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Erschienen in: BMC Public Health 1/2020

Open Access 01.12.2020 | Research article

Inequality in child undernutrition among urban population in India: a decomposition analysis

verfasst von: S. K. Singh, Shobhit Srivastava, Shekhar Chauhan

Erschienen in: BMC Public Health | Ausgabe 1/2020

Abstract

Background

With increasing urbanization in India, child growth among urban poor has emerged as a paramount public health concern amidst the continuously growing slum population and deteriorating quality of life. This study analyses child undernutrition among urban poor and non-poor and decomposes the contribution of various factors influencing socio-economic inequality. This paper uses data from two recent rounds of National Family Health Survey (NFHS-3&4) conducted during 2005–06 and 2015–16.

Methods

The concentration index (CI) and the concentration curve (CC) measure socio-economic inequality in child growth in terms of stunting, wasting, and underweight. Wagstaff decomposition further analyses key contributors in CI by segregating significant covariates into five groups-mother’s factor, health-seeking factors, environmental factors, child factors, and socio-economic factors.

Results

The prevalence of child undernutrition was more pronounced among children from poor socio-economic strata. The concentration index decreased for stunting (− 0.186 to − 0.156), underweight (− 0.213 to − 0.162) and wasting (− 0.116 to − 0.045) from 2005 to 06 to 2015–16 respectively. The steepness in growth was more among urban poor than among urban non-poor in every age interval. Maternal education contributed about 19%, 29%, and 33% to the inequality in stunting, underweight and wasting, respectively during 2005–06. During 2005–06 as well as 2015–16, maternal factors (specifically mother’s education) were the highest contributory factors in explaining rich-poor inequality in stunting as well as underweight. More than 85% of the economic inequality in stunting, underweight, and wasting among urban children were explained by maternal factors, environmental factors, and health-seeking factors.

Conclusion

All the nutrition-specific and nutrition-sensitive interventions in urban areas should be prioritized, focusing on urban poor, who are often clustered in low-income slums. Rich-poor inequality in child growth calls out for integration and convergence of nutrition interventions with policy interventions aimed at poverty reduction. There is also a need to expand the scope of the Integrated Child Development Services (ICDS) program to provide mass education regarding nutrition and health by making provisions of home visits of workers primarily focusing on pregnant and lactating mothers.
Hinweise

Supplementary Information

The online version contains supplementary material available at https://​doi.​org/​10.​1186/​s12889-020-09864-2.

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Abkürzungen
ANC
Ante Natal Care
BCG
Bacillus Calmette-Guerin
CC
Concentration Curve
CI
Concentration Index
DPT
Diphtheria, Pertussis, and Tetanus
GHI
Global Hunger Index
HAZ
Height-for-Age Z score
ICDS
Integrated Child Development Services
IEC
Information, Education, and Communication
IFA
Iron Folic Acid
IIPS
International Institute for Population Sciences
NCHS
National Centre for Health Statistics
NFHS
National Family Health Survey
ODF
Open Defecation Free
SC
Schedule Caste
ST
Schedule Tribe
UNICEF
United Nations International Children’s Emergency Fund
WAZ
Weight-for-Age Z score
WHO
World Health Organization
WHZ
Weight-for-Height Z score
Se
Standard error
SD
Standard deviation

Background

The rapid increase in the urban population due to urbanization in the last one decade has contributed to the urban poverty in India [47]. It is manifested in the form of inadequate provision of housing and shelter, water, sanitation, health, education, social security, livelihoods, and food security along with the special needs of vulnerable groups like women, and children [13]. The health of urban children as measured with malnutrition in the existing context of urbanization, has become an important issue in India [26]. Malnutrition among children under age five is a paramount public health concern in many developing countries, and India is no exception [33].
Child under-nutrition is expressed in different forms, including stunting (− > 2 SD length/weight for age), wasting (− > 2 SD weight for length/height), and underweight (− > 2 SD weight for age) [43]. In developing countries, an estimated 32% of children under five were stunted, 3.5% were severely wasted, and 20.2% were underweight [4]. The rate of stunting in India has declined from 48% to 38.4%, wasting has increased slightly from 19.8% to 21%, and underweight has decreased from 42.5% to 35.8% between the two time-periods of NFHS-3 and NFHS-4 [17]. Malnutrition in India is clustered in central, northern, and eastern regions [46]. In a study conducted in Indian settings, it was found that the spatial clustering of malnutrition was visible in those geographical pockets where poverty was high, women’s education was low, and BMI level among women was below average [22].
Malnutrition is primarily caused due to the immediate causes (inadequate dietary intake, lack of care and onset of disease), and the underlying causes (an unhealthy environment and insufficient education) [9]. Studies in countries other than India had also raised the issue of child growth significantly. In a study, it was found that there was a substantial poor/rich gap in the nutritional status in the urban residence of Kenya [11]. Moreover, the same study argued that poor nutritional status in urban areas is attributed to poor environment and housing, poor access to drinking water, food, and health services. One of the studies found that the children belonging to poor households were undernourished not only because of poverty, but also due to limited use of maternal health care services and poor care resulting from the lower educational status of parents and poor health of mothers [5].
Despite high levels of stunting, wasting, and underweight among under-five children in India, studies related to measuring growth faltering as measured with z score are very limited [14]. Studies have found that growth in weight appeared to start right from birth, and there appeared a fall in WAZ score for the first 3 months, and after that, the rate of fall appeared to slow down [25]. The study was done to compare NFHS-1 and NFHS-3 data to provide a comparison for all India level growth among children aged 0–3 years [25]. Growth in infancy was associated with poorer educational outcomes in later childhood. However, these outcomes, when adjusted for confounding factors, suggested that childhood educational attainment was more strongly influenced by other socio-demographic factors, especially maternal education and the quality of the home environment [15, 42]. Similarly, it was found that early childhood stunting is associated with deficits in cognition and educational achievement in late adolescence [42].
India ranks 102 in the Global Hunger Index [12], shows the severity of under-nutrition existence in the country. Moreover, other studies too carved out the fact that the poverty nutrition trap does exist in India [19]. There exist lack of literature focusing on examining the socio-economic gap for malnutrition among children in urban India. Therefore, this paper aims to measure undernutrition among urban poor and non-poor children below age five in India. It also analyses the changes in socio-economic inequality in undernutrition among children in urban India from 2005 to 06 to 2015–16.

