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Predictors of anaemia in mothers and children in Uttar Pradesh, India

Published online by Cambridge University Press:  08 January 2024

Leila M Larson*
Affiliation:
Department of Health Promotion, Education, and Behavior, Arnold School of Public Health, University of South Carolina, 915 Greene Street, Columbia, SC 29208, USA
Tinku Thomas
Affiliation:
Department of Biostatistics, St John’s Medical College, Bangalore, India
Anura V Kurpad
Affiliation:
Department of Physiology, St John’s Medical College, Bangalore, India
Reynaldo Martorell
Affiliation:
The Hubert Department of Global Health, Rollins School of Public Health, Emory University, Atlanta, USA
John Hoddinott
Affiliation:
Division of Nutritional Sciences, Cornell University, Ithaca, NY, USA
Victoria Oluwapamilerin Adebiyi
Affiliation:
Department of Health Promotion, Education, and Behavior, Arnold School of Public Health, University of South Carolina, 915 Greene Street, Columbia, SC 29208, USA
Sumathi Swaminathan
Affiliation:
Division of Nutrition, St John’s Research Institute, Bangalore, India
Lynnette M Neufeld
Affiliation:
Food and Agriculture Organization of the United Nations (FAO), Rome, Italy
*
*Corresponding author: Email [email protected]
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Abstract

Objective:

Anaemia affects more than half of Indian women and children, but the contribution of its causes remains unquantified. We examined interrelationships between Hb and nutritional, environmental, infectious and genetic determinants of anaemia in non-pregnant mothers and children in Uttar Pradesh (UP).

Design:

We conducted a cross-sectional survey of households in twenty-five districts of UP between October and December 2016. We collected socio-demographic data, anthropometry and venous blood in 1238 non-pregnant mothers and their children. We analysed venous blood samples for malaria, Hb, ferritin, retinol, folate, Zn, vitamin B12, C-reactive protein, α1-acid glycoprotein (AGP) and β-thalassaemia. We used path analysis to examine pathways through which predictors of anaemia were associated with Hb concentration.

Setting:

Rural and urban households in twenty-five districts of UP.

Participants:

Mothers 18–49 years and children 6–59 months in UP.

Results:

A total of 36·4 % of mothers and 56·0 % of children were anaemic, and 26·7 % of women and 44·6 % of children had Fe deficiency anaemia. Ferritin was the strongest predictor of Hb (β (95 % CI) = 1·03 (0·80, 1·27) g/dL in women and 0·90 (0·68, 1·12) g/dL in children). In children only, red blood cell folate and AGP were negatively associated with Hb and retinol was positively associated with Hb.

Conclusions:

Over 70 % of mothers and children with anaemia had Fe deficiency, needing urgent attention. However, several simultaneous predictors of Hb exist, including nutrient deficiencies and inflammation. The potential of Fe interventions to address anaemia may be constrained unless coexisting determinants are jointly addressed.

Type
Research Paper
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of The Nutrition Society

Anaemia affects 40 % of children 6–59 months of age and 30 % of non-pregnant women of reproductive age globally(Reference Stevens, Finucane and De-Regil1). The burden is particularly high in low- and middle-income countries and has important implications for cognition, school achievement, work productivity and income generation. The World Health Assembly set a target for 2025 of reducing anaemia by 50 % relative to the 2010 prevalence in women worldwide. To achieve this target, interventions must address the causes of anaemia appropriately. It is commonly stated that 50 % of anaemia is caused by Fe deficiency anaemia(Reference DeMaeyer and Adiels-Tegman2); however, the aetiology of anaemia is multifactorial and varies by setting, and the proportion of anaemia that is amenable to Fe treatment is still not well understood(Reference Engle-Stone, Aaron and Huang3,Reference Wirth, Woodruff and Engle-Stone4) .

The determinants of anaemia have been well characterised in the literature and include a complex pattern of biological, socio-demographic, environmental and genetic factors(Reference Balarajan, Ramakrishnan and Ozaltin5). Assessments of anaemia in vulnerable populations, and interventions and policies to address anaemia, have attempted to map its prevalence and understand its causes. The most important anaemias result from nutritional deficiencies and parasitic infections that cause increased loss or reduced absorption or utilisation of Fe (soil-transmitted helminths, malaria, schistosomiasis and other parasitic infections), and genetic disorders affecting Fe or Hb metabolism(Reference Balarajan, Ramakrishnan and Ozaltin5). Many studies have examined associations between anaemia or Hb concentration and their predictors using bivariate analyses(Reference Engle-Stone, Aaron and Huang3,Reference Nguyen, Gonzalez-Casanova and Nguyen6Reference Wirth, Rohner and Woodruff10) . However, the interplay of direct and indirect associations between Hb and its multiple predictors is inadequately understood. This information is critical for the design of programmes that can effectively reduce the burden of anaemia. The current analysis seeks to further elucidate the aetiology of anaemia, by examining the interactions and associations between genetic, environmental, infectious and nutritional predictors of Hb concentration in women and children living in rural and urban areas of Uttar Pradesh state, India. Uttar Pradesh is located in Northern India and shares a border with Nepal. It is one of the largest states in India with some of the highest numbers of malnourished women and children. According to the National Family Health and Welfare Survey-4, conducted prior to this study, 46·3 % of children under 5 years of age were stunted and 63·2 % were anaemic, and 52·5 % of non-pregnant women of reproductive age were anaemic(11).

