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01.12.2011 | Research article | Ausgabe 1/2011 Open Access

BMC Public Health 1/2011

Factors Influencing Receipt of Iron Supplementation by Young Children and their Mothers in Rural India: Local and National Cross-Sectional Studies

Zeitschrift:
BMC Public Health > Ausgabe 1/2011
Autoren:
Sant-Rayn Pasricha, Beverley-Ann Biggs, NS Prashanth, H Sudarshan, Rob Moodie, Jim Black, Arun Shet
Wichtige Hinweise

Competing interests

The authors declare that they have no competing interests.

Authors' contributions

SP, BA-B, JB, and AS planned the study and prepared the manuscript. SP and AS led the fieldwork. SP, BA-B and JB analysed the data. All authors conceived the study, read and approved the final manuscript.

Background

In India, approximately 55% of women of reproductive age and 69.5% of under-5 children are anaemic [1], and in children, over 70% of anaemia is attributable to iron deficiency [2]. Iron deficiency anaemia in mothers may be associated with an increased risk of maternal mortality, preterm delivery, and low birth weight [3]; and in children with reduced cognitive development [4]. Thus, anaemia is a major public health concern in India.
The Indian National Nutritional Anaemia Prophylaxis Programme recommends that all children aged 6 to 59 months, and all pregnant and lactating women, receive Iron Folic-Acid (IFA) [5]. Despite this policy, the prevalence of anaemia among toddlers aged 6-36 months has risen from 74.3% in 1998-9 to 78.9% in 2005-6 [1]. The third National Family Health Study (NFHS-3) examined receipt of iron and found that only 4.7% of children in India aged 6-59 months were receiving supplementation [1]. Several previous, local studies have also suggested that distribution of iron in India is poor [6, 7].
An improved understanding of the coverage of and factors associated with receipt of iron supplements by mothers and children in India could inform efforts to strengthen and better direct iron delivery programmes, especially in rural India. We hypothesised that receipt of iron supplementation to children in India is poor, and is associated with socioeconomic conditions and access to health care. To test this hypothesis and better understand factors associated with the receipt of iron supplementation among children in rural India, we conducted two analyses. 1) In two districts of rural Karnataka (the 'Karnataka Study'), we undertook a cross-sectional study to evaluate the receipt of iron to young children and their mothers, and identify factors at the socioeconomic, demographic and health-care delivery levels that may contribute to disparities in receipt of supplementation. 2) We analysed data obtained from the third National Family Health Study (NFHS-3) performed across India, to evaluate factors associated with delivery of iron to children and their mothers throughout rural India.

Methods

The Karnataka Study

The study was performed between August and October 2008. A detailed description of the methodology of this study has been previously published [8].

Study site and participants

The study was based in two rural Primary Health Centres (PHCs) in southern Karnataka. The Gumballi PHC, in Chamarajnagar district, the southernmost district of Karnataka, is 180 km south of Bangalore, and provides care for about 21,700 people in 13 villages. The Sugganahalli PHC is 90 km west of Bangalore in the Ramnagara district, and provides care for 14,400 people in approximately 80 villages [9]. Agriculture comprises the major economic activity in both regions. The average rural income in Chamarajnagar in 2006 was (Indian rupees) Rs 22,006 per capita, in Ramnagara was Rs 26,009 [10], as compared with Karnataka overall Rs 26,123 [11]. In the 2011 Indian census, the Ramanagara district had a population of 1,082,739 and a literacy rate of 69.2%; Chamarajnagar had a population of 1,020,962 with a literacy rate of 61.1% [12].
The sampling design was developed to be acceptable to the local population and the Non-Government Organisation managing the PHCs. Three of four sub-centres managed by each PHC were randomly selected for involvement in the study [13]. All children aged 12 to 23 months living in the villages served by the selected sub-centres (enumerated by a compilation of local lists and a house to house survey), and their mothers, were eligible for inclusion in the study, unless children were unwell or febrile, or had ever received a previous blood transfusion (as this was part of a larger study investigating the determinants of anaemia in this population). Field workers visited each eligible village on a pre-publicised day and administered the questionnaire to and collected blood samples from all mothers of children living in the site who were eligible for recruitment. If the child presented with a guardian who was not their mother (for example, a grandmother, sibling or aunt), maternal blood samples and details of pregnancy were not obtained.

Study Procedures

The questionnaire evaluated demographics (religion and caste, age of mother and child, sex of child, education level and literacy of mother). A wealth index adapted from the NFHS-3 was also used, in which household assets are assigned a weighted score [14]. Subjects were allocated to wealth quintiles based on this score. Delivery of important maternal (antenatal and postnatal health worker visits) and child (vaccinations, vitamin A supplementation) primary health services were recorded, as was use of available resources including whether the child had ever visited an Anganwadi (Integrated Child Development Scheme) centre. Receipt of antenatal and postnatal iron supplementation by the mother was evaluated: mothers were shown bottles (liquid formulations) and strips (tablets) of iron supplements and asked to recall if they had received these. Mothers were also asked to recall whether their child had ever received iron, and if so, the source. The questionnaire is available online [8]. The field team was trained in administration of the questionnaire; all completed questionnaires were reviewed for errors, and cross-checked between interviewers.
Venous blood was collected from children for evaluation of haemoglobin (Sysmex XT-2000i, Sysmex Inc., Kobe, Japan) and capillary blood haemoglobin was estimated in their mothers by HemoCue (HemoCue 201+, Angelholm, Sweden). Anaemia in children was defined as haemoglobin < 11 g/dL, and in women as < 12 g/dL (11 g/dL if pregnant) [15].