Methods

Data

The data used in this paper have been taken from two rounds of National Family Health Survey namely NFHS-3 (2005–06) and NFHS-4 (2015–16). The primary objective of the NFHS was to provide essential data on health and family welfare, as well as data on emerging issues including the nutritional status of children under age five at national, state, and district levels. Therefore, data from NFHS-4 (2015–16) was considered as a benchmark to examine the progress made by the country in various health indicators over time. Decisions about the overall sample size required for National Family Health Survey (2005–06 and 2015–16) were guided by several considerations, paramount among which was the need to produce indicators at the national levels, as well as separate estimates for urban and rural areas. The data is a nationally representative data which provide essential data on health and family welfare, as well as data on emerging issues in these areas. Additionally, National Family Health Survey is a part of Demographic and Health Surveys (DHS) which are nationally-representative household surveys that provide data for a wide range of monitoring and impact evaluation indicators in the areas of population, health, and nutrition. The findings of this study are based on a total of 15,241 urban children under 5 years in NFHS-3 and 53,483 urban children under five years in NFHS-4. The information related to child’s anthropometric measures covered measurements of height, weight and hemoglobin levels for children; Details about the NFHS-4 designs, tools, and protocols are presented in the national report of NFHS-4 [17], and all relevant information is available in the public domain on http://​rchiips.​org/​ NFHS.

Categorization of variables

Outcome variable

The three anthropometric indicators were used for children under five years: stunting (height for age < − 2 standard deviation (SD)), underweight (weight for age < − 2 SD), and wasting (height for age < − 2 SD). The measure used was recoded as per WHO standards [45].

Predictor variable

The study divided the predictors into five groups. 1) Maternal Factors 2) Socio-economic factors 3) Child-related factors 4) Environmental factors and 5) Health seeking factors. Maternal factors include age (15–24, 25–24 and 35+ years), Education (Illiterate and literate), age at first birth (< 18, 18–30, and > 30 years), Parity (1, 2, 3, 4+) and mother’s anaemia status (no and yes). Socio-economic factors include caste (SC/ST and non-SC/ST), religion (Hindu, Muslim, Christian, and Others) and Wealth status (Poorest, Poorer, Middle, Richer, and Richest). Child factors consist age (0–23, 24–47 months and 47–59 months), sex of the child (male and female), anemia status (no and yes), diarrhea, birth weight (normal and low birth weight (<2500grms), and colostrum feeding (yes and no). The environmental factors include the source of drinking water (protected and not protected), open defecation (opened and improved), stool disposal (yes and no), and geographical regions (North, Central, East, North-east, West, and South). Health seeking factors included the use of Skill Birth Attendants, Place of delivery (Home or any institution i.e., private/public hospital), full immunization includes children who received BCG (for tuberculosis), measles, and three doses each of DPT (diphtheria, whooping cough, and tetanus), and Polio. Full ANC is defined as women who had four or more ANC visits, had at least two tetanus injection, and consumed 100 IFA tablets/syrup for the most recent birth. Further, Colostrum feeding, defined as a child received breastfeeding within 1 h after delivery.
The variable of wealth status was created using the information given in the survey. Households were given scores based on the number and kinds of consumer goods they own, ranging from a television to a bicycle or car, and housing characteristics such as source of drinking water, toilet facilities, and flooring materials. These scores are derived using principal component analysis. National wealth quintiles are compiled by assigning the household score to each usual (de jure) household member, ranking each person in the household population by their score, and then dividing the distribution into five equal categories, each with 20% of the population. Further, wealth status of the household was recoded as poor and non-poor. To depict the poor and non-poor differentials, we clubbed first two wealth quintiles as poor (poorest and poorer) and next three quintiles as non-poor (middle, richer and richest).

Statistical analysis

Concentration index (CI)

The concentration curve is obtained by plotting the cumulative proportion of outcome variables (either stunting, underweight, or wasting) on y-axis against the increasing percentage of the population ranked by the socio-economic indicator (wealth index) on x-axis. The curves shows that whether the socio- economic status related inequality in the outcome variable (on x-axis) prevails or not. If the curve is above the line of equality (45 degree line) that means the index value is negative hence it shows that the outcome variable is disproportionally concentrated among the poor and vice-versa. Income-related inequality in stunting, underweight, and wasting was measured by the concentration index (CI) and the concentration curve (CC), using the wealth score as the socio-economic indicator and binary outcome as stunting, underweight, and wasting. The concentration index is defined as twice the area between the concentration curve and the line of equality. Concentration index measures the inequality of one variable (say stunting, underweight or wasting) over the distribution of another variable (wealth index). The index ranges from − 1 to + 1, where the index value of 0 (zero) shows no socio-economic inequality. However, positive value of index shows pro-rich inequality and vice-versa. Additional on the either scales higher the value, higher the extent of socio-economic inequality. The study used Wagstaff decomposition analysis to decompose the concentration index. Wagstaff’s decomposition demonstrated that the concentration index could be decomposed into the contributions of each factor to the income-related inequalities [41]. For any linear regression model on health outcome (y) (say stunting, underweight or wasting), such as.
$$ y=\alpha +{\sum}_k{\beta}_k{x}_k+\varepsilon $$
(1)
The concentration index for y, C, can be written as follows,
$$ C={\sum}_k\left({\beta}_k{\overline{x}}_k/\mu \right){C}_k+G{C}_{\varepsilon }/\mu $$
(2)
Where μ is the mean of y, \( {\overline{x}}_k \) is the mean of xk, Ck is the concentration index for xk (defined analogously to C), and GCε is the generalized concentration index for the error term (ε). Equation (2) shows that C is equal to a weighted sum of the concentration indices of the k regressors, where the weight for xk is the elasticity of y with respect to xk \( \left({\eta}_k={\beta}_k\frac{{\overline{x}}_k}{\mu}\right) \). The residual component captured by the last term reflects the socio-economic status related inequality in health that is not explained by systematic variation in the regressors by income, which should approach zero for a well-specified model. Each contribution is the product of elasticity with the degree of economic inequality. Moreover, the percentage contribution is obtained by dividing each absolute contribution by total absolute contribution multiplied by 100 to obtain the estimates.