Subjects and methods

Study design and sampling strategy

This study was led by the Global Alliance for Improved Nutrition with partner organisations St John’s Research Institute, Bangalore, India (SJRI), The India Nutrition Initiative and Cornell University. The study consisted of a cross-sectional survey of non-pregnant mothers of reproductive age (MRA) 18–49 years of age and children 6–59 months of age (preschool-age children (PSC)) living in rural and urban Uttar Pradesh. A total of twenty-five districts were selected: ten districts were purposefully sampled as part of a baseline evaluation to a double fortified salt programme in the state(Reference Cyriac, Webb Girard and Ramakrishnan12) (details forthcoming) and fifteen additional districts were selected randomly using simple random sampling with a random number generator out of all remaining districts in the state, for a total of twenty-five districts. Within each district, five villages (rural) and five wards (urban) were randomly selected from the 2011 Census of India. Within each ward, one Census Enumeration Block was selected randomly using the 2011 Census of India. Within each of these villages and Census Enumeration Blocks, five households were selected to be included in the survey using a modified random walk method (see online supplementary material, Supplemental Fig. 1).(13) In nine wards, an insufficient number of households fit our inclusion criteria (i.e. there were fewer than five households containing a mother of reproductive age with at least one child 6–59 months of age). In these cases, where possible, we attempted to select additional households from neighbouring villages or wards selected for the survey in the same district. As such, the total number of participants included in the study varied slightly from the original design. Within each household, one non-pregnant mother of reproductive age and one of her PSC 6–59 months of age were included. Households were excluded only in the case of physical or mental impairment that could impede measurements or provision of informed consent. Data were collected between October and December 2016.

A sample size of 1250 households in total was calculated to obtain a 5 % precision on the prevalence of Fe deficiency, in twenty-five randomly selected districts, anticipated prevalence of 25 %(Reference Haas, Rahn and Venkatramanan14), average household size of 5·7(11) and a design effect of 2(Reference Pasricha, Drakesmith and Black15). Using this pre-specified sample size of 1250, for this analysis, we were able to detect a minimum correlation coefficient with Hb of 0·09, with 90 % power and 5 % precision.

Measurements and data collection

All MRA were interviewed with a household survey. The survey consisted of questions about household demographic characteristics such as socio-economic status, water, sanitation, hygiene, use of Integrated Child Development Services (a programme delivered through the Anganwadi Centres), use of other safety net programmes, as well as information on the mother and child’s medical history and use of nutritional supplements (i.e. Fe, folic acid, Zn, Ca, vitamin C, vitamin D and multivitamins). Women’s dietary diversity was assessed based on a 9-food group score for a 24-h recall period(Reference Kennedy, Ballard and Dop16) and for children a 7-item child dietary diversity score was assessed according to WHO guidelines at the time during a 24-h recall period(17). Food insecurity in the past 12 months was measured using an 8-item Food Insecurity Experience Scale(18).

Plax-Cruzer Series (Indman Scale Corporation) weighing scales were used to assess weight of the mother and child to the nearest 0·1 kg, using the tare function for child weight. Standing height was taken from MRA and children 2 years and above using the Seca 213 stadiometer to the nearest 0·1 cm. Recumbent length of children less than 2 years of age was measured using the Seca 417 infantometer (Seca) to the nearest 0·1 cm. Stadiometers, length boards and weighing scales were calibrated daily using standard procedures provided by the manufacturers. Reliability estimates for anthropometric measurements were obtained by comparing the supervisors’ measurements (only supervisors performed anthropometry measurements) to those of an expert when assessing the same child, using five children(Reference de Onis, Onyango and Van den Broeck19,Reference Fernald, Kariger and Engle20) . Reliability measurements for weight and height yielded a Pearson’s correlation coefficient between measurements of the data collectors and expert of > 0·98 and a coefficient of reliability of > 0·98.

Hb concentration was measured using the HemoCue 201 + Analyser (HemoCue). A non-fasting venous blood sample (10 mL) was collected from each MRA and 7 mL was collected from each PSC. First, 4 mL of venous blood was collected in plastic spray-coated K2EDTA tubes from BD Vacutainer®. After slowly inverting the K2EDTA vial twice, a syringe was used to collect a few drops of whole blood from the tube and to place them on a clean plastic slide. The phlebotomist then filled a microcuvette with the drop and immediately tested the Hb concentration using the HemoCue. A drop of whole blood was also used to test for the presence of malaria, specifically P. vivax and P. falciparum, using a rapid diagnostic kit (FalciVax immune-chromatography, Zephyr Biomedicals) on both women and children.

An additional 3–6 mL of venous blood was collected in trace-element free tubes, with increased silica act clot activator, silicone-coated interior from BD Vacutainer®.

Laboratory blood measurements

Laboratory blood analyses were conducted at SJRI (i.e. red blood cell folate) and Sanjay Gandhi Postgraduate Institute (SGPGI) (i.e. all other analyses). Internal laboratory quality control was performed according to standard procedures. The laboratory at SGPGI completed the RIQAS certification through Randox Laboratories Limited (United Kingdom). The laboratory at SJRI participated in the Centers for Disease Control and Prevention’s VITAL-EQA programme.