Third National Family Health Study

The NFHS-3 (performed in 2005-6 by the International Institute for Population Sciences (Mumbai, India) and ICF Macro (Washington DC, USA)) surveyed women aged 15-49 years and their children aged 0-59 months across all 29 Indian states. Respondents were selected through a multistage cluster-based survey stratified by urban and rural populations. Only rural families were included in our analysis. The rural sample was obtained through a selection of villages based on the probability proportional to size principle, followed by random selection of households [16]. The questionnaire recorded whether children were currently receiving iron and whether their mothers had received iron during their most recent pregnancy [17]. It also recorded child's age, sex, birth order, maternal education, family caste and religion, household wealth index, and health care practices.

Statistical Considerations

Data from the Karnataka Study were entered into an EpiInfo database (EpiInfo 3.4.3, Centers for Disease Control and Prevention, Atlanta, USA) and exported to statistical software for analysis (Stata 11, StataCorp, College Station, Texas, USA). We calculated a sample size of 390 to ensure that the 95% confidence interval for an estimate of prevalence of 50% would have precision +/-5%. Significance for statistical tests was defined as p < 0.05. Associations with receipt of iron supplementation (a binary variable) were estimated using univariate and then multiple logistic regression. Wealth index and number of antenatal health worker visits were analysed as quintiles using dummy variables. The multiple regression models were fitted after forward stepwise logistic regression including all variables with retention of variables with p < 0.05. Each model was evaluated using likelihood ratio tests and confirmed using the Hosmer-Lemeshow goodness-of-fit test. T-tests were used to identify differences in continuous variables between groups.
NFHS-3 data was analysed with Stata 11 using the children's recode data (IAKR) file. Independent variables from the NFHS-3 questionnaire that reflected variables found to be associated with receipt of iron by mothers or children in the Karnataka Study were included in the analysis. Simple and multiple logistic regression models accounting for sample weights and the multistage cluster survey sampling design of the survey were used to identify associations with receipt of iron during pregnancy by the mother, or current receipt of iron by the child.

Ethics

The Karnataka study was approved by ethics committees of St John's National Academy of Health Sciences, Bangalore, India, and the Faculty of Medicine, Dentistry and Health Sciences, the University of Melbourne, Australia. Written informed consent was obtained from mothers or guardians of all participating children. The NFHS-3 had received approval from institutional review boards of the International Institute of Population Sciences, Mumbai, India and the ORC Macro, Calverton, Maryland, USA. Verbal informed consent was obtained from participating mothers by the interviewers [17].

Results

The Karnataka Study

Demographics and delivery of health services

We estimated that 470 children were living in the selected villages and thus potentially eligible for the study; 415 (88.3%) presented for screening [8], of which 10 were excluded: 7 due to fever and 3 due to previous transfusion. Thus, 405 children were recruited. The sample included two pairs of twins; mother and child data was adjusted to avoid duplication. Of 403 included children, 203 (50.3%) were male. The profile of the sampled population of mothers and children is presented in Table 1. We found that 63.1% of mothers and 75.3% of the children were anaemic [2].
Table 1
Demographic parameters of mothers and children
 
N
Mean [95% CI]
Median [range]
Prevalence n (% [95% CI])
Mother
Age1 (years)
376
23.2 [22.8, 23.6]
Years of education2
377
7 [0, 15]
Literate3
374
260 (69.5 [64.8, 74.2])
Wealth Index1
403
17.9 [16.7, 18.9]
Currently Pregnant3
374
45 (12.0 [8.7, 15.3])
Anaemic3,4
358
225 (62.8 [57.8, 67.9]
Child
Age1 (months)
401
17.2 [16.8, 17.5]
Male3
403
203 (50.4 [45.5, 55.3])
Birth order2
377
2 [1, 5]
Hindu, non Scheduled Caste3
390
209 (53.6 [48.6, 58.6])
Hindu, Scheduled Caste3
390
99 (25.4 [21.0, 29.7])
Scheduled Tribe3
390
61 (15.6 [12.0, 19.0])
Muslim3
390
21 (5.4 [3.1, 7.6])
Anaemic3,5
399
300 (75.2 [70.9, 79.4])
1 Mean [95% CI]
2 Median [range]
3 Prevalence n (% [95% CI])
4 Haemoglobin < 12 g/dL (non pregnant), <11 g/dL (pregnant)
5 Haemoglobin < 11 g/dL

Receipt of iron supplements

Delivery of health services to and receipt of iron by mothers and children is presented in Table 2. Less than half of the children, 167/402 (41.5% [36.7-46.4]) had ever received iron supplements. Only 45/393 (11.5% [8.3-14.6]) had ever received iron from a government source (PHC, sub-centre or Anganwadi centre). The majority - 113/158 (71.5% [64.4-78.6]) - of children who had received iron received it from a private rather than a government source. The wealth index of families of those children who received iron from private sources was higher than those who received it from a government source (21.1 points [19.1-23.1] versus 17.0 points [14.0-20.7] p = 0.034). Most of the mothers (92.0% [89.2-94.8]) reported receipt of iron supplements during pregnancy, although the majority (80.8%) received 40 or fewer tablets.
Table 2
Delivery of health services and anaemia prophylaxis to mothers and their children
 
N
n (% [95% CI])
Health Services Provided to Mother
Antenatal visits by health worker1
375
374 (99.7 [99.2, 100.0])
Had postnatal health worker visit
370
167 ([45.1 (40.4, 50.3])
Health Services Provided to Child
Vaccinations:
  
Birth
403
394 (97.8 [96.3, 99.2])
6 weeks
399
386 (96.7 [95.0, 98.5 ])
10 weeks
399
384 (96.2 [94.4, 98.1])
14 weeks
399
366 (91.7 [89.0, 94.4])
9 months
403
393 (97.5 [96.0, 99.0])
Fully vaccinated
403
359 (89.1 [86.0, 92.1])
Vitamin A supplementation received ever
403
403 (100.0%)
Child has ever visited:
  
