Skip to main content
PMC home page
Maternal & Child Nutrition logoLink to Maternal & Child Nutrition
. 2007 May 29;3(3):216–221. doi: 10.1111/j.1740-8709.2007.00099.x

Stunting, underweight and wasting among Integrated Child Development Services (ICDS) scheme children aged 3–5 years of Chapra, Nadia District, West Bengal, India

Kaushik Bose 1, Sadaruddin Biswas 1, Samiran Bisai 1, Sanjib Ganguli 1, Argina Khatun 1, Ashish Mukhopadhyay 1, Mithu Bhadra 1
PMCID: PMC6860773  PMID: 17539890

Abstract

This study investigated age and sex variations in height and weight, levels of stunting, underweight and wasting among 533 (254 boys; 279 girls) 3‐ to 5‐year‐old rural children of Bengalee ethnicity at 11 Integrated Child Development Services centres of Nadia District, West Bengal, India. Height‐for‐age, weight‐for‐age and weight‐for‐height < −2 z‐scores were used to evaluate stunting, underweight and wasting, respectively, following the National Center for Health Statistics (NCHS) Guidelines. Results revealed that boys were significantly heavier than girls at age 3 years. Significant age differences existed in mean height and weight in both sexes. Mean z‐scores of height‐for‐age, weight‐for‐age and weight‐for‐height were lower than those of NCHS for both sexes at all ages. The overall (age and sex combined) rates of stunting, underweight and wasting were 23.9%, 31.0% and 9.4%, respectively. The rate of underweight and wasting was higher among girls (underweight = 35.1%, wasting = 12.2%) compared with boys (underweight = 26.5%, wasting = 6.3%). In general, the frequency of stunting increased with increasing age in both sexes. Based on the World Health Organization classification of severity of malnutrition, the overall prevalence of underweight was very high (≥30%). The prevalence rates of stunting (20–29%) and wasting (5–9%) were medium. In conclusion, the nutritional status of the subjects is unsatisfactory. There is scope for improvement in the form of enhanced supplementary nutrition.

Keywords: India, Bengalee, preschool children, stunting, underweight, wasting

Introduction

Child growth is widely used to assess adequate nutrition, health and development of individual children, and to estimate overall nutritional status and health of populations. Compared with other health assessment tools, measuring child growth is a relatively inexpensive, easy‐to‐perform and non‐invasive process (WHO 1995; Lee & Nieman 2003; Blössner et al. 2006). During the preschool age period, children have special nutritional needs because of their extensive growth and development (WHO 1995; Lee & Nieman 2003; Bishnoi et al. 2004). The legacy of malnutrition,especially among preschool children, is a huge obstacle to overall national development (Bishnoi et al. 2004). Undernutrition among preschool children is an important health problem in rural India (Saxena et al. 1997; Yadav & Singh 1999; Mahapatra et al. 2000;Brahmbhatt et al. 2001; Rajaram et al. 2003; Kumar & Bhawani 2005; Ray 2005) including West Bengal (Mustaphi & Dobe 2005). However, there exists scanty information of the prevalence of undernutrition among preschool children in India (George et al. 2000; Bishnoi et al. 2004; Kumari 2005) and West Bengal (Shaikh et al. 2003; Mustaphi & Dobe 2005).

Three internationally recommended indicators most commonly used are child stunting (low height‐for‐age), underweight (low weight‐for‐age) and wasting (low weight‐for‐height) (WHO 1995; Lee & Nieman 2003). While stunting reflects a failure to reach linear growth potential due to suboptimal health and/or nutritional conditions, underweight reveals low body mass relative to chronological age, which is influenced by both, a child's height and weight. Underweight thus cannot distinguish between a child who is small in weight relative to his/her height and a child who is low in height relative to his/her age, but who may be normal in weight‐for‐height. On the other hand, wasting is an indicator of acute undernutrition, the result of more recent food deprivation or illness (WHO 1995).

