Factors associated with concurrent wasting and stunting among children 6–59 months in Karamoja, Uganda

listen audio

Study Justification:
The study aimed to investigate the factors associated with concurrent wasting and stunting (WaSt) among children 6–59 months in Karamoja, Uganda. This is important because children with WaSt and severe wasting have a similar risk of death. Understanding the correlates of WaSt can help inform prevention strategies and improve child health outcomes.
Study Highlights:
– The study analyzed data from the June 2015 to July 2018 Food Security and Nutrition Assessment in Karamoja, Uganda.
– A total of 33,054 children aged 6–59 months were included in the analysis.
– The study found that being male, aged 12–23 months, and having episodes of acute respiratory infection, diarrhea, and malaria/fever were associated with WaSt.
– Maternal underweight, short stature, low mid-upper arm circumference, and having ≥4 live-births were also associated with WaSt.
– WaSt was prevalent in households without livestock.
– The study recommended pragmatic and joint approaches to prevent the occurrence of WaSt.
– Future prospective studies on risk factors of WaSt were recommended to inform effective prevention strategies.
Recommendations for Lay Readers:
1. Pragmatic and joint approaches should be implemented to prevent concurrent wasting and stunting (WaSt) among children in Karamoja, Uganda.
2. It is important to address factors such as male gender, age between 12-23 months, and episodes of acute respiratory infection, diarrhea, and malaria/fever to reduce the risk of WaSt.
3. Maternal underweight, short stature, low mid-upper arm circumference, and having ≥4 live-births are also associated with WaSt and should be addressed.
4. Livestock ownership in households may play a role in preventing WaSt.
5. Further research is needed to better understand the risk factors of WaSt and develop effective prevention strategies.
Recommendations for Policy Makers:
1. Implement pragmatic and joint approaches, involving multiple stakeholders, to prevent concurrent wasting and stunting (WaSt) among children in Karamoja, Uganda.
2. Allocate resources and develop interventions targeting factors associated with WaSt, such as male gender, age between 12-23 months, and episodes of acute respiratory infection, diarrhea, and malaria/fever.
3. Address maternal underweight, short stature, low mid-upper arm circumference, and high parity (having ≥4 live-births) through targeted interventions and support.
4. Consider the role of livestock ownership in households and its potential impact on preventing WaSt.
5. Support and fund future prospective studies to further investigate the risk factors of WaSt and inform evidence-based prevention strategies.
Key Role Players:
1. Makerere University School of Public Health
2. International Baby Food Action Network (IBFAN), Uganda
3. United Nations (UN) Children’s Fund (UNICEF)
4. UN Food and Agriculture Organization (FAO)
5. UN World Food Programme (WFP)
6. Department of Risk Reduction at the Office of the Prime Minister, Uganda
7. Ministry of Health, Uganda
Cost Items for Planning Recommendations:
1. Resource allocation for pragmatic and joint approaches to prevent WaSt
2. Funding for interventions targeting factors associated with WaSt
3. Support for maternal health programs addressing underweight, short stature, and low mid-upper arm circumference
4. Investment in livestock ownership programs and support for households without livestock
5. Funding for future prospective studies on risk factors of WaSt and prevention strategies

The strength of evidence for this abstract is 8 out of 10.
The evidence in the abstract is strong because it is based on a large sample size (33,054 children) and utilizes multivariate mixed-effect logistic regression analysis. The study also includes a comprehensive assessment of various factors associated with concurrent wasting and stunting (WaSt) in children. To improve the evidence, it would be beneficial to include information on the representativeness of the sample and the generalizability of the findings to other populations. Additionally, providing more details on the methodology and data collection procedures would enhance the transparency and replicability of the study.

