Upsala J Med Sci 97: 79-92 

A longitudinal study on 
anthropometric and clinical development 

of Indian children adopted in Sweden 
I. Clinical and anthropometric condition at arrival 

L. A. Proos,' Y .  Hofvander,' K. Wennqvist,' T. Tuvemo2 
The 'International Child Health Unit of the 2Department of Pediatrics, Uppsala University, 

Uppsala Sweden 

ABSTRACT 

One hundred and fourteen children (60% girls) adopted from India through five major adoption 
organizations, were recruited consecutively. This paper describes the environment of the children 

in India and in Sweden, discusses the certainty of the ages and reports their condition at arrival 

in Sweden. The median age at arrival was 9.3 months, 62% being below one year of age (range 

3-72 months). Infectious diseases similar in kind and frequency to those noted in child populations 

in developing countries, were found. Heighdage and weightlage mean values were approximately 

-2 standard deviation scores (SDS) of the NCHS/WHO standard, which is similar to the 

anthropometric status of Indian average children. There were no significant sex differences. 
Thirty-seven birth weights were known, the majority below 2 500 g. Psychomotor retardation was 

found in 29% of the children. In the children with stunting and in those with weightlage 

< - 3  SDS at arrival there were high percentages of psychomotor retardation, anaemia and 

combined wasting and stunting. Therefore these children should be regarded as a risk group and 

be followed up with special care. 

INTRODUCTION 
During the period 1969-87 more than 27 OOO children were adopted from developing countries 

to Sweden, 4 800 of them from India. From 1975 onwards 1 300-1 700 children arrived yearly, 

an average of 300 from India. 

Retrospective studies of the somatic development and social adaptation after arrival have been 

carried out (9, 11, 14). These studies have shown rapid initial catch-up growth and favourable 

development in general. 

However, it has been found that Indian adopted girls undergo earlier sexual maturation and 

in some cases attain shorter final height than Indian and Swedish girls (1, 16, 17). Menarcheal 

age was positively correlated to the age at arrival and to the velocity of catch-up growth (16, 17). 

79 



Final height was positively related to menarcheal age and to height at arrival (17). The pubertal 

growth component was found to be normal, lower final height being associated with a shortened 

childhood growth phase due to early pubertal onset, as well as to lower height before onset of 

puberty (18). 

These studies indicate that the later growth and development of adopted children is influenced 

by their conditions before adoption as well as during the initial period after arrival in Sweden. 

A longitudinal prospective study can add information not obtainable by retrospective 

investigations. Limitation of the study population to children adopted from one country enables 

comparison with national data. 

The aim of the present study was to follow a group of adopted children from their arrival in 

Sweden and during the following 2 years, in order to record their growth, development and 

clinical condition, and to relate these parameters to sex, conditions before adoption, and to age, 

health and nutritional status at arrival. 

This paper describes the environment of the adopted children in India and Sweden, discusses 

the certainty of the age data and describes the anthropometric and clinical condition at arrival in 

Sweden. 

MATERIAL AND METHODS 
The parents of 132 children were invited to take part in the study, upon the arrival of the children 

in Sweden. They were consecutively recruited through 5 adoption organizations: the Adoption 

Centre (AC), the Children Above All-Adoptions (BFA), the Indo-Swedish Association for 

Intercountry Adoptions (ISIA), the Family Association for International Adoptions (FFIA), and 

the Swedish Association for Adopted Children's Welfare (SAW). The parents of 114 children 

(86%) were willing to take part. The rest answered that they were unable to participate. 

Due to the sensitivity of the issue of adoption experienced by many parents, the authors were 

advised by the adoption organizations neither to encourage enlistment in the study too insistently, 

nor to demand specification of the reason for non-participation. 

The adoptive parents answered a questionnaire regarding their child's social and health 

conditions in India, and also about their own age and education and the number of their previous 

biological and/or adopted children. The doctor carrying out the first health examination was 

supplied with a standardized examination form. The subsequent examinations during the 2 years 

of follow up were also standardized, and will be described in detail in a subsequent paper. The 

data collection started in 1985. 