The Integrated Child Development Services (ICDS) scheme is the largest national programme for the promotion of mother and child health and their development in the world (Kapil & Pradhan 1999). The beneficiaries include children below 6 years, pregnant and lactating mothers, and other women in the age group of 15–44 years (Kapil & Pradhan 1999). The package of services provided by the ICDS scheme includes supplementary nutrition, immunization, health check‐up, referral services, nutrition and health education, and preschool education (Kapil & Pradhan 1999). The scheme services are rendered essentially through the ‘Anganwadi’ worker at a village centre called ‘Anganwadi’. There is therefore an urgent need to evaluate the nutritional status of children at ICDS centres to determine whether they have low rates of stunting, underweight and wasting. Low rates of stunting, underweight and wasting would imply that the supplementary nutrition being administered to the children is effective in reducing the rates of undernutrition. However, very few investigations have done this (Bhasin et al. 2001; Mustaphi & Dobe 2005).

In view of this, the present investigation was undertaken to determine age and sex variations in height and weight, as well as to evaluate the levels of stunting, underweight and wasting, among 3‐ to 5‐year‐old ICDS children of Bengalee ethnicity from Chapra Block, Nadia District, West Bengal, India.

Materials and methods

Study area and subjects

The present study was undertaken at 11 ICDS centres in Chapra Block, Nadia District, West Bengal. The study area is situated at the India–Bangladesh international border, 140 km from Kolkata, the provincial capital of West Bengal. The area is remote and mostly inhabited by Muslims. All preschool children (3–5 years old) living in Chapra Block are enrolled at these centres. The ICDS authorities are allocated 80 paise (approximately 2 US cents) per head (child) per day by the Government of India to provide supplementary nutrition to the children. This financial assistance ensures that each child is given a porridge consisting of 41 g of rice and 17 g of lentils per day.

Formal ethical approval was obtained from Vidyasagar University and ICDS authorities prior to the commencement of the study. Subjects were randomly selected from 11 ICDS centres of Hatkhola Gram Panchyat of Chapra Block, Nadia District, West Bengal. A total of 545 children (male = 259; female = 286) aged 3–5 years were measured, out of whom 12 individuals (5 boys and 7 girls) were excluded because of missing data. The final sample size was 533 (254 boys and 279 girls). Age and ethnicity of the subjects were verified from official records.

Anthropometric measurements and evaluation of nutritional status

Height and weight measurements were taken on each subject following the standard techniques (Lohman et al. 1988). Technical errors of measurements (TEM) were found to be within reference values (Ulijaszek & Kerr 1999). Thus, TEM was not incorporated in statistical analyses.

Three commonly used undernutrition indicators – stunting, underweight and wasting – were used to evaluate the nutritional status of the subjects. The United States National Center for Health Statistics (NCHS) (Hamill et al. 1979; WHO 1983) age‐ and sex‐specific −2 z‐scores were followed to define stunting, underweight and wasting. The following scheme was utilized:

  • 1

     Stunting: <−2 HAZ (z‐score for height‐for‐age);

  • 2

     Underweight: <−2 WAZ (z‐score for weight‐for‐age);

  • 3

     Wasting: <−2 WHZ (z‐score for weight‐for‐height).

where HAZ, WAZ and WHZ refer to height‐for‐age, weight‐for‐age and weight‐for‐height age‐ and sex‐specific z‐scores, respectively, of NCHS.

We followed the World Health Organization (WHO 1995) classification for assessing severity of malnutrition by percentage prevalence ranges of these three indicators among children. The classification is shown in Table 1.

Table 1.

Classification assessment for severity of malnutrition by percentage prevalence ranges (WHO 1995)

Classifications Low (%) Medium (%) High (%) Very High (%)
Stunting <20 20–29 30–39 ≥40
Underweight <10 10–19 20–29 ≥30
Wasting <5 5–9 10–14 ≥15
Open in a new tab

Statistical analyses

The distributions of height and weight were not significantly skewed, therefore not necessitating their normalization. Between sexes, differences in means of height and weight were tested by Student's t‐test. One‐way (Scheffe's Procedure) analyses were undertaken to test for age differences in mean height and weight in each sex.