Serum ferritin and vitamin B12 were measured using sandwich electrochemiluminescence immunoassay ELECSYS 2010 (ROCHE Diagnostics). Serum C-reactive protein (CRP) and α1-acid glycoprotein (AGP) were measured using immunoturbidimetry: Cobas Integra 800 for CRP and Hitachi 902 for AGP (ROCHE Diagnostics). Serum Zn was measured using atomic absorption spectroscopy Hitachi Model Z2300 (Hitachi Group). β-thalassaemia was measured using ion-exchange HPLC VARIANT II β-thalassaemia Short Programme (BIO-RAD Laboratories). Serum retinol was measured using reverse-phase HPLC: Dionex Ultimate 3000 series HPLC instrument (Thermo Fisher Scientific). Red blood cell (RBC) folate was quantified using the WHO-recommended folate microbiological assay(Reference Cordero, Crider and Rogers21). The folate concentration was determined by measuring the turbidity of the inoculated medium at 590 nm using a microplate reader (SYNERGY H1 microplate reader, BioTek Instruments). The assay was carried out in a 96-well microplate and calibrated using 5-methyltetrahydrofolic acid standard provided by the CDC(Reference O’broin and Kelleher22,Reference Pfeiffer, Zhang and Lacher23) .

Variable creation and statistical analyses

A Wealth Index, using five categories, was calculated using principal component analysis with family assets, house materials and number of rooms, and agricultural land ownership, home ownership or commercial ownership. A water, sanitation and hygiene (WASH) index, also using quintiles, was calculated using principal component analysis with improved or unimproved source of drinking water, toilet facility and hygienic appearance of the mother and her child and the household compound(Reference Webb, Stein and Ramakrishnan24). BMI for women was derived by dividing the weight of mothers (in kg) by the square of their height (in cm). The following BMI categories were used to classify women: < 18·5, 18·5–24·9, 25·0–29·9 and over > 30 kg/m2. Length-for-age, weight-for-length and weight-for-age z-scores were calculated using the WHO 2006 child growth standards. Z-scores less than –2 were used to define stunting, wasting and underweight, respectively, and z-scores less than –3 were used to define severe stunting, severe wasting and severe underweight(Reference de Onis, Onyango and Van den Broeck19).

Anaemia was defined according to WHO criteria(25) in MRA: any anaemia as Hb < 12 g/dL, mild anaemia as Hb 11–11·9 g/dL, moderate anaemia as Hb 8–10·9 g/dL and severe anaemia as Hb < 8 g/dL; in PSC, any anaemia as < 11 g/dL, mild anaemia as Hb 10–10·9 g/dL, moderate anaemia as Hb 7–9·9 g/dL and severe anaemia as Hb < 7 g/dL. Hb adjustment for altitude was not needed as all areas were below 1000 m above sea level(25). Fe deficiency was defined as ferritin < 15 µg/L in MRA and < 12 µg/L in PSC(26). Vitamin A deficiency was defined as serum retinol concentration < 0·7 µmol/L in MRA and PSC(27). Ferritin (children and women) and retinol (children only) were adjusted for inflammation (CRP and AGP) using the BRINDA regression approach(Reference Suchdev, Namaste and Aaron28,Reference Namaste, Rohner and Huang29) . Vitamin B12 deficiency was defined as vitamin B12 concentration < 150 pmol/L in MRA and PSC(Reference de Benoist30). Zn deficiency was defined as Zn concentration < 10·7 µmol/L in MRA and < 9·9 µmol/L in PSC(Reference Brown, Rivera and Bhutta31). Individual Zn values were adjusted to a non-fasting state and 20 min between collection and processing for both women and children(Reference McDonald, Suchdev and Krebs32). In children only, they were also adjusted for CRP and AGP using the BRINDA regression approach(Reference McDonald, Suchdev and Krebs32). RBC folate level to define folate deficiency (for all age groups) using macrocytic anaemia as haematological indicator was defined as < 305 nmol/L(Reference Pfeiffer, Sternberg and Hamner33). Elevated CRP was defined as CRP concentration > 5 mg/L(34). Elevated AGP was defined as AGP concentration > 1 g/L(Reference Erhardt, Estes and Pfeiffer35). β-thalassaemia was defined as Hb A2 variant > 3·2 %(Reference Bain36).

We compared the magnitude of the associations between various predictors by fitting the data to a pre-specified model to determine their association with one another and with Hb (see online supplementary material, Supplemental Fig. 2). The pre-specified model was based on a review of the literature, and the pathways leading to anaemia were proposed drawing on the UNICEF conceptual framework of malnutrition that highlights the immediate, underlying and basic causes of malnutrition(37). Explanations of the theory behind the model development are presented in online supplementary material, Supplemental Fig. 2.

Univariate and bivariate analyses were conducted using SAS 9.4 (SAS Institute), and the path model was developed in StataSE version 15 (StataCorp) using maximum likelihood estimation. First, means, standard deviations and prevalence statistics were derived using standard SAS procedures. Non-normally distributed blood biomarkers (ferritin, vitamin B12, RBC folate, Zn, retinol, CRP, AGP) were natural logarithm (ln) transformed and geometric means were reported. Second, multiple variable logistic regression models were used to estimate the factors associated with anaemia in children and women, and population attributable fractions were calculated for each of these factors(Reference Bruzzi, Green and Byar38). Variables from our pre-specified theoretical model (see online supplementary material, Supplemental Fig. 2) were included in the multiple variable models. In all analyses, we accounted for clustering at the district level and weighted for district and setting (urban and rural) sampling. Weights were constructed for rural and urban populations separately using adjustment factors for (1) the proportion of people living in rural and urban localities in each district, (2) the size of each district and (3) the district’s likelihood of being selected. In SAS, proc surveymeans/surveyfreq and proc surveyreg/surveylogistic commands were used to account for the complex survey design; in StataSE, the svy command was used.