80 



Telephone contact with the parents was taken when necessary. The parents were offered 

medical advice regarding their children when needed. The parents' informed consent for data 

processing was obtained. 

Anthropometric measurements were carried out according to routines used in Swedish child 

health practice. 

The anthropometric data are expressed in standard deviation scores (SDS) according to the 

method recommended by WHO, using the reference data from the National Center for Health 

Statistics (NCHS) (15, 26, 27). The NCHS reference data are also applicable to Indian children 

(2, 25). When analyzing anthropometric data in relation to age at arrival, the age groups 

recommended by WHO were applied whenever possible. The calculation of standard deviation 

scores (SDS) for the anthropometric indices heighvage, weighdage, weighuheight and head 

circumference/age was done according to the procedure recommended by WHO (15, 26): 

Individual's value - median value of reference population 
Standard deviation value of reference population 

SDS =--------------------------------------------------------------------------------------------- 

The CDC Anthropometric Software Package (13) based on the NCHS reference 

population was used for the SDS calculations. 

According to WHO recommendations malnutrition was classified as "stunting" for height/age 

<-2 SDS, and as "wasting" for weight/height <-2 SDS (15, 26, 27). 

Psychomotor development was related to accepted standards (12). 

Statistical analysis using Student's t-test, bivariate linear regression, calculation of Pearson's 

correlation coefficient and non-parametric analysis of variance (Kruskal-Wallis test) were carried 

out using the SAS System (19, 20 21). 

When not otherwise stated, percentages are calculated on the total material of 114 children. 

RESULTS 
Environment in India and Sweden. The age at arrival and the sex distribution is seen in Table 1. 
The median age at amval was 9.3 months, 62% being below 1 year and 81 % below 2 years. The 

age ranged from 3-72 months. The girls dominated (60%). 

6 - 928571 81 



Table 1. A g e  at arrival 

Age at arrival BOYS Girls Total 
(months) n n n % 

- 11 31 40 71 62.2 
12 - 23 8 13 21 18.4 
24 - 35 2 9 11 9.7 
36 - 5 6 11 9.7 , 
Total n 46 68 114 100.0 ' 

% 40.4 59.6 100 
Mean age (months) 14.3 15.8 15.2 
Median age (months) 8.6 9.5 9.3 
Range (months) 3-62 3-72 3-72 

Most of the children were born in or near big cities (Calcutta 33%, Bombay 15%, Nagpur 

15% and Madras 9%). The remaining came from all over India. 

Information regarding one or both biological parents was available for 52 children. For 45 of 

these only the mother was known. Four of these 45 mothers had died and all the remaining lacked 

social support in various ways, e.g. they were unmarried, abandoned or widows. Six children had 

living married parents. In one case, only the father was known. 

For the majority (62%) the first institutional contact eventually leading to adoption was with 

a children's home, to which the children were brought by parents or relatives. Eighteen percent 

were born or left in a hospital and later transferred to a foster home or children's home. Fourteen 

percent of the children were foundlings, e.g. abandoned in the street. 

Most of the children (77%) were adopted from children's homes. Twenty-two percent came 

from foster homes, and 1% from a hospital. 

For 36 children (32 %) information regarding the previous medical history was available. This 

could refer to the period just before departure or earlier. The adoptive parents reported a 

summary of this information. Ten of the 36 children were reported to have had protein energy 

malnutrition, 11 acute respiratory infections, 9 diarrhoeal disease and 5 anaemia. A range of other 

diseases was also reported for a few or single cases: intestinal parasites, urinary, ear, eye and skin 
infections, hepatitis B, tuberculosis, vitamin A deficiency and rectal prolapse. Most children had 

more than one disease. 

The adoptive families were located all over Sweden, in both rural and urban areas. There 

were 112 families in all, consisting of 108 couples and four single mothers. All the 108 adoptive 

couples were married. Two couples adopted 2 children each, the rest of the families adopted 

1 child. 

82 



The mean age of the fathers (n=108) was 36 years (range 25-48 years) and that of the 

mothers (n= 112) was 35 years (range 25-50 years). Eighteen mothers were 40 years or older. 
For 7 of these mothers the adopted child was the first child. 