Results

The means and standard deviations of height and weight by age and sex are presented in Table 2. Significant sex difference (t = 2.14, P < 0.05) was observed in mean weight at age 3 years. Significant (P < 0.001) age differences existed in mean height and weight in boys [height: F (df1=2,df2=251) = 80.836; weight: F (df1=2,df2=251) = 50.232] as well as girls [height: F(df1=2,df2=276) = 119.519; weight: F (df1=2,df2=276) = 63.193].

Table 2.

Means and standard deviations of anthropometric characteristics of the rural Bengalee preschool children of Chapra, Nadia District, West Bengal, India

Age Sex n Height (cm) Weight (kg)
3 Boys 66 91.2 (5.6) 12.2* (1.4)
Girls 79 90.2 (4.9) 11.7* (1.3)
4 Boys 102 98.0 (5.1) 13.6 (1.4)
Girls 111 97.4 (5.2) 13.5 (1.5)
5 Boys 86 102.2 (5.3) 14.7 (1.7)
Girls 89 102.1 (4.9) 14.2 (1.5)
Open in a new tab

Standard deviations are presented in parentheses. *Significant sex differences (t = 2.14, P < 0.05).

Table 3 presents the mean z‐scores for height‐for‐age, weight‐for‐age and weight‐for height. Results revealed that the mean HAZ, WAZ and WHZ were lower than (negative value) those of NCHS for both sexes at all ages. These values ranged from −0.754 (HAZ for boys aged 3 years) to −1.803 (WAZ for girls aged 5 years).

Table 3.

Mean HAZ, WAZ and WHZ among the subjects

Age Sex HAZ WAZ WHZ
3 Boys −0.754 (0.183) −1.351 (0.112) −0.964 (0.089)
Girls −0.996 (0.147) −1.664 (0.102) −1.173 (0.095)
Total −0.886 (0.116) −1.521 (0.076) −1.077 (0.066)
4 Boys −0.900 (0.124) −1.403 (0.081) −0.999 (0.063)
Girls −1.040 (0.122) −1.476 (0.084) −0.998 (0.071)
Total −0.973 (0.087) −1.442 (0.059) −0.999 (0.048)
5 Boys −1.400 (0.130) −1.561 (0.095) −0.980 (0.079)
Girls −1.413 (0.119) −1.803 (0.082) −1.286 (0.075)
Total −1.406 (0.088) −1.684 (0.063) −1.136 (0.056)
Overall Boys −1.031 (0.083) −1.443 (0.054) −0.984 (0.043)
Girls −1.146 (0.075) −1.634 (0.052) −1.139 (0.046)
Total −1.092 (0.056) −1.543 (0.038) −1.065 (0.032)
Open in a new tab

HAZ, height‐for‐age z‐score; WAZ, weight‐for‐age z‐score; WHZ, weight‐for‐height z‐score.

Standard error of mean is presented in parentheses.

The frequencies of stunting, underweight and wasting are presented in Table 4. The overall (age and sex combined) rates of stunting, underweight and wasting were 23.9%, 31.0% and 9.4%, respectively. The rates of underweight and wasting were significantly higher among girls (underweight = 35.1%, wasting = 12.2%) compared with boys (underweight = 26.5%, wasting = 6.3%). In general, the frequency of stunted increased with increasing age in both sexes. Based on the WHO classification of severity malnutrition, the overall (age and sex combined) prevalence of underweight was very high (≥30%), while those of stunting (20–29%) and wasting (5–9%) were medium. It is noteworthy that, among girls, the prevalence of wasted was high (10–14%). Moreover, while in boys the prevalence of underweight was high (20–29%), it was found to be very high (≥30%) among girls.

Table 4.