Results

Table 1 shows the distribution of children under age five by selected background characteristics among urban poor and non-poor in India. It was found that significant health problems like anaemia and diarrhoea among under-five children were more prevalent among those from urban poor as compared to those from urban non-poor. On contrary, health-seeking behaviour was better practised by urban residents as compared to non-poor population.
Table 1
Percentage distribution of children under age five years by selected background characteristics among urban poor and non-poor in India, 2005–06 and 2015–16.
Variables
2005–06
2015–16
Non-poor
Poor
Non-poor
Poor
N
%
N
%
N
%
N
%
Age (years)
 15–24
4502
32.9
607
39.2
12,235
27.0
2843
34.6
 25–34
8099
59.2
756
48.8
28,657
63.3
4443
54.1
 35+
1092
8.0
185
12.0
4374
9.7
931
11.3
Education
 No
2711
19.8
1023
66.1
5357
11.8
3747
45.6
 Yes
10,982
80.2
525
33.9
39,909
88.2
4470
54.4
Age at First Birth (years)
 Less than 18
2210
16.1
626
40.44
3503
7.7
1561
19.0
 18–30
11,002
80.4
910
58.8
40,202
88.8
6520
79.4
 More than 30
481
3.5
12
0.78
1561
3.5
136
1.7
Parity
 1
3577
26.1
223
14.4
14,131
31.2
1506
18.3
 2
5334
39.0
344
22.2
18,883
41.7
2515
30.6
 3
2423
17.7
300
19.4
7620
16.8
1901
23.1
 4+
2359
17.2
681
44.0
4632
10.2
2295
27.9
Anemia
 No
7045
51.5
592
38.2
22,264
49.2
3312
40.3
 Yes
6648
48.6
956
61.8
23,002
50.8
4905
59.7
Socio-economic factors
Caste
 SC/ST
3406
24.9
565
36.5
12,103
26.7
3269
39.8
 Non-SC/ST
10,287
75.1
983
63.5
33,163
73.3
4948
60.2
Religion
 Hindu
9143
66.8
1013
65.4
29,762
65.8
5508
67.0
 Muslim
2714
19.8
413
26.7
10,077
22.3
2024
24.6
 Others
1836
13.4
122
7.9
5427
12.0
685
8.3
Child factors
Age (months)
 0–23
5115
37.4
576
37.2
17,199
38.0
3071
37.4
 24–47
5741
41.9
639
41.3
18,777
41.5
3399
41.4
 47–59
2837
20.7
333
21.5
9290
20.5
1747
21.3
Sex
 Male
7223
52.8
748
48.3
23,666
52.3
4221
51.4
 Female
6470
47.3
800
51.7
21,600
47.7
3996
48.6
Anemia
 No
7208
52.6
604
39.0
23,501
51.9
3719
45.3
 Yes
6485
47.4
944
61.0
21,765
48.1
4498
54.7
Diarrhea
 No
12,409
90.6
1396
90.2
41,256
91.1
7411
90.2
 Yes
1284
9.4
152
9.8
4010
8.9
806
9.8
Birth weight
 Normal
12,003
87.7
1462
94.4
38,744
85.6
7086
86.2
 LBW
1690
12.3
86
5.6
6522
14.4
1131
13.8
Colostrum feedinga
 No
8925
65.2
1136
73.4
30,234
66.8
5634
68.6
 Yes
4768
34.8
412
26.6
15,032
33.2
2583
31.4
Environmental factors
Source of drinking water
 Not Protected
1097
8.0
211
13.6
3889
8.6
965
11.7
 Protected
11,840
86.5
1259
81.3
39,039
86.2
6842
83.3
 Others
756
5.5
78
5.0
2338
5.2
410
5.0
Defecation
 Open defecation
1089
8.0
940
60.7
2725
6.0
4309
52.4
 Improved
11,790
86.1
511
33.0
40,065
88.5
3456
42.1
 Others
814
5.9
97
6.3
2476
5.5
452
5.5
Stool Disposal
 Yes
11,382
83.1
824
53.2
36,300
80.2
4235
51.5
 No
2308
16.9
724
46.8
8955
19.8
3982
48.5
Regions of India
 North
3029
22.1
315
20.4
10,054
22.2
910
11.1
 Central
2032
14.8
166
10.7
12,640
27.9
2632
32.0
 East
563
4.1
25
1.6
4634
10.2
2324
28.3
 North East
3023
22.1
361
23.3
5675
12.5
1165
14.2
 West
2823
20.6
496
32.0
4745
10.5
547
6.7
 South
2223
16.2
185
12.0
7518
16.6
639
7.8
Health seeking factors
Skilled birth attendanta
 No
2987
21.8
986
63.7
3950
8.7
2148
26.1
 Yes
10,706
78.2
562
36.3
41,316
91.3
6069
73.9
Place of deliverya
 Home
3757
27.4
1084
70.0
4629
10.2
2428
29.6
 Institution
9936
72.6
464
30.0
40,637
89.8
5789
70.5
Full Immunization
 No
5643
41.2
1088
70.3
15,158
33.5
3713
45.2
 Yes
8050
58.8
460
29.7
30,108
66.5
4504
54.8
Full ANCa
 No
11,303
82.6
1494
96.5
35,184
77.7
7501
91.3
 Yes
2378
17.4
54
3.5
10,082
22.3
716
8.7
SC/ST Scheduled Caste/Scheduled Tribe; ANC Ante-Natal Care
aestimates only for last birth; N: Sample; % Percentage
Figure 1 portrays the prevalence of child growth as measured through stunting, wasting, and underweight among urban poor and non-poor in India, during 2005–06 and 2015–16. It is evident from the results that three key indicators of growth among children under age five, namely stunting, underweight, and wasting were higher among urban poor children than among urban non-poor children for both the time-periods. Further, results show that the prevalence of stunting and underweight has declined among urban poor as well as non-poor children during the last one decade, i.e., from 2005 to 06 to 2015–16. However, the prevalence of wasting has increased, from 2005 to 06 to 2015–16, among urban poor as well as urban non-poor children, which may be primarily due to seasonal variation in the month of surveys. By and large, a similar result has been found in case of growth for poor and non-poor children in urban India during 2005–06 and 2015–16. The result found that the average growth is higher among urban poor than in urban non-poor for each classification of child anthropometry measures (Figure-S1; Supplementary file). For standard error, please refer supplementary Table S1and S2.
Table 2 presents the average growth among children as measured through z scores for HAZ, WHZ, and WAZ by segregating them into different age groups. Mean WAZ, HAZ and WHZ scores for children under 5 months were (− 0.95, − 1.54, − 1.11), and (− 0.36,-1.05, − 1.00) in 2005–06; and (− 0.86, − 1.49, − 1.09), and (− 0.33, − 1.18, − 1.25) in 2015–16 for urban poor and non-poor respectively. Significant differences in z score in poor as well as non-poor children were visible from the first 5 months itself. Of the total growth differential as measured with z score for height-for-age (HAZ) at 59 months among urban poor and non-poor in 2005–06 (− 2.51 and − 1.59), 38% (− 0.95) and 22% (− 0.36) of growth took place at first 5 months after birth; whereas, in 2015–16, the distribution increased to 41% (− 0.86) and 25% (− 0.33) respectively. Similarly, of the average growth in weight-for-age (WAZ) at 59 months among urban poor and non-poor in 2005–06 (− 2.18 and − 1.54), 71% (− 1.54) and 68% (− 1.05) of growth took place at first 5 months after birth; whereas, in 2015–16, the distribution was 41% (− 0.86) and 25% (− 0.33) respectively. For weight-for-height (WHZ) at 59 months among urban poor and non-poor in 2005–06 (− 0.99 and − 0.88), 112% (− 1.11) and 113% (− 1.00) of growth took place at first 5 months after birth; whereas in 2015–16, the distribution was 99% (− 1.09) and 131% (− 1.25) respectively. Growth