Forty-seven percent (51/108) of the fathers and 49% (55/112) of the mothers were first time 

parents. The 4 single mothers were among these. The mean age of the first time fathers was 

34 years (range 25-48), and of the first time mothers 33 years (range 25-44). 

Nine families had previous biological children (7 families had 1 child and 2 families had 

2 children). Three of these families also had previously adopted children. 

Fifty-one families had previously adopted children (48 families had one child and 3 families 

had 2 children). Eighty percent (43/54) of the previously adopted children came from India, the 

others from Sri Lanka, Indonesia, Thailand, Bolivia, Chile and Sweden. 
Socio-economic classification of the adoptive parents has been carried out according to the 

method based on occupational categories developed by Statistics Sweden (23). Compared with 

Swedish figures for 1986 of classification of parents, the distribution of socio-economic classes 

was similar among the adoptive parents, except that no unemployed or unclassifiable parents were 

found among the adoptive parents (Table 2) (6). 

Table 2 .  Classification of adoptive families ( n  = 112) 
Study population Swedish families with 

children 1986 (6) 
n % % 

HOMOGENEOUS FAMILIES~ 

A. 

B. 

C. 

Workers or assistant 

Intermediate non-manual 
employees, professionals 
or executives 35 31 
Self-employed (other 

non-manual employees 39 35 

than professionals) 1 1 

NON-HOMOGENEOUS FAMILIES 

One parent group A, the 
other group B 

One parent group C, the 
other any other occupation 

 OTHER^ 

24 21 

13 12 

33 

29 

4 

19 

5 

10 
~ 

TOTAL 112 100 100 
i.e. both parents belong to the same occupational group 
unemployed or unclassifiable 

83 



Certainty of the cbildren's age. The childrens' age was based on official documents issued by 
medical and civil authorities in India. Additional information was sometimes available from 

medical or other personnel at institutions where the children were cared for. The degree of 

certainty of the age was based on the information given to the adoptive parents as well as on the 
judgement of the doctor carrying out the first health examination after arrival. Based on this the 
age data of 54% were classified as "certain", 33% as "fairly certain" and 9% as "uncertain". 

Anthropometric evaluation. The majority (75 %) of the first examinations after arrival were carried 

out within 1 week, and 86% within 2 weeks. Sixty-four percent of the examinations were carried 

out at pediatric clinics, 26% at infectious diseases clinics, and 10% at other clinics. 

Figure 1 and Table 3 show the distribution and the means of the weightlage, height/age and 

the head circumferencehge. 

-2 S.D. 
1 

B 3 6 9 1 2  18 2 3 L 5 6 7 8  
months years 

Figure 1 .  Head circumference (triangles), height (squares) and weight (dots) at arrival for the 
adopted boys and girls, in relation to the NCHS reference (median and +/- 2 SD indicated). 

The mean values for weightJage, heightlage and head circumference/age were about -2 SDS, 

but with great variation. The mean weightlheight was approximately -1 SDS. Many children 

showed extremely low values, particularly among the young infants and the older children. 

84 



Table 4 shows the rate of stunting and wasting according to the definitions used; 47% were 

stunted, 1.8% wasted and 6.4% showed a combination of both conditions. There were no 

significant sex differences. 

The age distribution of the anthropometric variables and the nutritional status are seen in Tables 

5 and 6. The children in the age groups 0-5 months and 218 months had the lowest weight/age 

and heighuage. Analysis of variance (Kruskal-Wallis test) showed significant differences between 

the means of the age groups for heighuage and for weighuage, while for weight/height and head 

circumference/age there were no significant variations. Six of the 7 children with both stunting 

and wasting were found in the oldest age group. 