Third, the hypothesised path model examined the direct and indirect associations among WASH, dietary diversity, food insecurity, CRP, AGP, nutritional biomarkers (ferritin, Zn, retinol, vitamin B12, RBC folate) and Hb concentration. Prior to running the path model, Pearson’s correlations were run to examine correlations between all variables included in the model. A single model for PSC and for MRA was fitted to the data. Model fit was evaluated with common standards: a comparative fit index(Reference Bentler39) and a Tucker Lewis index > 0·90 for acceptable fit and > 0·95 for good fit(Reference Tucker and Lewis40), and a standardised root mean squared residual(Reference Lt and Bentler41) and a root mean square error of approximation < 0·08 for acceptable fit and < 0·05 for good fit(Reference Steiger42). If model fit statistics were not acceptable, modification indices were examined to decide whether additional pathways should be examined to improve model fit, and the model was re-specified. The PSC model was adjusted for child age in months. Group comparison for rural and urban settings was used to determine whether the model may be different in the two populations. A Wald test was used to determine statistically significant (P-value < 0·05) differences for any particular path. Standardised and unstandardised estimates were calculated.

β-thalassaemia trait was measured in only a subset of the women (n 744) due to insufficient blood, and the prevalence of β-thalassaemia trait was low in this population (3 %); hence, a path analysis with β-thalassaemia was run separately. The model with thalassaemia included direct pathways from β-thalassaemia trait to Hb concentration and to ferritin concentration.

A further additional analysis was run using full information maximum likelihood. Several laboratory analyses were missing for some participants, particularly children, given insufficient blood sample. Therefore, 45 % of PSC and 19 % of MRA were missing at least one value for the predictors of interest. Additional path modelling was done in StataSE using the sem command and the mlmv option, which estimates coefficients using full information maximum likelihood with all available data under the assumption that any missing data were at random(Reference Enders and Bandalos43).

Results

Across the state, 34·5 % of mothers and 13·8 % of fathers had no schooling; mean household size was 6·7 in urban and 7·5 in rural settings (Table 1). In PSC, mean dietary diversity for the 24-h period was poor and fewer than 5 % of children consumed flesh foods (Table 2). Similarly, in mothers, dietary diversity was low and fewer than 8 % of women consumed meat or fish (Table 3). Prevalence of stunting, wasting and underweight in PSC was 47·7, 6·7, and 32·5 %, respectively, and 25·9 % of MRA had a BMI < 18·5 kg/m2 (Tables 2 and 3). Prevalence of anaemia was 56·0 % in PSC and 36·4 % in MRA; prevalence of low ferritin, or Fe deficiency, was 64·3 % in PSC and 51·0 % in MRA after adjusting for inflammation. Among those with anaemia, 78·1 % of PSC and 74·4 % of MRA had Fe deficiency. Among those with Fe deficiency, 68·0 % of PSC and 50·6 % of MRA had anaemia. Malaria was < 1 %, likely due to the survey being conducted in the non-malarial months (October–December) (Tables 2 and 3); therefore, malaria was not included in further analyses.

Table 1 Descriptive characteristics of non-pregnant mothers of reproductive age and preschool-age children living in Uttar Pradesh *

WASH, water, sanitation and hygiene.

* Food insecurity scale is out of 8 with increasing scores representing increasing food insecurity. Higher WASH and wealth quintiles represent cleaner and wealthier households, respectively.

Table 2. Health and nutrition characteristics of preschool-age children living in Uttar Pradesh *

AGP, α1-acid glycoprotein; CRP, C-reactive protein.

* Morbidity measured as any episodes of fever, cough and diarrhoea in the past week.

Table 3 Health and nutrition characteristics of mothers of reproductive age living in Uttar Pradesh

AGP, α1-acid glycoprotein; CRP, C-reactive protein.

The fraction of anaemia attributable to low Fe was 37·8 % in PSC and 15·0 % in MRA. Other population attributable fraction percentages were below 15 % (Tables 4 and 5). In PSC, the correlation matrix indicated significant correlations between Hb and ferritin, RBC folate, vitamin B12, age and birth weight (see online supplementary material, Supplemental Table 1). In MRA, correlations were significant between Hb and ferritin, retinol, RBC folate and food insecurity (see online supplementary material, Supplemental Table 2).

Table 4 Multivariable analysis of the risk factors for anaemia and their population attributable fraction in preschool-age children *

PR, prevalence ratio; PAF, population attributable fraction; ref, reference.

* Analyses adjust for child age. Serum ferritin and retinol were adjusted for inflammation using BRINDA method. Serum Zn was adjusted for inflammation using BRINDA method, and for time of last meal and time of processing.

Table 5 Multivariable analysis of the risk factors for anaemia and their population attributable fraction in mothers of reproductive age *

PR, prevalence ratio; PAF, population attributable fraction; ref, reference.

* Serum ferritin was adjusted for inflammation using BRINDA method. Serum Zn was adjusted for time of last meal and time of processing.