for HAZ among children was found to be highest at age 21–25 months among urban poor, and at age 46–50 months among urban non-poor during 2005–06, whereas, growth in stunting was highest at age 21–25 months among urban poor and non-poor during 2015–16. It leads to the premise that the children were more susceptible to be stunted during the age of 21–25 months. Z score for WAZ among children was found to be highest at age 31–35 months among urban poor and at age 56–59 months among urban non-poor during 2005–06, whereas, z score for underweight was highest at age 21–25 months among urban poor and at age 56–59 months among urban non-poor during 2015–16. It means that urban non-poor children aged 56–59 months were more prone to be underweight. The z scores for WHZ among children was found to be highest at age 6–10 months among urban poor and at age 0–5 months among urban non-poor during 2005–06, whereas, z score for wasting was highest at age 6–10 months among urban poor and at age 0–5 months among urban non-poor during 2015–16. It means that children in their early months were more prone to be wasted.
Table 2
Mean height for age z (HAZ), weight for age z (WAZ), and weight for height z (WHZ) scores among children under five years in urban India, 2005–06 and 2015–16
Age (in Months)
2005–06
2015–16
Urban Poor
Urban Non-poor
Urban Poor
Urban Non-poor
n
Mean
SD
n
Mean
SD
n
Mean
SD
n
Mean
SD
0–5 months
 HAZ
100
−0.95
1.78
773
− 0.36
1.90
521
−0.86
1.91
2808
− 0.33
1.88
vWAZ
100
−1.54
1.63
773
−1.05
1.30
521
−1.49
1.32
2808
−1.18
1.31
 WHZ
100
− 1.11
1.75
773
−1.00
1.91
521
−1.09
1.79
2808
−1.25
1.84
5–10 months
 HAZ
127
−1.41
1.97
1153
−0.61
1.68
712
− 0.73
2.07
3784
−0.33
1.85
 WAZ
127
−2.06
1.43
1153
−1.08
1.28
712
−1.56
1.38
3784
−1.06
1.27
 WHZ
127
− 1.44
1.62
1153
−0.85
1.57
712
−1.34
1.57
3784
− 1.02
1.63
10–15 months
 HAZ
112
− 1.82
1.53
1105
−1.14
1.58
612
−1.51
1.89
3600
− 0.88
1.90
 WAZ
112
−1.91
1.26
1105
− 1.19
1.21
612
−1.71
1.30
3600
−1.10
1.26
 WHZ
112
−1.32
1.43
1105
−0.82
1.43
612
−1.22
1.49
3600
−0.84
1.52
15–20 months
 HAZ
157
−2.24
1.76
1172
−1.62
1.60
702
−1.74
1.83
3977
−1.27
1.72
 WAZ
157
− 2.04
1.30
1172
−1.27
1.24
702
−1.75
1.22
3977
−1.18
1.22
 WHZ
157
−1.30
1.47
1172
−0.68
1.32
702
−1.24
1.30
3977
−0.78
1.41
20–25 months
 HAZ
100
−2.76
1.52
1133
−1.76
1.56
656
−2.15
1.63
3771
−1.42
1.73
 WAZ
100
−2.19
1.39
1133
−1.47
1.17
656
−2.01
1.16
3771
−1.28
1.29
 WHZ
100
−1.10
1.49
1133
−0.81
1.22
656
−1.27
1.23
3771
−0.79
1.41
25–30 months
 HAZ
138
−2.33
1.61
1227
−1.61
1.54
667
−1.94
1.68
3819
−1.07
1.74
 WAZ
138
−2.05
1.10
1227
−1.38
1.18
667
−1.88
1.17
3819
−1.23
1.21
 WHZ
138
−1.10
1.10
1227
−0.73
1.21
667
−1.17
1.29
3819
−0.94
1.28
30–35 months
 HAZ
134
−2.61
1.81
1196
−1.72
1.61
697
−1.92
1.48
3877
−1.38
1.52
 WAZ
134
−2.25
1.22
1196
−1.49
1.23
697
−1.82
1.14
3877
−1.34
1.19
 WHZ
134
−1.10
1.20
1196
−0.77
1.29
697
−1.07
1.21
3877
−0.85
1.29
35–40 months
 HAZ
133
−2.52
1.61
1227
−1.66
1.64
710
−1.97
1.49
3900
−1.28
1.53
 WAZ
133
−2.13
1.00
1227
−1.53
1.27
710
−1.91
1.08
3900
−1.37
1.20
 WHZ
133
−0.98
1.02
1227
−0.86
1.24
739
−1.14
1.33
3900
−0.95
1.34
40–45 months
 HAZ
134
−2.46
1.56
1219
−1.70
1.50
739
−1.91
1.54
4041
−1.23
1.46
 WAZ
134
−2.01
1.35
1219
−1.50
1.11
739
−1.89
1.16
4041
−1.28
1.21
 WHZ
134
−0.83
1.47
1219
−0.75
1.18
710
−1.13
1.28
4041
−0.85
1.32
45–50 months
 HAZ
131
−2.48
1.68
1098
−1.85
1.63
749
−1.93
1.42
3976
−1.31
1.45
 WAZ
131
−2.10
1.47
1098
−1.69
1.20
749
−1.98
1.06
3976
−1.39
1.14
 WHZ
131
−0.90
1.50
1098
−0.87
1.25
749
−1.24
1.19
3976
−0.92
1.33
50–55 months
 HAZ
145
−2.62
1.20
1238
−1.46
1.39
718
−1.91
1.34
3883
−1.28
1.35
 WAZ
145
−2.22
1.06
1238
−1.39
1.17
718
−1.83
1.09
3883
−1.35
1.21
 WHZ
145
−0.95
1.26
1238
−0.78
1.27
718
−1.03
1.18
3883
−0.89
1.39
55–60 months
 HAZ
137
−2.51
1.29
1152
−1.59
1.36
734
−2.08
1.20
3830
−1.34
1.26
 WAZ
137
−2.18
1.02
1152
−1.54
1.16
734
−1.98
0.95
3830
−1.43
1.14
 WHZ
137
−0.99
1.21
1152
−0.88
1.19
734
−1.09
1.15
3830
−0.96
1.37
Figure 2 depict concentration curves for stunting, wasting, and underweight among children in urban India, during 2005–06 and 2015–16. The result of the concentration curve shows a reduction in the inequality for all three indicators among children below five years in urban India. However, there was a significant decrement in the inequality for stunting, underweight and wasting; the decrement was much faster in wasting (CI: 0.116 [Se: 0.010; p < 0.05] in 2005–06 to 0.045 [Se: 0.003; p < 0.05] in 2015–16) than in stunting (CI: 0.213 [Se: 0.006; p < 0.05] in 2005–06 to 0.162 [Se; 0.004; p < 0.05] in 2015–16) or underweight (CI: 0.186 [Se: 0.005; p < 0.05] in 2005–06 to 0.156 [Se; 0.004; p < 0.05] in 2015–16).
Table 3 presents the estimates of decomposition analysis for the contribution of various explanatory variables for stunting among urban children in India in 2005–06 & 2015–16. The absolute CI for stunting decreased from − 0.186 in 2005–06 to − 0.156 in 2015–16, which depicts that economic inequality has significantly decreased over the two time-periods (0.03; p < 0.05). In 2005–06, education of the mother explained about 19% of the observed inequality in the prevalence of stunting among children, which increased to around 27% during 2015–16. Most of the economic inequality in stunting during 2015–16 was explained through mother’s education, parity, defecation, and stool disposal. During 2015–16, education explained 26.6% of the observed inequality in stunting among children, followed by 19% by parity and 14.3% by defecation. During both periods, more than 85% of the economic inequality for stunting among children had been explained by three factors, namely; maternal factors, health-seeking factors, and environmental factors. Maternal factors remained the most significant contributor to inequality during both the time-periods. The contribution of environmental factors in explaining the disparity had increased by about 10% from 13.3% in 2005–06 to 23.2% in 2015–16. However, the contribution of health-seeking factors in explaining the inequality had declined from 30.6% in 2005–06 to 10.4% in 2015–16.
Table 3
Estimates of decomposition analysis for contribution of various explanatory variables for stunting among urban children under five years in India, 2005–06 & 2015–16
 