Table 3. Anthropometry at arrival 

Boys (n=46) Girls (n=68) Total (n=114) 

WEIGHT/age 

mean SDS 
range SDS 
n 
% <-2 SDS 
% <-3 SDS 

HEIGHT/age 

mean SDS 
range SDS 
n 
% <-2 SDS 
% <-3 SDS 

WEIGHTlHEIGHT 

mean SDS 
range SDS 
n 
% < -2 SDS 
% < - 3  SDS 

-2.06 

45 
49 
27 

(-4.02)- (-0.26) 

-2.08 

45 
51 
22 

(-5.26)-(+O. 14) 

-0.84 

45 
9 
0 

(-2.82)-(+0.90) 

HEAD CIRCUMFERENCE/age 

mean SDS -1.83 
range SDS (-3.91)- (-0.17) 
n 34 
% <-2 SDS 44 
% < - 3  SDS 9 

-2.38 
(-5.21)- (-0.14) 

66 
67 
24 

-2.33 
(-6.20)- ( + 0.90) 

66 
56 
27 

-1.02 

64 
8 
0 

(-2.27)-(+0.91) 

-2.07 

59 
54 
15 

(-4.62)-(+0.84) 

-2.25 

111 
60 
25 

(-5.21)- (-0.14) 

-2.23 

111 
54 
25 

(-6.20)-( +0.90) 

-0.94 

109 
8 
0 

(-2.82)-( +0.91) 

-1.98 

93 
51 
13 

(-4.62)-( + 0.84) 

85 



Table 4. Distribution of stunting and wasting (n=109) 

Normal Stunted Wasted Stunted & Total 

n %  n %  n %  n %  n % 
wasted 

Boys 21 46.7 20 44.4 1 2.2 3 6.7 45 100.0 
Girls 28 43.7 31 48.4 1 1.6 4 6.3 64 100.0 

All 
children 49 45.0 51 46.8 2 1.8 7 6.4 109 100.0 

Table 5. 
height/age, weight/heighf and head circurnference/age. 

Mean SDS values on arrival for all children for the various age groups, f o r  weight/age, 

Weightiage Heightiage Weightlheight Head circ/age 
n SDS n SDS n SDS n SDS 

0-5 22 -2.39 22 -2.61 20 -0.62 18 -1.88 
6-11 48 -2.13 48 -1.83 48 -0.91 41 -1.85 
12-17 13 -1.74 13 -1.75 13 -0.86 11 -1.88 
18- 28 -2.58 28 -2.84 28 -1.26 23 -2.35 

KRUSKAL- WALLIS 
TEST' p < 0.05 p < 0.01 NS 
' non-parametric analysis of variance (20), 5 % significance level 

NS 

Table 6. Age distribution o f  nutritional status ( n = 1 0 9 )  

Normal Stunted Wasted Stunted & Total 
Age wasted 
(months) n % n %  n %  n %  n % 

0-5 7 35.0 12 60.0 1 5.0 0 0 20 100.0 
6-11 25 52.0 21 43.8 1 2.1 1 2.1 48 100.0 
12-17 8 61.5 5 38.5 0 0  0 0 13 100.0 
2 18 9 32.1 13 46.5 0 0  6 21.4 28 100.0 

86 



There were birth weight data for 37 children (19 boys and 18 girls). Eighty-one percent 

(30/37) had a birth weight below 2 500 g. At arrival in Sweden 17 were < 6  months of age, 

19 were 6-17 months of age and 1 218 months of age. Sixty-five percent (24137) were stunted 

and 8.6% (3/35) were wasted. There was no sex difference regarding weight/age, height/age and 
weight/height at arrival, and therefore the sexes were combined into one group. Linear regression 

analysis showed that birth weight correlated significantly with weighdage at arrival (p < 0.001, 
r=0.38) and height/age at arrival (p<O.001, r=O.36), but not significantly with weight/height 

at arrival). 

Clinical examination. The clinical assessment after arrival showed that 54% had pathological 

findings, most commonly malnutrition (as judged clinically) (45 %), acute respiratory infections 

(8.8%), diarrhoea (4.4%), molluscum contagiosum (8.3%), scabies (9.7%), otitis media or 

otosalpingitis (15%), external otitis (3.7%) and throat infections (4,4%). Frequently the same 

child had several pathological findings. 

Anaemia (B-haemoglobin C 100 g/L) (5) was found in 15 % , elevated ESR ( ~ 2 0  mm/h) in 
26%, leucocytosis (215 x 109/1) in 40%, abnormal differential count (mainly lymphocytosis and 

eosinophilia) in 60%. HBsAg was positive in 8.3%. The stools were abnormal in 44%, with 

bacterial, parasitic or combined infections (Table 7). 

