Data source

Data from the 2016 Nepal Demographic and Health Survey (NDHS) was extracted for this study. The 2016 NDHS was executed under the flagship of the United States Agency for International Development (USAID). The DHS program, which is usually undertaken every 5 years, aids in gathering key demographic and health-related information in many developing nations. Interviews of Demographic and Health Surveys (DHS) occur in households with women of reproductive age (WRA) (15–49 years) and their children born in the 5 years before the survey. In the 2016 NDHS, a two-stage sample strategy was used in rural regions, and a three-stage sampling approach was used in urban areas. At first, stratified random sampling was employed to select 383 clusters across the country based on the population proportional to size method. Secondly, thirty households were randomly selected from each cluster using equal probability systematic sampling. Further information about the survey can be obtained from the respective reports⁽¹⁹⁾.

The information of 2061 live children aged 6–59 months whose mothers were not pregnant and had their body mass index (BMI) measured at the time of the interview was extracted for this study. The data consisted of information regarding children's household characteristics, maternal characteristics, nutritional status, illness status and birth characteristics. After removing missing data (n= 66) on children's stunting and wasting status, 1995 samples were considered for the final analysis.

Study outcomes

Two binary variables indicating children's nutritional status, stunting and wasting were used as the primary outcomes in this study. These variables were obtained from height and weight measurements of children aged 6–59 months. Stunting relates to low height-for-age measuring linear growth retardation and cumulative growth deficits. It was calculated with binary coding: 1 if the z-score of height-for-age below −2 standard deviations from the World Health Organization Child Growth Standards median, and 0 otherwise. On the other hand, wasting refers to low weight-for-height, indicating failure to receive adequate nutrition. Wasting was coded as 1 for the z-score of height-for-age below −2 standard deviations from the median of the World Health Organization Child Growth Standards and 0 otherwise. Malnourished, stunted or wasted children were coded 1 and 0 otherwise⁽²⁰⁾.

Explanatory variables

Explanatory variables were grouped under household characteristics, maternal characteristics, child characteristics related to infection and illnesses, and their feeding practices. The variables were further categorised as categorical, continuous or spatial. Continuous variables included the mother's age in completed years and the child's age in completed months. Mother's place of residence was categorised as urban and rural. Households having either flush or pour-flush toilets to a piped water system, septic tank or pit latrine, ventilated improved pit latrine, pit latrine with a slab or composting toilet, and do not share this facility with other households were categorised into improved toilet facilities. The wealth of households was divided into five ordinal groups ranging from poorest to richest. The wealth score was calculated using principal component analysis and the types of consumer items owned by the households, along with housing characteristics^{(Reference Rutstein and Johnson21)}. The number of household members was divided into two categories: those with five or fewer family members and those with five or more. Household food insecurity was assessed using the nine questions from the Household Food Insecurity Access Scale. Based on the responses, the food insecurity status of households was classified into four groups: secure, mildly insecure, moderately insecure and severely insecure^{(Reference Coates, Swindale and Bilinsky22)}. Mother's education status includes no education, primary, secondary and higher education. The mother's working status was classified as yes or no, depending on her working status in the 12 months before the survey. The current breastfeeding status was used as a dichotomous variable (0/1). Mother's BMI was calculated using two anthropometric indices, height and weight, measured by standardised scales. Four categories of BMI were included: underweight (<18⋅5 kg/m²), normal (18⋅5–23⋅0 kg/m²), overweight (23⋅0–27⋅5 kg/m²) and obesity (>27⋅5 kg/m²)^{(Reference Mamun and Finlay23)}. Mothers were asked whether children experienced fever and/or cough in the past 2 weeks preceding the survey. The responses were recorded as yes or no. Three groups of child's size at birth (large, average and small) were extracted from a written child health record or reported by the mother. Similarly, the birth orders of a child were categorised as the first, second or third, and fourth or higher. The district of mother's residence was used to explore the spatial variation of child malnutrition⁽¹⁹⁾. The rest of the study variables were considered categorical and analysed together with the continuous and spatial variables to assess possible effects on the malnutrition status of children. All the categorical explanatory variables are listed in Table 1 with their frequency distributions.