NFHS 2005–06
NFHS 2015–16
Variables
Elasticity
CI
Absolute contribution to CI
Percentage Contribution
Elasticity
CI
Absolute contribution to CI
Percentage Contribution
Mother factors
 Age (years)
−0.061
0.019
− 0.001
2.3
− 0.067
0.025
−0.002
5.5
 Education
−0.055
0.173
−0.010
19.1
−0.086
0.094
−0.008
26.6
 Age at First Birth (years)
−0.110
0.045
−0.005
9.9
0.019
0.023
0.000
−1.5
 Parity
0.081
−0.091
− 0.007
14.8
0.076
−0.075
− 0.006
19.0
 Anemia
−0.007
−0.076
0.001
−1.1
0.015
−0.051
− 0.001
2.6
Socio-economic factors
 Caste
−0.083
0.026
−0.002
4.4
−0.071
0.025
−0.002
5.9
 Religion
−0.008
− 0.003
0.000
−0.1
0.003
−0.002
0.000
0.0
Child factors
 Age (months)
0.094
− 0.005
0.000
0.9
0.023
0.001
0.000
−0.1
 Sex
−0.030
− 0.004
0.000
−0.3
− 0.026
−0.003
0.000
− 0.3
 Anemia
0.065
−0.064
−0.004
8.4
0.040
− 0.058
−0.002
7.7
 Diarrhea
0.001
−0.025
0.000
0.1
0.000
−0.039
0.000
0.0
 Birth weight
0.011
0.098
0.001
−2.2
0.012
− 0.027
0.000
1.1
 Colostrum feeding
0.001
0.079
0.000
−0.2
0.002
0.009
0.000
− 0.1
Environmental factors
 Source of drinking water
0.035
0.013
0.000
−0.9
0.010
−0.002
0.000
0.1
 Defecation
− 0.085
0.066
−0.006
11.4
−0.094
0.046
−0.004
14.3
 Stool Disposal
0.007
−0.308
−0.002
4.1
0.009
− 0.308
−0.003
8.9
 Regions of India
0.045
0.014
0.001
−1.3
−0.026
−0.002
0.000
−0.2
Health seeking factors
 Skilled birth attendant
0.000
0.141
0.000
−0.1
−0.032
0.042
−0.001
4.5
 Place of delivery
−0.070
0.163
−0.011
22.8
−0.029
0.050
−0.001
4.9
 Full Immunization
−0.016
0.146
−0.002
4.6
0.023
0.046
0.001
−3.5
 Full ANC
−0.004
0.360
−0.001
3.2
−0.007
0.208
−0.001
4.5
Explained CI
  