Table 7. Results of the stool examination of the children in "the 2-year study" ( n = 1 1 2 - 1 1 3 ) ,  at arrival 
in Sweden. 

Diagnosis' % 

Salmonella 15.9 
Giardia lamblia 13.3 
Trichuris trichiura 9.7 
Campylobacter 7.1 
Ascaris 6.2 
Strongyloides stercoralis 4.4 
Ancylostoma duodenale 3.5 
Hymenolepis nana 3.5 
S higella 1.8 
E. histolytica 1.8 

one child may have several infections 

87 



Of 108 children assessed regarding their psychomotor development, 29% were found to be 

retarded according to accepted development standards (12). 

Psychomotor retardation occurred mainly among the stunted children (47%), compared with 

7.8% in the non-stunted group. Corresponding figures for anaemia were 23% and 4.0%, 

respectively. 

Twenty five percent (28/111) of the children (27% of the boys and 24% of the girls) had 

weight/age < -3 SDS. This indicator was selected since it reflects both height for age and weight 
for height (27). The majority of those with height for age <-3 SDS and 5 of the 9 with weight 
for height < -2 SDS, were found in this group. Retarded psychomotor development was more 
common (54% compared to 21 % among the rest). Anaemia was also more frequent. Otherwise 

there were no clear differences regarding disease frequencies (Table 8). 

Table 8. Characteristics of children with w e i g h t / a g e  (-3 S D S  compared with those 2-3 S D S  

weight/age < -3 SDS weight/age 2 3  SDS 
(n=24-28) (n =72-83) 
n % n % 

Height/age <-3 SDS 
Weightlheight < -2 SDS 
Anaemia (B-Hb < 100 g/L) 
HBsAg positives 
Salmonella 
S higella 
Campylobacter 
E. histolytica 
Giardia lamblia 
Ascaris 
Trichuris trichiura 
Acute respiratory infection 
Diarrhoeal disease 
Urinary tract infection 
Scabies 
Conjunctivitis 
Throat infections 
Otitis 
Tuberculosis 
Retarded psychomotor 
development 

21 75 
5 19 
6 21 
3 12 
5 18 
2 7 
2 7 
0 0 
4 14 
2 7 
4 14 
0 0 
2 7 
1 4 
3 11 
0 0 
0 0 
4 14 
1 3 

14 54 

7 8 
4 5 

10 12 
5 6 

13 16 
0 0 
6 7 
2 2 

10 12 
5 6 
7 9 

11 13 
3 4 
1 1 
8 10 
2 2 
4 5 

13 16 
0 0 

17 21 

88 



DISCUSSION 

The study population was recruited consecutively during a certain period. The age and sex 

distributions in the studied population were very similar to those of all Indian children adopted 

in Sweden during the recruitment period. The 5 major Swedish adoption organizations 

undertaking adoptions of children from India were included. Therefore the study population could 

be considered as representative for Indian children adopted in Sweden during the period 

mentioned. 

There is no reason to believe that the defaulting 18 children were different from those in the 

study population. 

As many as 87% of the children were estimated as having a "certain" or "fairly certain" age. 

This seems reasonable since the majority of the children were very young at arrival, and it is 

easier to obtain reliable birth data for younger children. Furthermore, the margin of error in age 

estimation is naturally less the younger the child. 

The adoptive families were selected to provide a good emotional and social environment to 

the children. 

The majority of the children with known background came initially from socially deprived 

situations. The children's homes and foster homes, from which most of the children were 

adopted, were as a rule well-ordered but certainly not affluent. It is therefore not surprising to 

find that the diseases in India, as well as at arrival, corresponded to those usually found in 

developing countries. Moreover the anthropometric indices were similar to those of an average 

Indian population, characterized by chronic malnutrition among a considerable proportion of the 

children (3, 8, 22). Similar findings are reported also from earlier studies of children adopted 

from developing countries. The relatively high prevalence of psychomotor retardation has likewise 

been noted earlier. (9, 14). 

The mean weight and height for age at arrival were approximately 2 SDS lower than for 

affluent Indian children (2, 2 5 )  but were similar to Indian national average data which included 

also less privileged children (8). The distribution of wasting and stunting was similar to that found 

in India except for a higher percentage of combined wasting and stunting (Table 4) ( 2 2 ) .  