Children with concurrent wasting and stunting (WaSt) and children with severe wasting have a similar risk of death. Existing evidence shows that wasting and stunting share similar causal pathways, but evidence on correlates of WaSt remains limited. Research on correlates of WaSt is needed to inform prevention strategies. We investigated the factors associated with WaSt in children 6–59 months in Karamoja Region, Uganda. We examined data for 33,054 children aged 6–59 months using June 2015 to July 2018 Food Security and Nutrition Assessment in Karamoja. We defined WaSt as being concurrently wasted (weight-for-height z-scores <−2.0) and stunted (height-for-age z-score <−2.0). We conducted multivariate mixed-effect logistic regression to assess factors associated with WaSt. Statistical significance was set at p < 0.05. In multivariate analysis, being male (adjusted odds ratio [aOR] = 1.79; 95% confidence interval [CI] [1.60–2.00]), aged 12–23 months (aOR = 2.25; 95% CI [1.85–2.74]), 36–47 months (aOR = 0.65; 95% CI [0.50–0.84]) and 48–59 months (aOR = 0.71; 95% CI [0.54–0.93]) were associated with WaSt. In addition, acute respiratory infection (aOR = 1.30; 95% CI [1.15–1.48]), diarrhoea (aOR = 1.25; 95% CI [1.06–1.48]) and malaria/fever (aOR = 0.83; 95% CI [0.73–0.96]) episodes were associated with WaSt. WaSt was significantly associated with maternal underweight (body mass index <18.5 kg/m2), short stature (height <160 cm), low mid-upper arm circumference (MUAC <23 cm) and having ≥4 live-births. WaSt was prevalent in households without livestock (aOR = 1.30; 95% CI [1.13–1.59]). Preventing the occurrence of WaSt through pragmatic and joint approaches are recommended. Future prospective studies on risk factors of WaSt to inform effective prevention strategies are recommended.