−0.050
100
  
−0.030
100.00
Actual CI
  
−0.186
   
−0.156
 
Residual
  
−0.136
   
−0.126
 
Table 4 presents the estimates of decomposition analysis for the contribution of various explanatory variables for underweight among urban children in India, during 2005–06 & 2015–16. The actual CI for underweight decreased from − 0.213 in 2005–06 to − 0.162 in 2015–16, which depicts a significant reduction in economic inequality (0.051, p < 0.05). In explaining economic inequality for underweight in 2005–06, maternal education (28.8%) was the most significant contributor in explaining the majority of the inequality followed by open defecation (16.9%), and place of delivery (16.7%). In 2015–16, the contribution of maternal education slightly decreased to 25.4%, but remained as a significant contributor in explaining the inequality followed by open defecation (17.5%), and parity (16.3%). In 2015–16, nearly half of the economic disparities in underweight among urban children was explained by maternal factors (49%), followed by environmental factors (25.4%), and health seeking factors (14.4%).
Table 4
Estimates of decomposition analysis for contribution of various explanatory variables for underweight among urban children under five years in India, 2005–06 & 2015–16
 
NFHS 2005–06
NFHS 2015–16
Variables
Elasticity
CI
Absolute contribution to CI
Percentage Contribution
Elasticity
CI
Absolute contribution to CI
Percentage Contribution
Mother factors
 Age (years)
−0.043
0.019
−0.001
1.8
−0.072
0.025
−0.002
5.96
 Education
−0.078
0.173
−0.013
28.8
−0.081
0.094
−0.008
25.44
 Age at First Birth (years)
−0.067
0.045
−0.003
6.4
0.004
0.023
0.000
−0.34
 Parity
0.041
−0.091
−0.004
7.9
0.064
−0.075
−0.005
16.29
 Anemia
0.011
−0.076
−0.001
1.7
0.010
−0.051
−0.001
1.68
Socio-economic factors
 Caste
−0.048
0.026
−0.001
2.7
−0.059
0.025
−0.001
5.04
 Religion
−0.030
−0.003
0.000
−0.2
− 0.005
−0.002
0.000
0.00
Child factors
 Age (months)
0.079
−0.005
0.000
0.8
0.059
0.001
0.000
−0.25
 Sex
−0.017
−0.004
0.000
−0.2
− 0.029
−0.003
0.000
−0.25
 Anemia
0.033
−0.064
−0.002
4.5
0.025
−0.058
−0.001
4.87
 Diarrhea
0.002
−0.025
0.000
0.1
0.001
−0.039
0.000
0.17
 Birth weight
0.015
0.098
0.001
−3.2
0.019
−0.027
−0.001
1.68
 Colostrum feeding
0.003
0.079
0.000
−0.5
0.002
0.009
0.000
−0.08
Environmental factors
 Source of drinking water
0.038
0.013
0.000
−1.0
0.033
−0.002
0.000
0.17
 Defecation
−0.119
0.066
−0.008
16.9
−0.112
0.046
−0.005
17.46
 Stool Disposal
0.010
−0.308
−0.003
6.7
0.008
−0.308
−0.002
7.81
 Regions of India
0.028
0.014
0.000
−0.9
− 0.006
−0.002
0.000
−0.08
Health seeking factors
 Skilled birth attendant
−0.001
0.141
0.000
0.3
−0.026
0.042
−0.001
3.61
 Place of delivery
−0.048
0.163
−0.008
16.7
−0.045
0.050
−0.002
7.56
 Full Immunization
−0.018
0.146
−0.003
5.6
0.002
0.046
0.000
−0.34
 Full ANC
−0.006
0.360
−0.002
5.0
−0.005
0.208
−0.001
3.61
Explained CI
  
−0.047
100.00
  
−0.030
100.00
Actual CI
  
−0.213
   
−0.162
 
Residual
  
−0.166
   
−0.132
 
Table 5 presents the estimates of decomposition analysis for the contribution of various explanatory variables for wasting among urban children in India, 2005–06 & 2015–16. The actual CI for wasting decreased from − 0.116 in 2005–06 to − 0.045 in 2015–16, which depicts that economic inequality has significantly decreased over time (0.071, p < 0.05). Unlike for stunting and underweight, defecation (36.8%) explained the majority of the economic inequality in wasting during 2005–06, which further increased to (46.9%) in 2015–16. The contribution of maternal education in the explanation of economic inequality decreased from (33.4%) in 2005–06 to (11.8%) in 2015–16. In 2015–16, environmental factors (55.9%) explained most of the gap for economic inequality for wasted children in India, followed by maternal factors (22.2%) and Health seeking factors (22.2%).
Table 5
Estimates of decomposition analysis for contribution of various explanatory variables for wasting among urban children under five years in India, 2005–06 & 2015–16
 