In PSC, the path model indicated that RBC folate (standardised β (β) = –0·17, P < 0·001), retinol (β = 0·07, P = 0·034), ferritin (β = 0·49, P < 0·001) and AGP (β = 0·20, P = 0·002) were significantly directly associated with Hb concentrations (Fig. 1, see online supplementary material, Supplemental Table 3). CRP was indirectly associated with Hb through ferritin (see online supplementary material, Supplemental Tables 3 and 4). Both CRP (β = 0·21, P = 0·002) and AGP (β = 0·14, P = 0·016) were significantly directly associated with ferritin. Food insecurity (increasing insecurity) was negatively associated with RBC folate, vitamin B12 and retinol concentrations. WASH quintile (increasing cleanliness) was negatively associated with food insecurity (β = –0·33, P < 0·001) and AGP (β = –0·13, P = 0·029) and positively associated with dietary diversity (β = 0·15, P = 0·012) (Fig. 1).

Fig. 1 Path model of the predictors of Hb concentration in preschool-age children living in Uttar Pradesh.

Note: Results are presented as standardised estimates, adjusted for age in months. The model utilised log transformed Zn, folate, vitamin B12, retinol, CRP and AGP. WASH is represented in quintiles; all other variables are continuous scores or concentrations. Thin grey arrows represent non-significant associations; thick black arrows represent significant associations. Model fit statistics: RMSEA = 0·057; CFI = 0·960; TLI = 0·836; SRMR = 0·0034. Direct associations between inflammation biomarkers and nutritional biomarkers were estimated, but not all are presented; significant direct associations were also found between AGP and Zn (β = –0·15*), AGP and vitamin B12 (β = 0·02*), and CRP and vitamin B12 (β = –0·01*). AGP, α-1 acid glycoprotein; CRP, C-reactive protein; DD, dietary diversity score; FI, food insecurity score; WASH, water, sanitation and hygiene; RMSEA, root mean square error of approximation; CFI, comparative fit index; TLI, Tucker Lewis index; SRMR, standardised root mean squared residual. † Zn adjusted for time of processing and fasting. *P < 0·05. **P < 0·01. ***P < 0·001

In MRA, the path model indicated that only ferritin (β = 0·54, P < 0·001) was significantly directly associated with Hb concentration (Fig. 2, see online supplementary material, Supplemental Table 5). CRP was indirectly associated with Hb through ferritin (see online supplementary material, Supplemental Tables 5 and 6). CRP was significantly associated with ferritin (β = 0·14, P = 0·006), but AGP was not. Dietary diversity was associated with RBC folate and retinol concentrations. WASH was negatively associated with food insecurity (β = –0·36, P < 0·001) and positively associated with dietary diversity (β = 0·19, P < 0·001) and CRP (β = 0·17, P = 0·010) (Fig. 2).

Fig. 2 Path model of the predictors of Hb concentration in mothers of reproductive age living in Uttar Pradesh.

Note: Results are presented as standardised estimates. The model utilised log transformed Zn, folate, vitamin B12, retinol, CRP and AGP. WASH is represented in quintiles; all other variables are continuous scores or concentrations. Thin grey arrows represent non-significant associations; thick black arrows represent significant associations. Model fit statistics: RMSEA = 0·058; CFI = 0·926; TLI = 0·773; SRMR = 0·036. Direct associations between inflammation biomarkers and nutritional biomarkers were estimated, but not all are presented; significant associations were also found between AGP and vitamin B12 (β = 0·11*) and CRP and folate (β = 0·09**). AGP, α-1 acid glycoprotein; CRP, C-reactive protein; DD, dietary diversity score; FI, food insecurity score; WASH, water, sanitation and hygiene; RMSEA, root mean square error of approximation; CFI, comparative fit index; TLI, Tucker Lewis index; SRMR, standardised root mean squared residual. † Zn adjusted for time of processing and fasting. *P < 0·05. **P < 0·01. ***P < 0·001

For the additional analysis including β-thalassaemia in the MRA model, the path model indicated that both ferritin (β = 0·58, P < 0·001) and β-thalassaemia (β = –0·038, P = 0·019) were significantly directly associated with Hb concentration. There were no meaningful differences in the estimates between models with and without β-thalassaemia trait (see online supplementary material, Supplemental Tables 78).

No meaningful differences were found in the estimates between models using full information maximum likelihood estimation and models using maximum likelihood estimation in both PSC and MRA (see online supplementary material, Supplemental Tables 912). Basic descriptive variables (i.e. age, child sex and Hb concentration) were comparable across those with missing and non-missing data. In PSC and MRA models, no differences between rural and urban settings were found for any of the pathways.

Discussion

In mothers and children in Uttar Pradesh, ferritin, a measure of body Fe stores, appears to be the single most important correlate of Hb concentration. This is consistent with the literature on the importance of ferritin in the aetiology of anaemia(Reference Nguyen, Gonzalez-Casanova and Nguyen6,Reference Chaparro and Suchdev44Reference Atkinson, Armitage and Khandwala46) . Also consistent(Reference Balarajan, Ramakrishnan and Ozaltin5) is the existence of other determinants of anaemia, namely inflammation, folate and retinol. The path analysis illustrates how distal factors, such as dietary diversity, food insecurity and WASH, work through influences on nutritional status and inflammation indicators. Many Fe interventions (supplementation among others) are effective in increasing Hb concentration and reducing anaemia, but the magnitude of that reduction is often not as large as anticipated from the prevalence of Fe deficiency(Reference da Silva Lopes, Yamaji and Rahman47). The extent to which this may be due at least in part to the complex interrelationship among nutritional status, inflammation and Hb concentration illustrated by our path analysis has not been adequately studied.