Doctor
403
386 [95.8 (93.8, 97.8)]
Primary Health Centre
402
329 (81.8 [78.1, 85.6])
Anganwadi Centre
403
435 (85.6 [82.2, 89.1])
Maternal anaemia prophylaxis measures
Blood test during pregnancy
374
292 (78.1 [73.9, 82.3])
Iron supplementation during pregnancy
376
345 (91.7 [89.0, 94.6])
Dose of iron received
  
0 tablets
375
30 (8.0 [5.2, 10.7))
10-20 tablets
375
108 (28.8 [24.2, 33.4])
30-40 tablets
375
165 (44.0 [39.0, 49.1])
50-60 tablets
375
58 (15.5 [11.8, 19.1])
70-80 tablets
375
12 (3.2 [1.4, 5.0])
> 80 tablets
375
2 (0.5 [0.0, 1.3])
Iron supplementation post pregnancy
370
86 (23.2 [18.9, 27.6])
Children's anaemia prophylaxis measures
Child had received iron supplementation
402
167 (41.5 [36.7, 46.4])
Source of iron supplementation
  
Private doctor
161
91 (56.5 [48.8, 64.3])
Private shop
161
24 (14.9 [9.3, 20.5])
Primary Health Centre
161
35 (21.7 [15.3, 28.2])
Sub-centre health worker
161
8 (5.0 [1.6, 8.4])
Anganwadi worker
161
3 (1.9 [0.0, 4.0])
1 Median number of antenatal health worker visits 6 [range 0, 9]

Factors associated with receipt of iron supplements

Results of simple logistic regression analyses for factors associated with receipt of antenatal iron supplements by mothers are presented in Table 3 and results of multiple logistic regression analyses of these associations are shown in Table 4. Results of simple logistic regression analyses for factors associated with receipt of iron by children are presented in Table 5 and results of multiple logistic regression analyses of these associations are shown in Table 6.
Table 3
Factors associated with mother receiving iron supplementation during pregnancy (univariate logistic regression)
Factor
Total Population
Iron supplements received
(345/375)
Iron supplements not received (30/375)
 
p
 
N
Prevalence n (% [95% CI]), Mean [95% CI], or Median [Range]
N
Prevalence n (% [95% CI]), Mean [95% CI], or Median [Range]
N
Prevalence n (% [95% CI]), Mean [95% CI], or Median [Range]
Odds Ratio [95% CI] for receipt of iron
 
Wealth quintile 1, 4
        
Quintile 1
375
69 (18.4 [14.4, 22.4])
69
56 (81.2 [71.7, 90.6])
69
13 (18.8 [71.7, 90.6])
1.00 (Reference)
 
Quintile 2
375
66 (17.6 [13.7, 21.4])
66
61 (92.4 [85.9, 99.0])
66
5 (7.6 [1.0, 14.1])
2.83 [0.95, 8.45]
0.062
Quintile 3
375
86 (22.9 [18.7, 27.2])
86
80 (93.0 [87.5, 98.5])
86
6 (7.0 [1.5, 12.4])
2.65 [1.0, 7.07]
0.051
Quintile 4
375
75 (20.0 [15.9, 24.1])
75
75 (93.3 [87.6, 99.1])
75
5 (6.7 [0.9, 12.4])
3.25 [1.09, 9.66]
0.034
Quintile 5
375
79 (21.1 [16.9, 25.2])
79
78 (98.7 [96.2, 100.0])
79
1 (1.3 [0.0, 3.7])
18.57 [2.36, 146.06]
0.005
Mother's age (years) 2
374
23.2 [22.8, 23.6]
342
23.2 [22.8, 23.5]
31
23.9 [22.0, 25.8]
0.95 per year [0.87, 1.04]
0.275
Child's age (months) 2
401
17.2 [16.8, 17.5]
343
17.0 [16.7, 17.4]
31
17.8 [16.3, 19.2]
0.94 per month [0.84, 1.04]
0.251
Maternal Education 1
        
0
375
89 (23.7 [19.4, 28.1])
89
80 (89.9 [83.5, 96.3])
89
9 (10.1 [3.7, 16.5])
1.00 (Reference)
 
1-6 years
375
46 (12.3 [8.9, 15.6])
46
43 (93.5 [86.1, 100.0])
46
3 (6.5 [0, 13.9])
1.61 [0.42, 6.27]
0.491
7-9 years
375
117 (31.2 [26.5, 25.9])
117
107 (91.5 [86.3, 96.6])
107
10 (8.5 [3.4, 13.7])
1.20 [0.47, 3.10]
0.701
10 years
375
97 (25.9 [21.4, 30.3])
97
90 (92.8 [87.5, 98.0])
97
7 (7.2 [2.0, 12.5])
1.446 [0.52, 4.06]
0.484
11+ years
375
26 (6.9 [4.4, 9.5])
26
25 (96.2 [88.2, 100.0])
26
1 (3.8 [0, 11.8])
2.7 [0.33, 22.39]
0.358
Literate mother 1
373
259 (69.4 [64.7, 74.1])
259
241 (93.1 [89.9, 96.2])
259
18 (6.9 [3.8,10.1])
1.58 [0.73, 3.39]
0.245
Birth order 3
377
2 [1, 5]
344
2 [1, 5]
31
1 [1, 4]
0.90 [0.58, 1.41]
0.634
Religion/Caste 1
        
Hindu, non SC/ST 5
374
198 (52.9 [47.9, 58.0])
198
190 (96.0 [93.2, 98.7])
198
8 (4.0 [1.3, 6.8])
1.00 (Reference)
 