NFHS 2005–06
NFHS 2015–16
Variables
Elasticity
CI
Absolute contribution to CI
Percentage Contribution
Elasticity
CI
Absolute contribution to CI
Percentage Contribution
Mother factors
 Age (Years)
−0.008
0.019
0.000
1.3
−0.004
0.025
0.000
1.4
 Education
−0.023
0.173
−0.004
33.4
−0.009
0.094
−0.001
11.8
 Age at First Birth (years)
0.006
0.045
0.000
−2.1
−0.004
0.023
0.000
1.4
 Parity
0.013
−0.091
−0.001
9.9
0.006
−0.075
0.000
6.6
 Anemia
0.003
−0.076
0.000
1.9
0.002
−0.051
0.000
1.0
Socio-economic factors
 Caste
−0.034
0.026
−0.001
7.6
−0.009
0.025
0.000
3.1
 Religion
−0.004
−0.003
0.000
0.0
−0.010
−0.002
0.000
−0.4
Child factors
 Age (months)
−0.068
−0.005
0.000
−2.5
−0.056
0.001
0.000
0.7
 Sex
−0.027
−0.004
0.000
−1.1
−0.023
− 0.003
0.000
− 0.7
 Anemia
−0.006
− 0.064
0.000
−3.0
− 0.008
−0.058
0.000
−6.6
 Diarrhea
0.003
−0.025
0.000
0.4
0.001
−0.039
0.000
0.7
 Birth weight
0.007
0.098
0.001
−5.9
0.010
−0.027
0.000
3.5
 Colostrum feeding
0.004
0.079
0.000
−2.8
0.004
0.009
0.000
−0.7
Environmental factors
 Source of drinking water
0.023
0.013
0.000
−2.3
0.031
−0.002
0.000
0.7
 Defecation
−0.066
0.066
−0.004
36.8
−0.072
0.046
−0.003
46.9
 Stool Disposal
0.002
−0.308
−0.001
3.8
0.002
−0.308
−0.001
8.0
 Regions of India
0.006
0.014
0.000
−0.6
0.017
−0.002
0.000
0.4
Health seeking factors
 Skilled birth attendant
0.011
0.141
0.002
−12.7
−0.001
0.042
0.000
0.4
 Place of delivery
−0.004
0.163
−0.001
5.3
−0.006
0.050
0.000
3.8
 Full Immunization
−0.022
0.146
−0.003
26.4
−0.025
0.046
−0.001
16.0
 Full ANC
−0.002
0.360
−0.001
6.1
−0.001
0.208
0.000
2.1
Explained CI
  
−0.012
100.00
  
−0.007
100.00
Actual CI
  
−0.116
   
−0.045
 
Residual
  
−0.104
   
−0.038
 

Discussion

Despite recent achievements in economic progress, India failed to ensure better outcomes in child growth. Results further suggested that there exists socio-economic clustering that is further widening the gap in securing development among children. Through this study, we have tried to explain the factors contributing to economic inequality in stunting, underweight, and wasting among children below five years in urban India.
There is little data to understand the timing of growth faltering in under-five age children in India, and whatever limited study conducted to understand the growth faltering among children measured growth faltering through reference growth standards of NCHS (National Centre for Health Statistics) methodology [25]. This study has the edge over previous studies in measuring growth faltering as this study used WHO standards to measure the growth faltering among children over NCHS methodology [34]. The result confirms that wasting among urban poor and non-poor children was more prone during the first year of birth, and stunting among urban poor and non-poor children is more prone during the second year of birth. Growth flattering in underweight is more during the second year of birth among urban poor children and the fifth year of birth among urban non-poor children. Critically, children aged 21–25 months were more prone to growth faltering than the children of any other age group. Studies found that children in low-middle-income countries experience rapid growth faltering during the first two years of life [40].
Maternal factors remained a prime contributor to inequality. Stunting in simple terms is defined as - > 2 SD height-for-age [38], and measures the past or chronic child undernutrition. The mother’s related factors explained a little more than half of the inequality for stunting among children during 2015–16. Various studies in Indian set up are in coordination with this study, concluded that maternal factors such as mother’s age mother’s education, age at first birth, parity, and anaemia were highly associated with stunting [28, 36]. Of all the mother’s factors, mother’s education is the most significant contributor to the economic inequality in defining stunting among children. Not only in India [10], but in developed [44] and developing countries [2, 20] also, mother’s education was found significantly associated with stunting among children. Among environmental factors, defecation and stool disposal explained the highest economic inequality in stunting among children. A study conducted in Rwanda for 10 years, using decomposition analysis reported that defecation has no association with stunting [30]. Another study conducted in rural Zimbabwe employing cluster-randomized trials found that WASH (Water, Sanitation, and Hygiene) practices implemented in rural areas are unlikely to reduce stunting [16]. However, few studies found that sanitation and defecation significantly affect stunting among children [24]. A study conducted in Indian settings utilizing NFHS data concluded that the practice of open defecation influences the inequality in stunting [35]. Health seeking factors explained about 30% of the inequality in stunting in 2005–06, and in 2015–16, it could only explain about 10% of the inequality. From various works of literature, it can be summed up that full Antenatal Care and Skill attendants at birth had increased over time in India [1].
Underweight is defined as - > 2 SD weight-for-age, and it depicts the past as well as present undernutrition. During both the time, mother’s factors remained the highest contributory factors that explained the inequality in underweight among children aged 0–5 years. Employing the decomposition approach, a study concluded that maternal factors improve WAZ among children aged 0–5 years in India [27]. In other studies also, the role of mother’s education in explaining the inequalities in underweight was highlighted in Indian settings [29, 35]. Of the environmental factors, defecation remained the highest contributor to the inequality in underweight with nearly 17%, during both the time-periods. Open defecation is a problem among masses in India, and recently the Indian Government has done well to tackle the issue [6]. On the base of the decomposition approach, a study conducted in India confirmed that open defecation positively influences the inequality in underweight [35]. A study conducted in five Indian states; Uttar Pradesh, Karnataka, Madhya Pradesh, Rajasthan, and West Bengal, found that children from open defecation free (ODF) districts were less underweight than children in non-ODF districts [37], thus confirming the importance of open defecation in understanding the inequality in underweight. The result found that health-seeking factors explained nearly one-fourth (27.7%) of the inequality in underweight in 2005–06, but the same declined to nearly 14.4% in 2015–16. The decline in the contribution of the place of delivery in explaining the inequality signifies the equitable access of institutional deliveries in urban areas among poor and non-poor. A study found that in India, the utilization of institutional delivery care has increased from 43% in 2004 to 83% in 2014 [21]. This increase in institutional delivery had helped in shrinking the gap of inequality in underweight, as explained by place of delivery.
Wasting is defined as - > 2 SD weight-for-height among children. It is a measure of current nutrition status, also known as acute undernutrition. The inequality in wasting among children has decreased, but the prevalence of wasting has increased. Around the world, wasting had reduced at a plodding pace over the last 40 years, but in countries like India and Sri Lanka, wasting has increased [39]. Maternal factors (44.4%) were the highest contributory factors in explaining the inequality in wasting among children during 2005–06, but the contribution of maternal factors in inequality in wasting had declined significantly to 22.2% in 2015–16. In previous studies, maternal factors were deemed as the contributory factors in explaining the inequalities in wasting among children aged below five years [23]. Nearly half of the inequality in wasting among children had been explained by open defecation (46.9%) in 2015–16, citing the importance of sanitation. Since the weight-for-height is a measure of current nutritional status and is likely to be affected by small illnesses episodes and infectious diseases [23], the contribution of defecation in inequality in wasting among children is highly visible. Unavailability of toilet facilities within households promotes open defecation, and in turn, it facilitates water-borne diseases, which negatively affect the current health and nutrition status among children. Open defecation reinforces under-nutrition (wasting) via increased susceptibility to infections and through reducing immunity [31].