Those concerns notwithstanding, approximately 78 % of children and 74 % of mothers with anaemia, had Fe deficiency (as defined by low ferritin). These statistics and the path analysis estimates suggest that Fe status is the most important problem in this context, which urgently needs to be addressed. In both women and child models, ferritin was the strongest statistical predictor of Hb concentration. These findings complement other studies in South Asia where malaria prevalence was also low. Results from Vietnam and India indicate significant increased odds of anaemia in women and children with Fe deficiency(Reference Nguyen, Gonzalez-Casanova and Nguyen6,Reference Pasricha, Black and Muthayya7,Reference Nair, Fernandez-Rao and Nagalla48) . The study in Northern Vietnam found that 11 % of anaemia among women of reproductive age was attributable to insufficient Fe stores(Reference Nguyen, Gonzalez-Casanova and Nguyen6).

In our study, a negative association was found between folate and Hb concentration in children. While others have found contrasting results of positive associations between folate and Hb(Reference Ndiaye, Idohou-Dossou and Diouf49), some have found similar inverse associations in low- and middle-income school-age children living in Bogota, Colombia(Reference Arsenault, Mora-Plazas and Forero50) and in elderly Americans(Reference Morris, Jacques and Rosenberg51). In Colombia, few children had low folate status, likely because wheat flour is fortified with folic acid in the country(52). In the USA, high serum folate was associated with anaemia only in older adults with low vitamin B12 (Reference Morris, Jacques and Rosenberg51). The negative association between folate and Hb in populations with low folate deficiency, as is the case in our study (only 8·7 % of PSC and 18·3 % of MRA were folate deficient), and particularly among individuals with low vitamin B12 status is not well understood(Reference Caicedo, Villamor and Forero53,Reference Woeller, Fox and Perry54) . Some have stipulated that a high folate intake could create a competitive reduction in Fe absorption or metabolism, which would result in less Hb synthesis(Reference Shayeghi, Latunde-Dada and Oakhill55Reference Pellis, Dommels and Venema57). From another perspective, individuals with elevated folate may be consuming foods high in folate, which are also high in phytates, ultimately reducing Fe absorption, a hypothesis that we could not test in this analysis. Further, those consuming high cereal diet, resulting in high folate, may also have lower intake of high-quality protein necessary for Hb production(Reference Reissman58).

After micronutrient status, the strongest predictor of Hb is inflammation, a marker of infection, which can reduce appetite, use nutrient resources in fighting infections and reduce absorption(Reference Scrimshaw59,Reference Dewey and Mayers60) . These findings are consistent with a pooled analysis of sixteen national surveys in PSC and ten surveys in WRA, in which inflammation was repeatedly found to be significantly associated with anaemia, particularly in contexts with a high burden of infection. The association between inflammation and Hb, independently of Fe, has been demonstrated in studies in young Indian children(Reference Pasricha, Black and Muthayya7), Danish blood donors(Reference Kotze, Pedersen and Petersen61) and Sierra Leonean children and women(Reference Wirth, Rohner and Woodruff10). Inflammation has also been shown to be indirectly associated with Hb by acting on hepcidin, an Fe regulating peptide hormone, causing the down-regulation of Fe absorption and erythropoiesis(Reference Nemeth, Tuttle and Powelson62).

Genetic Hb disorders have been identified as important contributors to anaemia. In a study of WRA in Cambodia, Hb E homozygous disorder was one of the strongest predictors of Hb, even before Fe status; heterozygous Hb E and Constant Spring traits were also important statistical predictors of Hb concentration(Reference Karakochuk, Whitfield and Barr63). Pasricha and colleagues also showed a significant association between β-thalassaemia minor and Hb in Indian children(Reference Pasricha, Black and Muthayya7). Our results complement these findings by indicating a direct association between β-thalassaemia and Hb concentration in our population of women.

The population studied showed a high prevalence of concurrent Fe deficiency and anaemia; therefore, the statistical contributions of nutritional predictors of anaemia are likely generalisable to populations with similarly high prevalence of Fe deficiency and anaemia but needs to be explored further in populations where Fe deficiency may not be associated with such a high proportion of anaemia, such as settings with malaria or high proportions of genetic abnormalities. Our study captures low prevalence of acute inflammation (CRP) and higher prevalence of chronic inflammation (AGP), which could be reflective of seasonality. October to December is the beginning of winter, and the post-rainy season when episodes of diarrhoea and incidence of malaria are typically lower compared to the summer months(Reference Lauderdale, Caminade and Heath64,Reference Ahmed, Farheen and Muzaffar65) . Results are likely to be different in seasons with higher incidence of infectious disease. The implications of this seasonal pattern of inflammation for the potential for impact of Fe interventions should also be explored.