We conducted secondary data analysis of the June 2015 to July 2018 Food Security and Nutrition Assessment (FSNA) cross‐sectional survey datasets conducted in all the seven districts of the Karamoja Region in North‐Eastern Uganda. Data was pooled from seven FSNA datasets for the current study. These datasets have been described in detail elsewhere (Odei Obeng‐Amoako, Myatt, et al., 2020). The FSNA surveys were carried out by the Makerere University School of Public Health and the International Baby Food Action Network (IBFAN), Uganda, in collaboration with the United Nations (UN) Children's Fund (UNICEF), the UN Food and Agriculture Organization (FAO), the UN World Food Programme (WFP), the Department of Risk Reduction at the Office of the Prime Minister and the Ministry of Health, Uganda. The FSNA protocol adapted the Standardized Monitoring and Assessment of Relief and Transitions (SMART) survey methodology (Golden et al., 2006). The FSNA employed a two‐stage cluster sampling approach. First, a probability proportional to size sampling procedure was used to select clusters from a list of parishes in each district. Secondly, households in each of the clusters were selected by systematic random sampling technique (UNICEF, Department for International Development [DFID], WFP, FAO, & IBFAN, 2018). The estimated number of children and households were selected from each of the clusters per the FSNA protocol (UNICEF, DFID, WFP, FAO, & IBFAN, 2018). FSNA adapted a standardized semistructured questionnaire for data collection by trained research assistants. The FSNA questionnaire consists of household characteristics, food security and nutrition modules. The household and food security modules were administered to household heads or adults present at the time of the interview while the mothers or caregivers (hereinafter referred as caregivers) of children under 5 years were interviewed using the nutrition module. Weight and height measurements were collected from nonpregnant women with children aged 0–59 months in the household. Mid‐upper arm circumference (MUAC) was measured for both pregnant and nonpregnant women with children aged 0–59 months. Weight, height and MUAC measurements were collected from children aged 6–59 months found in the household. Recumbent length was measured for children <24 months old. Bilateral pitting oedema and haemoglobin levels among children aged 6–59 months were also examined. Child age in months was obtained from the child health cards or by maternal recall using a local event calendar. We defined wasted as weight for height z‐score (WHZ) <−2.0, stunted as height for age z‐score (HAZ) <−2.0, and underweight as weight for age z‐score (WAZ) <−2.0 based on z‐scores of the 2006 World Health Organization (WHO) growth standards (WHO, 2006). Degrees of anthropometric deficits were defined as no deficit as z‐scores ≥−2; moderate deficits as z‐scores <−2 and ≥−3 and severe deficits as <−3 z‐scores. We defined acute malnutrition as wasting (WHZ <−2) and/or MUAC <12.5 cm; severe acute malnutrition (SAM) as severe wasting (WHZ <−3) and/or MUAC <11.5 cm and moderate acute malnutrition (MAM) as moderate wasting (WHZ ≥−3 to −2) and/or MUAC ≥11.5 cm and ≤12.5 cm (United Nations High Commissioner for Refugees [UNHCR] & WFP, 2011). The outcome of our study was WaSt among children aged 6–59 months. We defined WaSt as concurrently having WHZ <−2 and HAZ 40 years (UBOS & ICF, 2018). Maternal educational level was described using the cumulative number of years of formal education attained. Educational level was categorized as no education, 1–7 years (primary) and ≥8 years (secondary and above). We also classified the number of live‐births of caregivers into 1–3, 4–6 and >7 number of live‐births. We categorized maternal body mass index (BMI) as normal (BMI = 18.5–24.9 kg/m2), underweight (BMI < 18.5 kg/m2), and overweight/obese (BMI ≥ 25 kg/m2) (UNHCR & WFP, 2011). Maternal height was categorized as tall (height ≥170 cm), moderately tall (height = 160–170 cm) and short (height <160 cm). Maternal MUAC signifying acute malnutrition was classified as low MUAC (MUAC 35 (acceptable) (INDDEX Project, 2018). We evaluated the presence of a latrine in a household as a probable factor associated with WaSt. Sources of drinking water were defined as improved water sources (piped/tap, protected well/spring and borehole fitted with a hand‐pump) and unimproved water sources (surface water, river, dam, runoff, rainwater collected in a tank and water from open well/spring) (WHO & UNICEF, 2006). The association between food security seasons and the occurrence of WaSt was also examined. FSNA surveys were conducted in May/June for the lean (hunger or preharvest) and in November/December for the nonlean (postharvest) seasons. Children aged 6–59 months were included in the analysis. We used WHO flags for outliers; HAZ 6, WAZ 5, and WHZ 5 were excluded as biologically implausible z‐scores values (WHO, 2009). Given that WaSt was the outcome variable, children with incomplete data on WHZ or HAZ or both were excluded from the study. Children with bilateral pitting oedema, height 120 cm and MUAC >20 cm were also excluded from the dataset (MoH Uganda & UNICEF, 2016). The maternal MUAC measurements which were out of range of upper quartile +3.0× interquartile range (IQR) and lower quartile −3.0× IQR were censored as outliers (Healy, Chambers, Cleveland, Kleiner, & Tukey, 1984). All statistical analyses were conducted using STATA 13.0. We also analysed anthropometric z‐scores per WHO growth standards in STATA (Leroy, 2011). We used descriptive statistics to summarize continuous variables using medians and IQRs and categorical variables using percentages. We used multivariate mixed‐effect logistic regression to assess child level, maternal and household level, socioeconomic and seasons factors associated with WaSt. Mixed‐effect logistic regression method adjusted for the clustering effect of the multistage sampling design used in the FSNA survey. In the multivariate analysis we only included explanatory variables with p 10). In the multivariate analysis, we used a backward stepwise method to remove the nonsignificant variables (p > 0.05). To identify variables with interaction effects in the model, we assessed the significance (p > 0.05) of each interaction term one at a time in the basic model, but none of the interaction terms was conceptually meaningful. We found no confounding factors in our model after testing for a ≥10% change in the effect measure in the presence of another variable. We retained maternal stature and season of the survey in the final model although they were dropped during the backward stepwise process based on literature (Black et al., 2013; Harding et al., 2018). Akaike information criterion (AIC) and Bayesian information criterion (BIC) methods were used to assess for the goodness of fit of our model. Factors associated with WaSt were reported by adjusted odds ratio (aOR) at 95% confidence interval (CI). We set statistical significance at p < 0.05 in this analysis.

N/A

Based on the information provided, here are some potential innovations that could improve access to maternal health:

1. Mobile Health (mHealth) Applications: Develop mobile applications that provide information and resources on maternal health, including prenatal care, nutrition, and postnatal care. These apps can also provide reminders for appointments and medication, as well as connect women with healthcare providers through telemedicine.

2. Community Health Workers: Train and deploy community health workers who can provide education and support to pregnant women and new mothers in remote areas. These workers can conduct home visits, provide basic healthcare services, and refer women to appropriate healthcare facilities when necessary.

