aligns with results from previous studies conducted in low- and middle-income countries that demonstrated weight faltering or poor weight gain following an acute illness due to an infection, such as diarrhoeal disease [16,17,18,19]. Though not measured in this study, the built environment in which a child lives is crucial to determining their access to food and the diversity of foods available for their consumption [4, 9, 16]. Younger age and lower household wealth are key indicators of the development of MAM and these populations should be targeted in future therapeutic feeding programs. Additionally, higher WHZ at enrolment was associated with a lower risk of incident MAM during follow-up, which indicates the importance of good nutritional status in the prevention of developing MAM during an acute illness like diarrhoea in children.

We found that a number of factors that previous studies [5,6,7] have identified as risk factors for both prevalent and incident MAM (e.g., maternal education, dehydration, low plasma zinc and child sex) were not associated with MAM in our analyses. This might have been due to the strong association with study site and other identified risk factors, the absence of a biologic relationship, or limited power in the case of the relatively rare event of incident MAM.

Limitations

This study’s results should be interpreted in the context of several limitations. Since this was not a planned secondary analysis, the original trial was not powered a priori to primarily detect changes in anthropometry among enrolled children. Additionally, there are other potentially unmeasured confounders that were not accounted for in this study. Specifically, we did not measure dietary intake or the use of ready to use supplemental feeds, which may have prevented the development in MAM in some children. However, ready to use supplemental feeds are infrequently administered to children without malnutrition or with MAM in low- and middle-income countries including India and Tanzania [7, 15]. Furthermore, local ecology or geographical environment, residential culture, maternal knowledge of diarrhoea treatment, and government policies combating malnutrition and diarrhoea which are factors that may have a significant impact on development of MAM were not collected in our study and thus were not factored into our regression model. Finally, the incidence of MAM after enrolment (2.5%) was very rare, making our analyses of incident MAM likely underpowered.

Among children with diarrhoea, younger children and those from households with less wealth were at greater risk of MAM. These children should be prioritized in interventions that target feeding and follow up among children with diarrheal illnesses to reduce the occurrence of MAM as well as its sequelae and to contribute towards achieving Sustainable Development Goal number two (SDG 2) and Global Nutritional targets that aims at tackling of undernutrition and hunger. In addition, improving the "stock of health" (proxied by nutritional status at baseline) can be an effective strategy for preventing more severe illness when episodes of childhood diarrheal disease occur in low-resource environments.

The datasets analysed during this current study are available on reasonable request to kpmanji@gmail.com.

CI:

Confidence Interval

MAM:

Moderate Acute Malnutrition

MUAC:

Mid Upper Arm Circumference

SAM:

Severe Acute Malnutrition

UNICEF:

The United Nations Children’s Fund

WAZ:

Weight for Age Z score

WHO:

World Health Organisation

ZTDT:

Zinc Therapeutic Dose Trial

We thank the families and children for their participation in this trial. We also thank the study staff who contributed to this study.

This work was supported by the Bill and Melinda Gates Foundation. Dr. Duggan’s work is funded in part by grants (K24 DK104676 and P30 DK040561) from the National Institutes of Health.

1. Christopher P. Duggan and Karim Manji contributed equally as senior authors.

Authors and Affiliations

1. Department of Paediatrics and Child Health, Muhimbili University of Health and Allied Sciences, P.O. Box 65001, Dar Es Salaam, Tanzania

   Rodrick Kisenge, Sarah Somji & Karim Manji

2. Centre for Public Health Kinetics, New Delhi, India

   Usha Dhingra, Arup Dutta, Deb Saikat, Pratibha Dhingra & Sunil Sazawal

3. Division of Paediatric Emergency Medicine, Emory University School of Medicine, Atlanta, USA

   Chris A. Rees

4. Clinical Research Centre, Division of Gastroenterology, Hepatology and Nutrition, Boston Children’s Hospital, Boston, MA, USA

   Enju Liu, Chris Sudfeld & Christopher P. Duggan

5. Division of Gastroenterology, Hepatology and Nutrition, Boston Children’s Hospital, Boston, MA, USA

   Christopher P. Duggan

6. Harvard T.H. Chan School of Public Health, Boston, USA

   Chris Sudfeld & Christopher P. Duggan

7. The World Health Organization, Geneva, Switzerland

   Jon Simon & Per Ashorn

Contributions

RRK wrote the main manuscript text, EL did the statistical analysis and prepared the tables, EL, CRS interpreted the data . All authors made substantial contribution to the conception of this work and critically reviewed the manuscript.

Corresponding author

Correspondence to Rodrick Kisenge.

Ethics approval and consent to participate

All caregivers provided written informed consent for participation in the trials.

The protocol for the was approved by the WHO Ethics Review Committee, the Muhimbili University of Health and Allied Science Committee of Research and Publications, the Tanzania Food and Drug Authority, the Tanzanian National Institute of Medical Research, the institutional review board of Boston Children’s Hospital and the institutional ethics committee of Subharti Medical College and Hospital, Meerut, India.

Consent for publication

Not applicable.

Competing interests

The authors declare no competing interests.

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