Prevalence (%) of stunting, underweight and wasting among the children

Age Sex Stunting (HAZ < −2.0) Underweight
(WAZ < −2.0) Wasting (WHZ < −2.0)
3 Boys 19.7 28.8 6.1
Girls 19.0 38.0 16.5
Total 19.3 33.8 11.7
4 Boys 21.6 22.6 7.8
Girls 25.2 30.6 7.2
Total 23.5 26.8 7.5
5 Boys 30.2 30.2 5.8
Girls 27.0 38.2 14.6
Total 28.6 34.3 10.3
Overall Boys 23.7 26.5* 6.3**
Girls 24.0 35.1 12.2
Total 23.9 31.0 9.4
Open in a new tab

HAZ, height‐for‐age z‐score; WAZ, weight‐for‐age z‐score; WHZ, weight‐for‐height z‐score. *Significant sex differences of underweight (χ2 = 4.76, P = 0.02913).**Significant sex differences of wasting (χ2 = 5.42, P = 0.019899).

Discussion

Anthropometric indicators have been widely used in population‐based studies directed to nutritional evaluation. Although they are proxy indicators (that is, they represent indirect measures of undernutrition that do not take into account nutrient intake or biochemical examination), their wide use is justified due to the ease of the method and its high sensitivity to nutritional alterations in a population (Post & Victoria 2001). Cohort studies, ideal for nutritional conditioning monitoring, suffer, in developing countries, from the logistic difficulties usually associated with population studies of large magnitude. In such cases, cross‐sectional studies can provide relevant elements for understanding the connection between health status and physical conditions of life. These studies have the advantage of relatively low costs, and they can also provide fundamental information for the implementation of health surveillance systems and the definition of long‐term health intervention strategies (Waterlow et al. 1977; Satyanarayan et al. 1989; Martorel et al. 1996).

Undernutrition continues to be a cause of ill‐health and premature mortality among children in developing countries like India (Nandy et al. 2005). The most commonly used indicators of undernutrition among children are stunting (low height‐for‐age), wasting (low weight‐for‐height) and underweight (low weight‐for‐age). Stunting is an indicator of chronic undernutrition, the result of prolonged food deprivation and/or disease or illness; wasting is an indicator of acute undernutrition, the result of more recent food deprivation or illness; underweight is used as a composite indicator to reflect both acute and chronic undernutrition, although it cannot distinguish between them (WHO 1995).

These indices are compared against an international reference population developed from anthropometric data collected in the United States by the NCHS (Hamill et al. 1979; WHO 1983). Children whose measurements fall below −2 z‐scores of the reference population median are considered undernourished (i.e. to have stunting, wasting or to be underweight). These indices reflect distinct biological processes, and their use is necessary for determining appropriate interventions (WHO 1995).

The results of the present study clearly indicated that, based on the WHO classification of severity malnutrition, the overall (age and sex combined) prevalence of underweight was very high (≥30%) while those of stunting (20–29%) and wasting (5–9%) were medium. It is noteworthy that, among girls, the prevalence of wasted was high (10–14%). Moreover, while in boys the prevalence of underweight was high (20–29%), it was found to be very high (≥30%) among girls. The rates of underweight were lower than that reported from India (47%) by UNICEF (2006). Results on stunting indicated that, among these children, there existed a medium level of chronic undernutrition due to prolonged food deprivation. Regarding wasted, it was also observed that there existed a medium rate of acute undernutrition that was indicative of more recent food deprivation. Studies on underweight, which is used as a composite indicator to reflect both acute and chronic undernutrition, demonstrated that the level was very high. These findings suggested widespread adverse nutritional experience of the subjects. However, it must be noted here that the rates of underweight, wasting and stunting of the children of the present study were much lower than those reported among other children from various parts of India (Dolla et al. 2005).