Scheduled Caste
374
97 (25.9 [21.5, 30.4])
97
85 (87.6 [81.0, 94.3])
97
12 (12.4 [5.7, 19.0])
0.30 [0.12, 0.76]
0.011
Scheduled Tribe
374
58 (15.6 [11.8, 19.2])
58
52 (89.7 [81.6, 97.7])
58
6 (10.3 [2.3, 18.4])
0.7 [0.12, 1.09]
0.073
Muslim
374
21 (5.6 [3.3, 8.0])
21
17 (81.0 [62.6, 99.3])
21
4 (19.1 [0.7, 37.4])
0.18 [0.05, 0.66]
0.009
Number of antenatal health worker visits 1,6
        
Quintile 1
374
69 (18.5 [14.5, 22.4])
69
57 (82.6 [73.4, 91.8])
69
12 (17.3 [8.2, 26.6])
Reference
 
Quintile 2
374
53 (14.2 [10.6, 17.7])
53
46 (86.8 [77.4, 96.2])
53
7 (13.2 [3.8, 22.6])
1.38 [0.50, 3.80]
0.529
Quintile 3
374
40 (10.7 [7.6, 13.8])
40
39 (97.5 [92.4, 100.0])
40
1 (2.5 [0.0, 7.6])
8.21 [1.02, 65.74]
0.047
Quintile 4
374
118 (31.6 [26.8, 36.3])
118
109 (92.3 [87.5, 97.2])
118
9 (7.6 [2.8, 12.5])
2.55 [1.01, 6.41]
0.047
Quintile 5
374
94 (25.1 [20.7, 29.6])
94
93 (98.9 [96.8, 100.0])
94
1 (1.1 [0.0, 3.2])
19.59 [2.48, 154.61]
0.005
Postnatal health worker visit 1
369
167 (45.3 [40.2, 50.4])
167
164 (98.2 [96.2, 100.0])
167
3 (1.8 [0.0, 3.8])
8.43 [2.51, 28.33]
0.001
Iron supplementation given post pregnancy 1
369
86 (23.3 [19.0, 27.6])
86
84 (97.7 [94.4, 100.0])
86
2 (2.3 [0.0, 5.6])
4.61 [1.08, 19.78]
0.040
Blood test during pregnancy 1
373
291 (78.0 [73.8, 82.2])
291
276 (94.9 [92.3, 97.4])
291
15 (5.2 [2.6, 7.7])
4.12 [1.92, 8.84]
< 0.001
1Prevalence: n (% [95% CI])
2Mean [95% CI]
3Median [range]
4Wealth index: Quintile 1: 2-8 Quintile 2: 9-12; Quintile 3: 13-18; Quintile 4: 19-26; Quintile 27-62.
5SC = Scheduled Caste, ST = Scheduled Tribe
6Number of antenatal health worker visits: Quintile 1: 1-3; Quintile 2: 4; Quintile 3: 5; Quintile 4: 6-7; Quintile 8-9.
Table 4
Factors associated with mother receiving iron supplementation during pregnancy (multiple logistic regression)
Factor
Odds Ratio [95% CI]
P
Postnatal health worker visit
9.57 [2.50, 36.58]
0.001
Wealth quintile 1
  
Quintile 1
1.00 (Reference)
 
Quintile 2
2.28 [0.61, 8.53]
0.223
Quintile 3
2.83 [0.84, 9.50]
0.093
Quintile 4
2.63 [0.71, 9.67]
0.146
Quintile 5
11.20 [1.17, 106.82]
0.036
Religion/Caste
  
Hindu, Non SC/ST 2
1.00 (Reference)
 
Scheduled Caste
0.32 [0.11, 0.96]
0.041
Scheduled Tribe
0.63 [0.18, 2.19]
0.468
Muslim
0.11 [0.02, 0.56]
0.008
Number of antenatal health worker visits 3
  
Quintile 1
1.00 (Reference)
 
Quintile 2
1.69 [0.51, 5.64]
0.394
Quintile 3
8.66 [0.93, 80.87]
0.058
Quintile 4
1.07 [0.35, 3.29]
0.908
Quintile 5
16.02 [1.83, 140.06]
0.012
Blood test during pregnancy
3.00 [1.19, 7.57]
0.020
1Wealth index: Quintile 1: 2-8 Quintile 2: 9-12; Quintile 3: 13-18; Quintile 4: 19-26; Quintile 27-62.
2SC = Scheduled Caste, ST = Scheduled Tribe
3Number of antenatal health worker visits: Quintile 1: 1-3; Quintile 2: 4; Quintile 3: 5; Quintile 4: 6-7; Quintile 8-9.
Table 5
Factors associated with child ever receiving iron supplementation (univariate logistic regression)
Factor
Total Population
Iron supplements received (345/375)
Iron supplements not received (30/375)
 
p
 
N
Prevalence n (% [95% CI]), Mean [95% CI], or Median [Range]
N
Prevalence n (% [95% CI]), Mean [95% CI], or Median [Range]
N
Prevalence n (% [95% CI]), Mean [95% CI], or Median [Range]
Odds Ratio [95% CI] for receipt of iron
 
Wealth quintile 1, 4
        
Quintile 1
402
77 (19.2 [15.3, 23.0])
77
24 (31.2 [20.6, 41.8])
77
53 (68.8 [58.3, 79.4])
Reference
 