No significant differences regarding anthropometry were found between the sexes, which is 

in accordance with the findings of Sastry et al. ( 2 2 ) .  

In our study population there were data on birth weight for only 37 children. The sub-sample 

is naturally limited to children delivered in an institution where birth weight is recorded. As many 

as 30 (81 %) had low birth weight ( < 2  500 8). The Indian low birth weight average is 30% ( 2 4 ) ,  

with a wide range depending on socio-economic conditions (7). Our sub-sample is probably 

biased, including many socially deprived mothers. Malnutrition and pregnancy complications may 

6 t-928571 .s9 



have caused these mothers to deliver in a hospital or similar health service, thereby enabling the 

birth weight to be recorded. 

Birth weight has been found to predict weight and height in early childhood (4, 10). The high 

proportion of stunting seen already in the children who were youngest at arrival (0-5 months) fits 

with the high percentage of low birth weight in this group (Table 6). Our study sample of 

37 children showed significant positive correlations between birth weight, and height as well as 

weight at arrival, confirming the studies mentioned above. 

The low height/age in the youngest age group (Table 5 )  indicates that stunting may have been 

present already before birth. The lower rate of stunting in the age group 6-17 months may be due 

to mortality selection of the weakest and to nutritional catch-up in the survivors. The high rate 

of stunting seen in the oldest children conforms to rates found in India (22). 

The wide ranges of the anthropometric indices at arrival (Table 3) probably reflect the 

differences in the children's pre-adoptive environment, of which we only have limited knowledge. 

The stunted children showed a high rate of anaemia and psychomotor retardation. The children 

with very low weight for age (a group which contained many of the most severely stunted and/or 
wasted) also included a high proportion of children with psychomotor retardation and anaemia. 

Stunted and very low weight children should be regarded as risk groups and routinely be given 

a more prolonged and intensive follow up after arrival. 

ACKNOWLEDGEMENTS 

The authors wish to thank the adoptive parents and their children for their participation and 
interest in the study. We also thank the adoption organizations mentioned above (AC, BFA, ISIA, 
FFIA and SAW) for their co-operation. Moreover we are grateful to Kerstin Goransson of the 
Uppsala University Data Centre for her help with the data processing and to Professor Gunnar 
Eklund, the Karolinska Institute, Stockholm and Tore Lundstrom of the Regional Oncologic 
Centre, the UppsaldOrebro Health Care region, for their statistical advice. The study was 
supported by grants from the Swedish Council for Social Research (SFR), Stockholm, and from 
Uppsala University. 

REFERENCES 

1. 

2. 

3. 

4. 

90 

Adolfsson, S . ,  & Westphal, 0.: Early pubertal development in girls adopted from Far- 
Eastern countries. Pediatr Res 15:82, 1981. 
Aganval, K.N., et al.: Growth performance of affluent Indian children (under-fives). 
Growth Standard for Indian children. Nutrition Foundation of India. Sci Report 11, 1991. 
Banik, N.D.: quoted in: Eveleth, P.B. & Tanner, J.M.: Worldwide variation in human 
growth. Cambridge Univ Press, 1976. 
Binkin, N.J., Yip, R., Fleshood, L. & Trowbridge, F.L.: Birth weight and childhood 
growth. Pediatrics 6:828-834, 1988. 



5. 

6. 
7. 

8. 

9. 

10. 

11. 

12. 
13. 

14. 

15. 

16. 

17. 

18. 

19. 

20. 

21. 

22. 

23. 

24. 
25. 

26. 

27. 