Strengths and limitations

One of the strengths of the study is the considerable sample size for both the survey periods. This study explores the inequalities in stunting, underweight, and stunting among urban poor by employing survey data, which is 10 years apart, thus giving a clear picture of decadal change in economic inequality in stunting, underweight, and wasting among urban children. Decomposition allows our understanding of various factors contributing to the disparities inequality in stunting, underweight, and wasting among urban children. This study segregated the covariates of economic inequality into five categories; mother’s factor, health-seeking factors, environmental factors, child factors, and socio-economic factors, thus highlighting the importance of particular covariate in explaining the inequality. The cross-sectional nature of data limits our knowledge about the causation accurately. Maternal factors used in this article may not be exclusively maternal physiological or maternal factors as such only, some of them are more of socio-economic nature (e.g. education). Educational status is commonly used as a proxy of socio-economic status.

Conclusions

The study made a reasonable attempt to describe the growth pattern among children below five along with the inequality in stunting, underweight, and wasting among children in urban India. Several important observations emerge from this study. First, during 2005–06 as well as 2015–16, maternal factors (specifically mother’s education) were the highest contributory factors in explaining rich-poor inequality in stunting and underweight among urban children. Second, maternal factors were the most significant contributory factors in explaining the wasting among children during 2005–06, however environmental factors (specifically open defecation) became the most significant contributory factors in explaining the rich-poor inequality in wasting among children during 2015–16. Third, more than 85% of the inequality in stunting, underweight, and wasting among urban children was explained by maternal factors, environmental factors, and health-seeking factors. Fourth, growth faltering among children reaches its peak by the end of 2 years of age.
Rich-poor inequality in malnutrition calls out for the expedite policy interventions aimed at poverty reduction in urban areas. There is also a need to provide mass education regarding nutrition and health, along with focussing on the correlates that aim at improving mother’s education. Environmental factors also promoted the inequality in stunting, wasting, and underweight in urban children; there is a need to focus the enigma of open defecation in India. After the launch of Swachh Bharat Mission in 2014, the government of India has focused a lot on building individual household latrines [6]. Despite having access to latrines, people prefer to defecate in open [3, 8, 18, 32]. There is a need to promote the use of latrines among Indian masses. There is a need to bring a change in behavioural aspects and preferences of people to promote latrine use. Information, Education, and Communication (IEC) activities are encouraged to clamp down the economic inequality in stunting, underweight, and wasting among urban children. Since the cognitive and developmental deficiency resulting from malnutrition may significantly be irreversible after two years of age [7], it is being understood that the ‘window of opportunity’ for preventing malnutrition ends at age two years. It is therefore encouraged that policy-makers shall evenly target children for nutritional programs, with emphasis on children aged below two years.
All the nutrition-specific and nutrition-sensitive interventions in urban areas should be prioritized, focusing on urban poor, who are often clustered in low-income slums. Rich-poor inequality in child growth faltering calls out for integration and convergence of nutrition interventions with policy intervention aimed at poverty reduction in urban areas. There is also a need to expand the scope of the ICDS program to provide mass education regarding nutrition and health by making provisions of home visits primarily focusing at pregnant and lactating mothers.

Acknowledgements

Not applicable.
The data is freely available in public domain and survey agencies that conducted the field survey for the data collection have collected a prior consent from the respondent. Local ethics committee of International Institute for Population Sciences (IIPS), Mumbai, ruled that no formal ethics approval was required to carry out research from this data source.
Not applicable.

Competing interests

The authors declare that they have no competing interests.
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Metadaten
Titel
Inequality in child undernutrition among urban population in India: a decomposition analysis
verfasst von
S. K. Singh
Shobhit Srivastava
Shekhar Chauhan
Publikationsdatum
01.12.2020
Verlag
BioMed Central
Erschienen in
BMC Public Health / Ausgabe 1/2020
Elektronische ISSN: 1471-2458
DOI
https://doi.org/10.1186/s12889-020-09864-2

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