Quintile 2
402
71 (17.7 [13.9, 21.4])
71
25 (35.2 [23.8, 46.6])
71
46 (64.8 [53.4, 76.2])
1.20 [0.61, 2.38]
0.602
Quintile 3
402
91 (22.6 [18.5, 26.7])
91
35 (38.5 [28.3, 48.6])
91
56 (61.5 [51.4, 71.7])
1.38 [0.73, 2.62]
0.324
Quintile 4
402
79 (19.7 [15.8, 23.6])
79
37 (46.8 [35.6, 58.1])
79
42 (53.2 [41.9, 64.4])
1.95 [1.01, 3.74]
0.046
Quintile 5
402
84 (20.9 [16.9, 24.9])
64
46 (54.8 [43.9, 65.6])
84
38 (45.2 [34.4, 56.1])
2.67 [1.40, 5.10]
0.003
Mother's age (years) 2
374
23.2 [22.8, 23.6]
161
23.1 [22.6, 23.6]
212
23.3 [22.8, 23.8]
0.98 per year [0.93, 1.04]
0.555
Child's age (months) 2
401
17.2 [16.8, 17.5]
165
17.0 [16.5, 17.5]
235
17.3 [16.8, 17.7]
0.98 per month [0.92, 1.04]
0.445
Maternal Education 1
        
0
374
89 (23.8 [19.5, 28.1])
89
31.5 [21.6, 41.3]
89
68.6 [58.7, 78.4]
1.00 (Reference)
 
1-6 years
374
45 (12.0 [8.7, 15.3])
45
53.3 [38.2, 68.5]
45
46.7 [31.5, 61.8]
2.49 [1.19, 5.20]
0.015
7-9 years
374
117 (31.3 [26.6, 36.0])
117
40.2 [31.2, 49.2]
117
59.8 [50.8, 68.8]
1.46 [0.82, 2.61]
0.199
10 years
374
98 (26.2 [21.7, 30.7])
98
48.0 [37.9, 58.0]
98
52.0 [42.0, 62.1]
2.01 [1.10, 3.65]
0.022
11+ years
374
25 (6.7 [4.1, 9.2])
25
60.0 [39.4, 80.6]
25
40.0 [19.4, 60.6]
3.27 [1.31, 8.17]
0.011
Literate mother 1
373
259 (69.4 [64.7, 74.1])
259
48.3 [42.1, 54.4]
259
51.7 [45.6, 58.9]
2.02 [1.27, 3.21]
0.003
Birth order 3
377
2 [1, 5]
161
2 [1, 5]
215
2 [1, 5]
0.91 [0.70, 1.19]
0.495
Religion/Caste 1
        
Hindu, non SC/ST 5
389
209 (53.7 [48.8, 58.7])
209
101 (48.3 [41.5, 55.2])
209
108 (51.7 [44.8, 58.5])
1.00 (Reference)
 
Scheduled Caste
389
99 (25.4 [21.1 29.8])
99
34 (34.3 [24.8, 43.9])
99
65 (65.7 [56.1, 75.2])
0.56 [0.34, 0.92])
0.022
Scheduled Tribe
389
61 (15.7 [12.1, 19.3])
61
25 (41.0 [28.3, 53.6])
61
36 (59.0 [46.3, 71.7])
0.74 [0.42, 1.32])
0.313.
Muslim
389
20 (5.1 [2.9, 7.4])
20
1 (5.0 [0.0, 15.5])
20
19 (95.0 [84.5, 100.0])
0.06 [0.01, 0.43])
0.005
Number of antenatal health worker visits 1. 6
        
Quintile 1
374
68 (18.2 [14.3, 22.1])
68
38 (55.9 [43.8, 68.0])
68
30 (44.1 [32.0, 56.2])
1.00 (Reference)
 
Quintile 2
374
53 (14.2 [10.6, 17.7])
53
15 (28.3 [15.8, 40.8])
53
38 (71.7 [59.2, 84.2])
0.31 [0.15, 0.67]
0.003
Quintile 3
374
40 (10.7 [7.6, 13.8])
40
18 (45.0 [28.9, 61.1])
40
22 (55.0 [38.9, 61.1])
0.65 [0.29, 1.41])
0.276
Quintile 4
374
118 (31.6 [26.8, 36.3])
118
63 (53.4 [44.3, 62.5])
118
55 (46.7 [37.4, 55.7])
0.90 [0.60, 1.65])
0.742
Quintile 5
374
95 (25.4 [21.0, 29.8])
95
26 (27.4 [18.2, 36.5])
95
69 (72.6 [63.5, 81.8])
0.30 [0.15, 0.57]
< 0.0001
Postnatal health worker visit 1
369
166 (45.0 [39.9, 50.1])
166
74 (44.6 [36.9, 52.2])
166
92 (55.4 [47.8, 63.1])
1.07 [0.71, 1.62]
0.740
Iron supplementation given post pregnancy 1
369
86 (23.3 [19.0, 27.6])
86
84 (97.7 [94.4, 100.0])
86
2 (2.3 [0.0, 5.6])
4.61 [1.08, 19.78]
0.040
Antenatal maternal iron supplementation 1
374
344 (92.0 [89.2, 94.7])
344
153 (44.5 [39.2, 49.8])
344
191 ((55.5 [50.3, 60.8])
2.20 [0.95, 5.08]
0.064
Postnatal maternal iron supplementation 1
369
85 (23.0 [18.7, 27.4])
85
54 (63.5 [53.1, 73.9])
85
31 (36.5 [26.0, 46.9])
2.88 [1.74, 4.76])
< 0.0001
Blood test during pregnancy 1
374
291 (78.0 [73.8, 82.2])
291
137 (47.1 [41.3, 52.8])
291
154 (52.9 [47.2, 58.7])
2.15 [1.27, 3.65]
0.005
Child's sex (male = 1) 1
402
203 (50.5 [45.6, 55.4])
203
103 (50.7 [43.8, 57.7])
203
100 (49.3 [42.3, 56.2])
2.17 [1.45, 3.26]
< 0.001
Services accessed ever
        