It has been suggested that, as undernutrition is a function of both food deprivation and disease, which are in turn the consequences of poverty, anthropometric indices can serve only as proxies for evaluating the prevalence of undernutrition among children (Nandy et al. 2005). Efforts to reduce undernutrition, morbidity and mortality depend on reducing poverty and raising people's living standards by improving the quality of homes and by increasing access to clean drinking water and adequate sanitation. Such interventions have positive impacts on health, and implementing these also goes some way towards fulfilling people's basic human rights (Nandy et al. 2005). However, in the context of the present study, it should be noted that ICDS offers only supplementary nutrition to young children and controlling of other related factors of undernutrition is not within its ambit. As the nutritional status of the subjects of the present study is not satisfactory, it seems that there is scope for much improvement in the form of enhanced supplementary nutrition than what is currently being offered by the ICDS scheme in Chapra Block, Nadia District of West Bengal. Therefore, it is imperative that the ICDS authorities urgently consider the enhancement of the supplementary nutrition being currently given. It seems that the current food supplementation, consisting of 41 g of rice and 17 g of lentils, per child is insufficient and these amounts should be increased. This requires additional government funding.

Acknowledgements

All subjects who participated in the study are gratefully acknowledged. Special thanks are due to the ICDS authorities of Hatkhola Gram Panchyat of Chapra Block of Nadia District. The help and assistance of Z. Mondal is gratefully acknowledged.