Table 1. Distribution of nutritional status of children under different study variables and their association through P-value

Statistical analysis

We employed a bivariate probit distribution regression model^{(Reference Adebayo and Gayawan17,Reference Gayawan and Fadiji24)} to jointly fit the binary variables – stunting and wasting, accounting for their correlation and estimating their association with the considered covariates. Let, for an ith child, Y _i1 and Y _i2 denote stunting and wasting as binary response variables, and $Y_{i1}^{\rm \ast }$ and $Y_{i2}^{\rm \ast }$ refer to corresponding latent variables, defined such that, for j  = 1,2

$$Y_{ij} = \left\{{\matrix{ {1, \;} \hfill & {Y_{ij}^{\rm \ast } > 0, \;} \hfill \cr {0, \;} \hfill & {\;{\rm otherwise}.} \hfill \cr } } \right.$$

In other words, a child is considered stunted or wasted if the values of the corresponding latent variables are positive. Furthermore, let (Y _i1, Y _i2)^′ denote a vector of the two correlated binary response variables. The bivariate probit distribution of (Y _i1, Y _i2)^′ conditional on the considered covariates can be perceived from the joint distribution of the latent variables $( {Y_{i1}^{\rm \ast } , \;{\rm \;}Y_{i2}^{\rm \ast } } ) ^{\prime}$.

For the ease of refering the terms ahead, subscript i has been deleted from the notations. Let X denote the vector of categorical covariates, u, continuous covariates, w, and spatial covariates, s, under study such that X = (u, w, s)^′. The latent variables $( {Y_{1}^{\rm \ast } , \;{\rm \;}Y_{2}^{\rm \ast } } ) ^{\prime}$, conditional on X, are assumed to jointly follow a bivariate normal distribution, i.e., $( {Y_{1}^{\rm \ast } , \;{\rm \;}Y_{2}^{\rm \ast } } ) ^{\prime}\vert X\sim N( {\mu , \;{\rm \Sigma }} )$. The term μ = (μ ₁, μ ₂)^′ is a vector of means of latent variables $Y_{1}^{\rm \ast }$ and $Y_{2}^{\rm \ast }$ for stunting and wasting, respectively; and ${\rm \Sigma } = \left[{\matrix{ {\sigma_1^2 } & {{\rm \;}\rho \sigma_1\sigma_2} \cr {{\rm \;}\rho \sigma_1\sigma_2} & {\sigma_2^2 } \cr } } \right]$ is the covariance matrix. The term ρ is the correlation coefficient between the latent variables; whereas the variances $\sigma _1^2$ and $\sigma _2^2 {\rm \;}$of $Y_{1}^{\rm \ast }$ and $Y_{2}^{\rm \ast }$, respectively, are assumed as 1 in diagonal places of Σ to enable identifiability.

We consider the distributional probit model of Klein et al. ^{(Reference Klein, Kneib and Lang25)}, which allows capturing the effects of covariates on all the model parameters. Let a vector of the parameters μ ₁, μ ₂ and ρ be denoted by θ = (θ ₁ = μ ₁, θ ₂ = μ ₂, θ ₃ = ρ). Following the framework of structured additive distribution regression of Klein et al. ^{(Reference Klein, Kneib and Lang25)}, the parameter θ _k can be associated with the covariates through geoadditive predictors $\eta ^{\theta _k}$ through appropriate link functions ensuring the restrictions on the parameter space such that $\theta _k = h_k^{\theta _k} {\rm \;}( {\eta^{\theta_k} } )$^{(Reference Klein, Kneib and Lang25)}.

The link function $h_k^{\theta _k}$ in the case of mean parameters μ ₁ and μ ₂ are assumed as identity, whereas to the model correlation coefficient, ρ, Fisher z-transformation is considered. The predictor,${\rm \;}\eta^{\theta _k}$, linked to the kth parameter can be written in a matrix form as, $\eta^{\theta _k} = \sum\nolimits_j^{J_k} {Z_j^{\theta _k} \beta _j^{\theta _k} }$, where $Z_j^{\theta _k}$ stands for design matrices found by basis function expansion. The terms $\beta _j^{\theta _k}$ are the vectors of regression coefficients that are assigned an improper Gaussian prior, as

$$\beta _j^{\theta _k} {\rm \;}\sim \left({\displaystyle{1 \over {\tau_j^{\theta_k} }}} \right)^{{\rm rank}( {K_j^{\theta_k} } ) }{\rm exp}\left({-\displaystyle{1 \over {2{( \tau_j^{\theta_k} ) }^2}}{( {\beta_j^{\theta_k} } ) }^{\prime}K_j^{\theta_k} \beta_j^{\theta_k} } \right), \;\eqno \;$$

where the term $K_j^{\theta _k}$ refers to a prior precision matrix, and $( \tau _j^{\theta _k} ) ^2$ are variance parameters to control the smoothness of the prior and are assigned with inverse gamma hyperprior.