Fernlund, P., Fex, G., Hanson, A. Stenflo, J. & Lundh, B.: Laurells Klinisk kemi i 
Praktisk Medicin. Sjatte upplagan. Studentlitteratur, Lund, 1991. 
Gellerstedt, L.: Kvinnor, man och barn i klasstrukturen. Valfardsbulletinen 2: 18-21, 1989. 
Gopalan, C.: Women and nutrition in India. Some practical considerations. Bull Nutr 
Found of India, 4: 1-4, 1989. 
Growth and physical development of Indian infants and children. Indian Council of Medical 
Research, ICMR, Tech Rep Ser No. 18, New Dehli, 1972. 
Gunnarby, A., Hofvander, Y., Sundelin, C. & Sjolin, S.: Utlandska adoptivbarns 
halsotillstand och anpassning till svenska forhallanden. Lakartidningen 79; 1679-1705, 
1982. 
Hofvander, Y.: International comparisons of postnatal growth of low birth weight infants 
with special reference to differences between developing and affluent countries. Acta 
Paediatr Scand Suppl 296, 1982. 
Hofvander, Y. & Sundelin, C.: Transnational adoptions. In: Advances in international 
maternal and child health. Vol 2. (eds. D.B. Jelliffe & E.F.T. Jelliffe), pp. 111-116, 
Oxford University Press, Oxford, 1982. 
Illingworth, R.S. : The normal child. Churchill Livingstone, Edinburgh, 1979. 
Jordan, M.D.: the CDC Anthropometric Software Package. Version 3.0. Tutorial guide and 
handbook. Anthropometric analysis software based on the CDC Standard Deviation-Derived 
Growth Reference Curves Derived from NCHSKDC Reference Population. The Centers 
for Disease Control, Center for Health Promotion and Eduvation, Division of Nutrition, 
Statistics Branch, 1600 Clifton Road, Atlanta, Georgia 30333, 1986. 
Magnusson, B. & Proos, L.: Vikt- och langdutveckling hos adoptivbam frin u-lander. 
Lakartidningen 76:3192-3 193, 1979. 
Measuring change in nutritional status. Guidelines for assessing the nutritional impact of 
supplementary feeding programmes for vulnerable groups. World Health Organization, 
Geneva, 1983. 
Proos, L.A., Hofvander, Y. & Tuvemo, T.: Menarcheal age and growth pattern of Indian 
girls adopted in Sweden. I. Menarcheal age. Acta Paediatr Scand 80:852-858, 1991. 
Proos, L.A., Hofvander, Y. & Tuvemo, T.: Menarcheal age and growth pattern of Indian 
girls adopted in Sweden. 11. Catch-up growth and final height. Indian J Pediatr 58: 105-1 14, 
1991. 
Proos, L.A., Karlberg, J., Hofvander, Y. & Tuvemo, T.: Pubertal growth of Indian girls 
adopted in Sweden. Submitted to Acta Paediatr Scand. 
SAS Institute Inc. SAS Language Guide for Personal Computers, Version 6.03 Edition. 
SAS Institute Inc., Cary, NC, 1988, 
SAS Institute Inc. SAWSTAT Guide for Personal Computers. Version 6 Edition. SAS 
Institute Inc., Cary, NC, 1987. 
SAS Institute Inc. SAS Procedures Guide for Personal Computers, Version 6.03. SAS 
Institute Inc., Cary, NC, 1988. 
Sastry, J.G., Vijayaraghavan, K. & Rao, N.P.: Indian preschool children - a profile on 
stunting and wasting. J Trop Pediatr, 5:237-240, 1989. 
Swedish socio-economic classification. Statistics Sweden. Report on Statistical Co- 
ordination, 4, 1982. 
The state of the world's children 1992. UNICEF. Oxford University Press, Oxford, 1992. 
Vijayaraghavan, K., Singh, D. & Swaminathan, M.C.: Heights and weights of well- 
nourished Indian school children. Indian J Med Res 59548-654, 1971. 
Waterlow, J.C., Buzina, R., Keller, W., Lane, J.M., Nichaman, M.Z. & Tanner, J.M.: 
The presentation and use of height and weight data for comparing the nutritional status of 
groups of children under the age of 10 years. Bull Worlds Health Organ 55:489-498, 1977. 
WHO Working Group. Use and interpretation of anthropometric indicators of nutritional 
status. Bull World Health Organ 64:929-941, 1986. 

7 - 928571 91 



Address for reprints: Dr Lemm A.Proos 
International Child Health Unit 
Department of Pediatrics 
Uppsala University Children's Hospital 

Sweden 
S-751 85 UPPSALA 

92