Doctor1
403
385 (95.7 [93.8, 97.5])
385
164 (42.6 [37.6, 47.6])
385
221 (57.4 [52.4, 62.4])
3.46 [0.98, 12.25]
0.054
Primary Health Centre1
402
328 (81.8 [78.0, 85.6])
328
138 (42.1 [36.7, 47.4])
328
190 (57.9 [52.6, 63.3])
1.10 [0.66, 1.84])
0.713
Anganwadi Centre1
402
345 (85.8 [82.4, 89.2])
345
124 (35.9 [30.8, 41.0])
345
221 (64.1 [59.0, 69.1])
0.18 [0.10, 0.35])
< 0.001
Child fully vaccinated1
402
359 (89.1 [86.0, 92.1])
358
136 (40.0 [32.9, 43.0])
358
222 (62.0 [57.0, 67.1])
0.6 [0.13, 0.51]
< 0.001
1Prevalence n (% [95% CI])
2Mean [95% CI]
3Median [range]
4Wealth index: Quintile 1: 2-8 Quintile 2: 9-12; Quintile 3: 13-18; Quintile 4: 19-26; Quintile 27-62.
5SC = Scheduled Caste, ST = Scheduled Tribe
6Number of antenatal health worker visits: Quintile 1: 1-3; Quintile 2: 4; Quintile 3: 5; Quintile 4: 6-7; Quintile 8-9.
Table 6
Factors associated with child ever receiving iron supplementation (multiple logistic regression)
Factor
Odds Ratio [95% CI]
P
Child's sex (male = 1)
2.45 [1.47, 4.10]
< 0.001
Wealth quintile 1
  
Quintile 1
1.00 (Reference)
 
Quintile 2
0.89 [0.37, 2.16]
0.797
Quintile 3
1.31 [0.59, 2.90]
0.504
Quintile 4
1.65 [0.71, 3.83]
0.242
Quintile 5
2.63 [1.11, 6.24]
0.028
Religion/Caste
  
Hindu, non SC/ST 2
1.00 (Reference)
 
Scheduled Caste
0.69 [0.38, 1.28]
0.240
Scheduled Tribe
0.90 [0.43, 1.77]
0.776
Muslim
0.02 [0.00, 0.27]
0.002
Number of antenatal health worker visits 3
  
Quintile 1
1.00 (Reference)
 
Quintile 2
0.25 [0.10, 0.61]
0.003
Quintile 3
0.54 [0.21, 1.40]
0.201
Quintile 4
0.78 [0.37, 1.63]
0.506
Quintile 5
0.25 [0.11, 0.55]
< 0.001
Visited Anganwadi
0.23 [0.11, 0.49]
< 0.001
Child fully vaccinated
0.33 [0.15, 0.75]
0.008
Postnatal maternal iron supplementation
2.31 [1.25, 4.28]
0.008
Maternal blood test during pregnancy
2.10 [1.09, 4.03]
0.026
1Wealth index: Quintile 1: 2-8 Quintile 2: 9-12; Quintile 3: 13-18; Quintile 4: 19-26; Quintile 27-62.
2SC = Scheduled Caste, ST = Scheduled Tribe
3Number of antenatal health worker visits: Quintile 1: 1-3; Quintile 2: 4; Quintile 3: 5; Quintile 4: 6-7; Quintile 8-9.
No association was identified between anaemia in children and receipt of iron by either the child or their mother (for receipt of iron ever by children odds ratio (OR) 0.80 [0.51-1.27]; for receipt of any antenatal iron by mothers OR 1.97 [0.89-4.34]). Similarly, there was no association between anaemia in mothers and receipt of either antenatal or postnatal iron (receipt of any antenatal iron OR 1.10 [0.51-2.44], receipt of any postnatal iron OR 0.95 [0.57-1.60]).

Third National Family Health Study

The dataset included 51,555 children and 36,850 of their mothers, of which 29,706 children and 20,631 mothers were coded as living in rural areas. Nationally, 4.6% [4.3-5.0] of all children were receiving iron at the time of interview: urban children were more likely to be receiving iron (7.0% [6.1-7.8]) than rural children (3.7% [3.3-4.1]) (OR for rural 0.55 [0.47-0.64], P < 0.001). Of mothers, 65.4% [64.0, 66.8] had received iron during their most recent pregnancy; women living in urban areas (73.9% [72.2-75.5]) were more likely to receive iron than rural mothers (61.1% [59.4-62.9]) (OR for rural 0.52 [0.50-0.55], P < 0.001). Because of differences between urban and rural India, further analysis was restricted to subjects living in rural India. Simple and multiple logistic regression analyses for factors associated with receipt of iron supplements by children and by mothers antenatally are presented in Table 7. The prevalence of each independent factor evaluated is presented in the NFHS-3 report [1].
Table 7
Factors associated with receipt of iron across rural India: National Family Health Study-3 data
 
Antenatal iron supplements received by mother
Iron supplements currently received by children
Factor
Odds Ratio [95% CI]
P
Odds Ratio [95% CI]
P
Univariate logistic regression
Wealth quintile
1.51 [1.44, 1.57]
< 0.001
1.35 [1.26,1.45]
< 0.001
Maternal education
    