The cross-sectional nature of the data does not allow us to establish the associations as causal. Further, path analysis could be biased when applied to cross-sectional data, particularly when the effects of mediation unfold over time(Reference Maxwell and Cole66). Longitudinal data should be used to confirm these findings and estimates of association. Ten of the twenty-five districts were not randomly selected because of the dual purpose of this survey, serving as a state survey and a baseline evaluation to a double fortified salt programme. However, we expect that results are representative of the state because of the geographical spread of selected districts, design and rigorous sampling methods within each district. Our sample of children unexpectedly included fewer girls than boys, which could have introduced some bias in our results given that certain blood disorders, such as glucose-6-phosphate dehydrogenase deficiency, are more common in males than females(Reference Goyal, Garg and Goyal67). Although we tested extensively for nutritional deficiencies, inflammatory biomarkers and more distal social and environmental factors which may affect anaemia, we were not able to test for all possible predictors. Importantly, we did not conduct egg counts of intestinal parasites, nor did we test for genetic Hb disorders other than β-thalassaemia. The use of path analysis allowed for a more complex view of the predictors of anaemia in this population, accounting for both direct and indirect associations between predictors, and allowing for comparability in magnitudes of associations between predictors and between settings.

The associations observed in this analysis begin to illustrate the complex aetiology of anaemia and the potential interrelationship between several nutritional and immune function-related causes, as well as their relations with more distal determinants such as WASH and food security. In both women and children, ferritin, a marker reflective of Fe stores, is still the single strongest correlate of Hb concentration, but other nutritional deficiencies are also important statistical predictors. The nature of these relationships, particularly with infection and inflammation, however, is not straightforward, and the extent to which Fe and other nutritional interventions can be fully effective to address anaemia is not clear. Even for the proportion of anaemia that, according to our model, is attributable to Fe deficiency, other causes may inhibit a response to Fe interventions if not simultaneously addressed. Our models suggest that interventions using experimental study designs that simultaneously address multiple nutritional predictors as well as control of infection and inflammation will have greater potential to reduce the prevalence of anaemia. More complex models and comprehensive measurements, as introduced in this study, are needed to more fully understand the aetiology of anaemia and populations’ potential responses to interventions, so as to design cost-effective solutions to an important public health problem.

Acknowledgements

We wish to thank Professor Madan Godbole for his contributions to the implementation of the survey, as well as the women and children who participated in this study.

Financial support

Funding was provided by the Bill and Melinda Gates Foundation through a grant to GAIN.

Conflict of interest

None of the authors declares a conflict of interest with regard to this manuscript. All authors have read and approved the submitted manuscript.

Authorship

The authors’ responsibilities were as follows: all co-authors contributed to the design of the study and critically reviewed the manuscript. L.M.L. participated in the development of study protocols and designed the anaemia aetiology component, coordinated data collection, analysed the data and drafted the initial manuscript; L.M.N. conceived the design for the state survey and evaluation, secured funding and holds overall responsibility for the study. T.T. and J.H. prepared the sampling strategy and statistical considerations. A.V.K. and S.S. supervised study preparations and data collection. V.O.A. contributed to data analysis and manuscript preparation. All authors read and approved the final manuscript as submitted.

Supplementary material

For supplementary material accompanying this paper visit https://doi.org/10.1017/S1368980024000028

Ethics of human subject participation

This study was conducted according to the guidelines laid down in the Declaration of Helsinki, and all procedures involving research study participants were approved by the Institutional Review Boards of Sanjay Gandhi Post Graduate Institute of Medical Sciences, Lucknow, India, and St John’s Medical College and Hospital Institutional Ethics Committee, Bangalore, India. Written informed consent was obtained from all women participants and the primary caregivers of all children participating in the study.

The impact evaluation was registered with the Registry for International Development Impact Evaluations (RIDIE-STUDY-ID-58f6eeb45c050).

Footnotes

a

Formerly Global Alliance for Improved Nutrition (GAIN), Rue Varembé 7, 1202 Geneva, Switzerland.