References

  1. Bhasin S.K., Bhatia V., Kumar P. & Aggarwal O.P. (2001) Long‐term nutritional effects of ICDS. Indian Journal of Pediatrics 68, 211–216. [DOI] [PubMed] [Google Scholar]
  2. Bishnoi P., Sehgal K. & Kwatra A. (2004) Anthropometric measurements of preschool children as effected by socioeconomic factors. Asia Pacific Journal of Clinical Nutrition 13(Suppl.), S132. [Google Scholar]
  3. Blössner M., De Onis M. & Uauy R. (2006) Estimating stunting from underweight survey data In: Culture, Ecology, Nutrition, Health and Disease (Bose K. ed.), pp. 145–152. Kamla Raj Enterprise: Delhi. [Google Scholar]
  4. Brahmbhatt S.R., Brahmbhatt R.M. & Boyages S.C. (2001) Impact of protein energy malnutrition on thyroid size in an iodine deficient population of Gujarat (India): is it an aetiological factor for goiter? European Journal of Endocrinology 145, 11–17. [DOI] [PubMed] [Google Scholar]
  5. Dolla C.K., Meshram P., Srivastava P., Karforma C., Das S. & Uike M. (2005) Nutritional status of Kodaku pre‐school children in central India. Journal of Human Ecology 17, 229–231. [Google Scholar]
  6. George K.A., Kumar N.S., Lal J.J. & Sreedevi R. (2000) Anemia and nutritional status of pre‐school children in Kerala. Indian Journal of Pediatrics 67, 575–578. [DOI] [PubMed] [Google Scholar]
  7. Hamill P.V., Drizd T.A., Johnson C.L., Reed R.B., Roche A.F. & Moore W.M. (1979) Physical growth: National Center for Health Statistics percentiles. American Journal of Clinical Nutrition 32, 607–629. [DOI] [PubMed] [Google Scholar]
  8. Kapil U. & Pradhan R. (1999) Integrated Child Development Services scheme (ICDS) and its impact on nutritional status of children in India and recent initiatives. Indian Journal of Public Health 43, 21–25. [PubMed] [Google Scholar]
  9. Kumar S. & Bhawani L. (2005) Managing child nutrition in a drought affected district of Rajasthan – a case study. Indian Journal of Public Health 49, 198–206. [PubMed] [Google Scholar]
  10. Kumari S. (2005) Nutritional status of scheduled caste pre‐school children. Indian Journal of Public Health 49, 258–259. [PubMed] [Google Scholar]
  11. Lee R.D. & Nieman D.C. (2003) Nutritional Assessment. McGraw‐Hill: New York. [Google Scholar]
  12. Lohman T.G., Roche A.F. & Martorell R. (1988) Anthropometric Standardization Reference Manual. Human Kinetics Books: Chicago, IL. [Google Scholar]
  13. Mahapatra A., Geddam J.J., Marai N., Murmu B., Mallick G., Bulliyya G. et al. (2000) Nutritional status of preschool children in the drought affected Kalahandi district of Orissa. Indian Journal of Medical Research 111, 90–94. [PubMed] [Google Scholar]
  14. Martorel R., Rivera J. & Kaplowitz H. (1996)Consequences of stunting in early childhood for adult body size in Guatemala. Annals of Nestle 48, 85–92. [Google Scholar]
  15. Mustaphi P. & Dobe M. (2005) Positive deviance – the West Bengal experience. Indian Journal of Public Health 49, 207–213. [PubMed] [Google Scholar]
  16. Nandy S., Irving M., Gordon D., Subramanian S.V. & Davey Smith G. (2005) Poverty, child undernutrition and morbidity: new evidence from India. Bulletin of the World Health Organization 83, 210–216. [PMC free article] [PubMed] [Google Scholar]
  17. Post C.L. & Victoria C.G. (2001) The low prevalence of weight‐for‐height deficits in Brazilian children is related to body proportions. Journal of Nutrition 131, 1133–1134. [DOI] [PubMed] [Google Scholar]
  18. Rajaram S., Sunil T.S. & Zottarelli L.K. (2003) Analysis of childhood malnutrition in Kerala and Goa. Journal of Biosocial Science 35, 335–351. [DOI] [PubMed] [Google Scholar]
  19. Ray S.K. (2005) Action for tackling malnutrition: growth monitoring or surveillance. Indian Journal of Public Health 49, 214–217. [PubMed] [Google Scholar]
  20. Satyanarayana K., Radhaiah G., Mohan K.R., Thimmayamma B.V., Rao N.P., Rao B.S. et al. (1989) The adolescent growth spurt of height among rural Indian boys in relation to childhood nutrition background: a 18 years longitudinal study. Annals of Human Biology 16, 289–300. [DOI] [PubMed] [Google Scholar]
  21. Saxena N., Nayar D. & Kapil U. (1997) Prevalence of underweight, stunting and wasting. Indian Pediatrics 34, 627–631. [PubMed] [Google Scholar]
  22. Shaikh S., Mahalanabis D., Chaterjee S., Kurpad A.V. & Khaled M.A. (2003) Lean body mass in preschool aged children in India: gender differences. European Journal of Clinical Nutrition 57, 389–393. [DOI] [PubMed] [Google Scholar]
  23. Ulijaszek S.J. & Kerr D.A. (1999) Anthropometric measurement error and the assessment of nutritional status. British Journal of Nutrition 82, 165–177. [DOI] [PubMed] [Google Scholar]
  24. UNICEF (2006) Report Progress for Children – A Report Card on Nutrition. [WWW document]. URL http://www.unicef.org/progressforchildren/2006n4/index.html (last accessed 2 April 2007). [Google Scholar]
  25. Waterlow J.C., Buzina R., Keller W., Lane J.M., Nichman M.Z. & Tanner J.M. (1977) The prevention and use of height and weight data for comparing the nutritional status of group of children under the age of 10 year. Bulletin of the World Health Organization 55, 489–498. [PMC free article] [PubMed] [Google Scholar]
  26. World Health Organization (1983) Measuring Change in Nutritional Status. WHO: Geneva. [Google Scholar]
  27. World Health Organization (1995) Physical Status: The Use and Interpretation of Anthropometry. Technical Report Series no. 854. WHO: Geneva. [PubMed] [Google Scholar]
  28. Yadav R.J. & Singh P. (1999) Nutritional status and dietary intake in tribal children of Bihar. Indian Pediatrics 36, 37–42. [PubMed] [Google Scholar]

Articles from Maternal & Child Nutrition are provided here courtesy of Wiley

RESOURCES