0 years
Reference
 
Reference
 
Primary
2.58 [2.30, 2.89]
< 0.001
1.76 [1.36, 2.28]
< 0.001
Secondary
4.11 [3.66, 4.61]
< 0.001
2.41 [1.96, 2.96]
< 0.001
Higher
14.00 [8.87, 22.08]
< 0.001
3.80 [2.61, 5.52]
< 0.001
Child's sex (male = 1)
0.98 [0.91, 1.05]
0.516
1.10 [0.95, 1.26]
0.191
Literate mother1
1.94 [1.84, 2.05]
< 0.001
1.47 [1.34, 1.61]
< 0.001
Birth order
0.78 [-.77, 0.80]
< 0.001
0.85 [0.81, 0.89]
< 0.001
Religion/Caste2
    
Hindu, non SC/ST
1.21 [1.08, 1.34]
= 0.001
1.31 [1.09, 1.57]
= 0.005
Scheduled Caste
0.95 [0.85, 1.07]
= 0.418
0.71 [0.55, 0.92]
= 0.008
Scheduled Tribe
1.04 [0.88, 1.23]
= 0.657
1.06 [0.82, 1.38]
= 0.651
Muslim
0.74 [0.62, 0.87]
< 0.001
0.82 [0.61, 1.09]
= 0.167
Antenatal health worker visits (OR per visit)
1.77 [1.70, 1.85]
< 0.001
1.02 [1.01, 1.02]
< 0.001
Antenatal iron received by mother
N/A
N/A
3.02 [2.32, 3.93]
< 0.001
Postnatal iron received by mother
Not measured
 
Not measured
 
Blood test during pregnancy
2.36 [2.10, 2.64]
< 0.001
2.50 [2.02, 3.10]
< 0.001
Services accessed:
    
Anganwadi Centre3
2.03 [1.79, 2.30]
< 0.001
1.79 [1.47, 2.19]
< 0.001
Child vaccinated4
2.03 [1.73, 2.38]
< 0.001
1.28 [0.84, 1.94]
= 0.244
Multiple logistic regression 5
Wealth quintile
-
 
1.12 [1.02, 1.23]
= 0.019
Maternal education
    
0 years
Reference
 
Reference
 
Primary
1.60 [1.34, 1.91]
< 0.001
1.47 [1.02, 2.11]
= 0.039
Secondary
1.53 [1.31, 1.79]
< 0.001
2.15 [1.17, 3.97]
= 0.014
Higher
5.20 [2.65, 10.22]
< 0.001
3.17 [1.56, 6.44]
= 0.001
Literate mother1
-
 
0.74 [0.57, 0.97]
= 0.030
Birth Order
-
 
-
 
Religion/Caste2
    
Hindu, non SC/ST
-
 
-
 
Scheduled Caste
-
 
-
 
Scheduled Tribe
-
 
-
 
Muslim
0.75 [0.62, 0.91]
= 0.003
-
 
Antenatal health worker visits (OR per visit)
-
 
-
 
Antenatal iron supplementation given to mother
N/A
 
2.24 [1.56, 3.22]
< 0.001
Blood test during pregnancy
2.06 [1.78, 2.38]
< 0.001
1.86 [1.47, 2.37]
< 0.001
Services accessed:
    
Anganwadi Centre3
1.79 [1.51, 2.12]
< 0.001
1.47 [1.20, 1.80]
< 0.001
Child Vaccinated4
1.28 [1.06, 1.54]
= 0.010
-
 
1 Literacy defined as 0 = cannot read, 1 = can read part of a sentence, 2 = can read complete sentence; visually impaired mothers excluded.
2SC = Scheduled Caste; ST = Scheduled Tribe. Logistic regression performed for each category.
3Mother's use of Anganwadi in the last 3 months.
4Child ever had a vaccination
5Multiple regression coefficients only displayed for variables found to be significantly associated; variables not associated indicated with '-'.