The predictor $\eta^{\theta _k}$ may be defined with the general form, $\eta^{\theta _k} = \sum\nolimits_{j = 1}^{J_k} {f_j^{\theta _k} ( X ) }$, where the functions $f_j^{\theta _k} ( X ) ,$ ${\rm \;}j = 1, \;2, \;\ldots , \;J_k, \;{\rm \;}$ refer to different effects of different covariates. For example, $f_j^{\theta _k} ( X ) = {u}^{\prime}\beta ^{\theta _k}$ relate to linear effects of vector of categorical covariates u with linear effect parameters $\beta ^{\theta _k}.$ In this linear case, the design matrix $Z_j^{\theta _k}$ simply be the vector u. Similarly, smooth functions $f_j^{\theta _k} ( X ) = {\rm \;}f_j^{\theta _k} ( {w} )$ stand for non-linear effects of continuous covariate vectors w. Furthermore, the function $f_j^{\theta _k} ( X ) = {\rm \;}f_j^{\theta _k} ( {s} )$ accounts for spatial effects for discrete spatial units, s.

The linear effect parameters were assumed with a flat non-informative prior, i.e., $P( {\beta^{\theta_k}} ) \propto {\rm constant}.$ For the non-linear smooth functions $f_j^{\theta _k} ( {w_i} ) , \;$ Bayesian P-spline priors^{(Reference Lang and Brezger26)} were considered with the design matrix $Z_j^{\theta _k}$ comprising of D B-spline basis functions found from piecewise polynomials defined on equidistant grid of knots. According to the literature, we employed cubic B-splines based on twenty equidistant knots, which provide sufficient flexibility to capture complex non-linearity. We considered a second-order random walk prior over the basis coefficients and an inverse gamma hyperprior over the variance parameters of the prior^{(Reference Brezger and Lang27)}. Furthermore, a Gaussian Markov random field (GMRF) prior^{(Reference Rue and Held28)} was utilised to model spatial effects, $f_j^{\theta _k} ( s ) , \;$ where s are discrete spatial locations on a geographical map. In case of spatial effects, the design matrix $Z_j^{\theta _k} = Z_j^{\theta _k} [ {i, \;s} ]$ are indicator functions with value 1 if the ith observation relates to the location s, or with values 0 otherwise. Thus, the spatial effects $f_j^{\theta _k} ( s ) {\rm \;}$ are considered as equal to the spatial coefficients $\beta _j^{\theta _k}$. GMRF considers adjacent spatial locations as neighbours if they share a common boundary and thus are correlated. Assuming N(s) as the vector of neighbours of location, s, the conditional distribution of $\beta _j^{\theta _k} = f_j^{\theta _k} ( s )$ given the spatial effects at locations other than s is Gaussian with mean parameter as the average of spatial effects of all neighbours of s, and variance proportional to number of neighbours of s, |N(s)|. That is, a GMRF prior over $\beta _j^{\theta _k}$ is defined as

$$\beta _j^{\theta _k} ( s ) \vert \beta _j^{\theta _k} ( r ) , \;{\rm \;}r\ne s{\rm \;}\sim {\rm \;}N\left({\displaystyle{1 \over {\vert {N( s ) } \vert }}\mathop \sum \limits_{r\epsilon N( s ) } \beta_j^{\theta_k} ( r ) , \;{\rm \;}\displaystyle{{{( {\tau_j^{\theta_k} } ) }^2} \over {\vert {N( s ) } \vert }}{\rm \;}} \right){\rm \;, \;}$$

where the smoothness parameter $( {\tau_j^{\theta_k} } ) ^2$ was assumed to follow inverse gamma hyperprior. More details of the Bayesian structured additive models can be found in the literature^{(Reference Belitz, Brezger and Klein29)}.

The Bayesian estimation of the parameters of the above-mentioned bivariate probit distributional model was achieved via the Metropolis-Hastings algorithm of Markov Chain Monte Carlo (MCMC) techniques, based on iteratively weighted least square (IWLS) as proposed by Klein et al. ^{(Reference Klein, Kneib and Lang25)}. A multicollinearity check was performed between the linear covariates through the variance inflation factor (VIF), however, no multicollinearity issue was found among the covariates as the VIF values obtained were all less than 2⋅5. The analysis was executed using openly available software for inference in structured additive models, BayesX^{(Reference Belitz, Brezger and Klein29)} using R-package BayesXSrc^{(Reference Belitz, Brezger and Kneib30)}. For all associations, P-values less than 0⋅05 were considered statistically significant.