3. Telemedicine: Establish telemedicine services that allow pregnant women and new mothers to consult with healthcare providers remotely. This can help overcome geographical barriers and improve access to specialized care, especially in areas with limited healthcare facilities.

4. Maternal Health Vouchers: Implement voucher programs that provide financial assistance to pregnant women and new mothers, enabling them to access essential maternal health services, such as prenatal care, skilled birth attendance, and postnatal care.

5. Mobile Clinics: Set up mobile clinics that travel to remote areas, providing comprehensive maternal health services, including prenatal care, screenings, vaccinations, and family planning. These clinics can also offer health education and distribute essential supplies.

6. Maternal Health Education Programs: Develop and implement community-based education programs that focus on maternal health, covering topics such as nutrition, hygiene, breastfeeding, and family planning. These programs can be delivered through workshops, support groups, and mass media campaigns.

7. Improved Transportation Infrastructure: Invest in improving transportation infrastructure, such as roads and transportation networks, to ensure that pregnant women can easily access healthcare facilities, especially in rural and remote areas.

8. Maternal Health Monitoring Systems: Implement digital health systems that track and monitor maternal health indicators, such as antenatal visits, immunizations, and birth outcomes. These systems can help identify gaps in care and enable targeted interventions.

9. Maternal Health Financing: Develop innovative financing mechanisms, such as microinsurance or community-based health financing schemes, to make maternal health services more affordable and accessible to women in low-income communities.

10. Partnerships and Collaboration: Foster partnerships between government agencies, healthcare providers, non-governmental organizations, and community-based organizations to collectively address the barriers to maternal health access and develop sustainable solutions.

It is important to note that the specific context and needs of the Karamoja Region in Uganda should be taken into consideration when implementing these innovations.
AI Innovations Description
The research conducted in Karamoja, Uganda identified several factors associated with concurrent wasting and stunting (WaSt) in children aged 6-59 months. These factors include:

1. Child factors: Being male, aged 12-23 months, and aged 36-47 months were associated with WaSt. This suggests that younger children, particularly males, are at higher risk of WaSt.

2. Morbidity: Acute respiratory infection, diarrhea, and malaria/fever episodes were associated with WaSt. This highlights the importance of addressing and preventing these common childhood illnesses to reduce the risk of WaSt.

3. Maternal factors: Maternal underweight (body mass index
AI Innovations Methodology
The study you provided focuses on identifying factors associated with concurrent wasting and stunting (WaSt) among children 6-59 months in Karamoja, Uganda. The methodology used in the study includes secondary data analysis of the June 2015 to July 2018 Food Security and Nutrition Assessment (FSNA) cross-sectional survey datasets conducted in the Karamoja Region. The datasets were collected using a two-stage cluster sampling approach, with households selected through systematic random sampling. A standardized semistructured questionnaire was used to collect data on household characteristics, food security, and nutrition. Anthropometric measurements, morbidity information, and socioeconomic factors were also collected.

To analyze the data, multivariate mixed-effect logistic regression was conducted to assess the factors associated with WaSt. The analysis included child-level factors (age, sex, morbidity), maternal-level factors (age, education, nutritional status), household characteristics (head’s sex, education, wealth index, livestock ownership, land access), and markers of food security seasons. The statistical significance was set at p < 0.05.

The results of the analysis showed several factors associated with WaSt. These included being male, aged 12-23 months, and having acute respiratory infection, diarrhea, or malaria/fever episodes. Maternal underweight, short stature, low mid-upper arm circumference, and having four or more live births were also associated with WaSt. Additionally, households without livestock were more likely to have WaSt.

To simulate the impact of recommendations on improving access to maternal health, a methodology could involve conducting prospective studies to identify risk factors for WaSt and inform effective prevention strategies. This would involve collecting data on various factors such as maternal health, nutrition, and socioeconomic status, and analyzing their association with WaSt. The impact of interventions or recommendations could then be assessed by comparing the prevalence of WaSt before and after the implementation of these strategies. Statistical methods such as logistic regression or other appropriate models could be used to analyze the data and determine the effectiveness of the recommendations in improving access to maternal health.

Partilhar isto:
Facebook
Twitter
LinkedIn
WhatsApp
Email