Discussion

The Indian Government has endorsed a policy, in line with World Health Organization recommendations [15], of providing routine iron supplementation to all children aged 6-60 months, and all pregnant and lactating women [5]. By conducting both a targeted study in two districts of rural Karnataka and also using data from a nationally representative survey, we have found a marked difference between anaemia control policy and iron supplement receipt in the field. We have also identified considerable disparities that are partly mediated by socio-economic and health care factors.
Private providers, rather than government health care workers, are the major source of supplements for children. Possible reasons for this may include, firstly, a lack of availability of appropriate supplements within the government system: inadequate supply of supplements in rural Indian PHCs has been previously observed [18], and government supplied liquid preparations suitable for children may be particularly difficult to access [19]. Iron preparations appropriate for young children are more expensive than iron tablets in retail pharmacies in India [20]. Secondly, government health workers and managers may be insufficiently educated about the importance of iron supplementation for prevention of anaemia in young children, and hence may not routinely provide this therapy [21]. Thirdly, wealthier families may be more likely to seek optimal health outcomes through private providers [22]. The unexpected finding in the Karnataka Study of an inverse association between children's receipt of iron supplementation and indicators of apparently good primary health care (receiving a full course of vaccinations and visits to the Anganwadi centre), together with the very low rate of distribution from government sources, raises the possibility that families who exclusively use government services are unable to receive iron supplements for their child through that system.
Data from both our field study and the NFHS-3 identify clear links between maternal anaemia control measures and delivery of iron to children. This may be due to improved awareness of anaemia and the value of iron in mothers, or to superior knowledge, attitudes and practices regarding anaemia prophylaxis in health workers caring for both mothers and their children. We have previously reported that children's haemoglobin concentrations in this population are chiefly associated with their iron status and their mother's haemoglobin [2]. Thus, controlling maternal anaemia may prevent anaemia in children as well as improve the health of the mother. Iron supplementation programmes for pregnant [23] and non-pregnant women [24] have been successfully implemented in several settings worldwide, including in India [25], and these programmes could be expanded with potential benefits for children as well as their mothers.
There are important differences between the methodology of the Karnataka Study and the NFHS-3. The two studies evaluated different outcomes: NFHS-3 asked whether children were currently receiving iron; the Karnataka Study asked whether children had ever received iron supplements. This may partly explain the lower national prevalence of receipt of iron identified on the NFHS-3: assuming all children received the nationally recommended 100 days of supplementation annually, and supplementation was evenly distributed across a year, 27% of children should have been receiving iron in the NFHS-3. However, the NFHS-3 data also indicated overall performance of services was poorer nationally than in the Karnataka Study. For example, whereas the Karnataka Study showed that 85.7% of children had ever visited an Anganwadi centre, NFHS-3 data shows that only 20.2% of children had visited a centre in the previous 3 months; this difference suggests heterogeneous access to ICDS services nationally that may explain the disparate findings in association between attendance at Anganwadi centres and receipt of iron between the two studies. Unlike the NFHS-3 data, the Karnataka study identified the source of iron received by children and thus was able to specifically evaluate government distribution. Although lower receipt of iron by children of Muslim families, as noted in the Karnataka Study, was not borne out nationally, this was identified among pregnant women from Muslim families in the national dataset. Finally, the Karnataka Study was prospectively designed with specific elements in the questionnaire to obtain a better understanding of the receipt of iron in rural India; the NFHS-3 dataset was used to perform a post-hoc analysis to understand iron receipt nationally.
Very few other published studies have reported receipt iron in the field by children in India. A study of 487 pregnant women in Andhra Pradesh identified receipt of iron by only 19%, and only 1% among children [7]. The Micronutrient Taskforce reviewed national nutritional anaemia control programmes in 1996 and identified limitations, including "poor compliance, irregular supplies, (and) low education/counseling" [26]. Thus, our study provides one of few comprehensive evaluations of iron supplementation both nationally, and in detail in a representative rural population.
The results of our study should be interpreted within the context of its strengths and limitations. This study analysed cross-sectional rather than longitudinal data, thus we are able to report only associations between variables, rather than definite cause and effect. Since the Karnataka Study sample size was relatively small, we sought to improve the external generalisability by also evaluating national (NFHS-3) data and making comparisons. Beyond variables measured in this study, there are likely to be multiple other factors that interact to affect the efficacy of anaemia control policies, concerning distribution and supply chains of iron supplements, performance of the health system as a whole, affordability of supplements, and acceptability of iron formulations to families.
Further research, including qualitative studies, are required to understand the gap between national anaemia control policy and practice in the field, and for disparities in receipt of iron supplements. Specifically, additional research is required to understand why receipt of iron was suboptimal in a setting where other vertical programmes (such as vaccination and Vitamin A distribution) function relatively well, as noted in the Karnataka Study. Such information may help to either specifically improve the iron supplementation programme or offer potential opportunities for synergy with these other programmes. Secondly, a study of the supply chain required for the provision of iron supplementation: from raw materials, manufacture, and distribution to the PHC, may help understand reasons for inadequate receipt of supplements that we did not address in this study. This could help programme managers plan for and procure sufficient stock of iron supplements for distribution through public systems. Thirdly, understanding the knowledge, attitudes and practices of government health workers and managers would help clarify how these factors affect implementation of anaemia control measures [27]. This information would help policymakers direct their management and training messages to improve iron supplementation through the government health system. Finally, research directed at understanding the likely acceptability of liquid iron formulations by children and their mothers in the field could be undertaken to address adherence to supplements, if or when they are made available.
Our finding, both locally and nationally, that children belonging to poorer families are less likely to receive iron (despite a higher burden of anaemia in poorer children [2]), is an example of the 'inverse care law': the poorest with greatest need have least access to valuable interventions [28]. Based on our results, improving the receipt of iron supplementation among all, but especially the poorest families, could potentially be achieved through education of health workers responsible for providing iron during pregnancy, in the post partum, and to children. Additionally, other primary health services offer an opportunity to introduce iron supplementation, for example, integrated delivery with 9 and 18 month vaccinations or with Vitamin A supplements [29]. Once women have experienced health benefits from iron, they may be more committed to continuing iron supplementation themselves [30] and may also be more likely to seek iron supplementation for their children, as suggested by our data. However, beyond these strategies, emphasis must also be given to further developing longer-term strategies to eliminate anaemia including; development of effective alternatives to iron supplementation, such as home fortification by microencapsulated micronutrients [31], iron fortification of staple foods, condiments and complementary foods [32], and dietary diversification.

Conclusions

Despite an enormous and deteriorating problem of anaemia in India, iron supplementation policies for rural children and mothers are inadequately implemented. Key factors associated with access to iron supplements are wealth and maternal access to health services; ethnic disparities seem to be important, and improved maternal access to anaemia control measures also benefits access for children. Ensuring optimal delivery of iron supplements to all children and pregnant women, regardless of their socioeconomic background, could help address the enormous burden of anaemia in this population.

Acknowledgements and funding

The authors would like to acknowledge the field team led by Mrs Varalaxmi Vijaykumar that was involved in data collection. We are indebted to the community health workers and village Anganwadi workers who assisted in the fieldwork. We are grateful to Dr R Narayan who reviewed the manuscript and provided valuable comments. The study was funded by the Allen Foundation (MI, USA) and the Fred P Archer Charitable Trust (VIC, Australia). SP was supported by a Melbourne Research Scholarship (University of Melbourne, Australia). The authors are grateful to Measure DHS for permission to use the NFHS-3 dataset in this study.

Competing interests

The authors declare that they have no competing interests.

Authors' contributions

SP, BA-B, JB, and AS planned the study and prepared the manuscript. SP and AS led the fieldwork. SP, BA-B and JB analysed the data. All authors conceived the study, read and approved the final manuscript.
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