References

Stevens, GA, Finucane, MM, De-Regil, LM et al. (2013) Global, regional, and national trends in haemoglobin concentration and prevalence of total and severe anaemia in children and pregnant and non-pregnant women for 1995–2011: a systematic analysis of population-representative data. Lancet Global Health 1, e1625.CrossRefGoogle ScholarPubMed
DeMaeyer, E & Adiels-Tegman, M (1985) The prevalence of anaemia in the world. World Health Statistics Quarterly Rapport trimestriel statistiques sanitaires mondiales 38, 302316.Google ScholarPubMed
Engle-Stone, R, Aaron, GJ, Huang, J et al. (2017) Predictors of anemia in preschool children: Biomarkers Reflecting Inflammation and Nutritional Determinants of Anemia (BRINDA) project. Am J Clin Nutr 106, 402s415s.CrossRefGoogle ScholarPubMed
Wirth, JP, Woodruff, BA, Engle-Stone, R et al. (2017) Predictors of anemia in women of reproductive age: Biomarkers Reflecting Inflammation and Nutritional Determinants of Anemia (BRINDA) project. Am J Clin Nutr 106, 416s427s.Google ScholarPubMed
Balarajan, Y, Ramakrishnan, U, Ozaltin, E et al. (2011) Anaemia in low-income and middle-income countries. Lancet (London, England) 378, 21232135.CrossRefGoogle ScholarPubMed
Nguyen, PH, Gonzalez-Casanova, I, Nguyen, H et al. (2015) Multicausal etiology of anemia among women of reproductive age in Vietnam. Eur J Clin Nutr 69, 107.CrossRefGoogle ScholarPubMed
Pasricha, SR, Black, J, Muthayya, S et al. (2010) Determinants of anemia among young children in rural India. Pediatrics 126, 20093108.CrossRefGoogle ScholarPubMed
Soofi, S, Khan, GN, Sadiq, K et al. (2017) Prevalence and possible factors associated with anaemia, and vitamin B 12 and folate deficiencies in women of reproductive age in Pakistan: analysis of national-level secondary survey data. BMJ Open 7, e018007.CrossRefGoogle ScholarPubMed
Moor, MA, Fraga, MA, Garfein, RS et al. (2017) Individual and community factors contributing to anemia among women in rural Baja California, Mexico. PloS one 12, e0188590.CrossRefGoogle ScholarPubMed
Wirth, JP, Rohner, F, Woodruff, BA et al. (2016) Anemia, micronutrient deficiencies, and malaria in children and women in Sierra Leone Prior to the ebola outbreak - findings of a cross-sectional study. PloS one 11, e0155031.CrossRefGoogle Scholar
IIPS (2016) National Family Health Survey (NFHS-4), 2015–2016. India. https://dhsprogram.com/pubs/pdf/fr339/fr339.pdf (accessed November 2018).Google Scholar
Cyriac, S, Webb Girard, A, Ramakrishnan, U et al. (2022) Making programmes worth their salt: assessing the context, fidelity and outcomes of implementation of the double fortified salt programme in Uttar Pradesh, India. Matern Child Nutr 18, e13243.CrossRefGoogle ScholarPubMed
UNICEF (2005) Multiple Indicator Cluster Survey Manual, 2005: Monitoring the Situation of Children and Women. New York: UNICEF.Google Scholar
Haas, JD, Rahn, M, Venkatramanan, S et al. (2014) Double-fortified salt is efficacious in improving indicators of iron deficiency in female Indian tea pickers. J Nutr 144, 957964.CrossRefGoogle ScholarPubMed
Pasricha, S-R, Drakesmith, H, Black, J et al. (2013) Control of iron deficiency anemia in low-and middle-income countries. Blood, J Am Soc Hematol 121, 26072617.Google ScholarPubMed
Kennedy, G, Ballard, T & Dop, MC (2015) Guidelines for Measuring Household and Individual Dietary Diversity. Nutrition and Consumer Protection Division, Food and Agriculture Organization of the United Nations. Rome: FAO.Google Scholar
WHO (2010) Indicators for Assessing Infant and Young Child Feeding Practices: Part 2: Measurement. Geneva: WHO; available at http://apps.who.int/iris/bitstream/handle/10665/44306/9789241599290_eng.pdf;jsessionid=D3CF1668887A94E42C4BDC192A96E8E9?sequence=1 (accessed January 2014).Google Scholar
FAO (2023) The Food Insecurity Experience Scale. https://www.fao.org/in-action/voices-of-the-hungry/fies/en/ (accessed November 2023).Google Scholar
de Onis, M, Onyango, AW, Van den Broeck, J et al. (2004) Measurement and standardization protocols for anthropometry used in the construction of a new international growth reference. Food Nutr Bull 25, S2736.CrossRefGoogle ScholarPubMed
Fernald, LCH, Kariger, P, Engle, P et al. (2009) Examining Early Child Development in Low-Income Countries. Washington, DC: The World Bank.CrossRefGoogle Scholar
Cordero, AM, Crider, KS, Rogers, LM et al. (2015) Optimal serum and red blood cell folate concentrations in women of reproductive age for prevention of neural tube defects: world Health Organization guidelines. Morbidity Mortality Weekly Rep 64, 421.Google ScholarPubMed
O’broin, S & Kelleher, B (1992) Microbiological assay on microtitre plates of folate in serum and red cells. J Clin Pathol 45, 344347.CrossRefGoogle ScholarPubMed
Pfeiffer, CM, Zhang, M, Lacher, DA et al. (2011) Comparison of serum and red blood cell folate microbiologic assays for national population surveys. J Nutr 141, 14021409.CrossRefGoogle ScholarPubMed
Webb, AL, Stein, AD, Ramakrishnan, U et al. (2006) A simple index to measure hygiene behaviours. Int J Epidemiol 35, 14691477.CrossRefGoogle ScholarPubMed
WHO (2014) Haemoglobin Concentrations for the Diagnosis of Anaemia and Assessment of Severity. Geneva, Switzerland: World Health Organization; 2011. Contract No: WHO/NMH/NHD/MNM/111. http://apps.who.int/iris/bitstream/handle/10665/85839/WHO_NMH_NHD_MNM_11.1_eng.pdf?sequence=3 (accessed January 2014).Google Scholar
WHO (2020) WHO Guideline on Use of Ferritin Concentrations to Assess Iron Status in Populations. Geneva: World Health Organization.Google Scholar
WHO (2011) Serum Retinol Concentrations for Determining the Prevalence of Vitamin A Deficiency in Populations. Geneva: WHO; available at http://www.who.int/vmnis/indicators/retinol.pdf (accessed January 2015).Google Scholar
Suchdev, PS, Namaste, SM, Aaron, GJ et al. (2016) Overview of the Biomarkers Reflecting Inflammation and Nutritional Determinants of Anemia (BRINDA) project. Adv Nutr (Bethesda, Md) 7, 349356.CrossRefGoogle ScholarPubMed
Namaste, SM, Rohner, F, Huang, J et al. (2017) Adjusting ferritin concentrations for inflammation: Biomarkers Reflecting Inflammation and Nutritional Determinants of Anemia (BRINDA) project. Am J Clin Nutr 106, 359S371S.CrossRefGoogle ScholarPubMed
de Benoist, B (2008) Conclusions of a WHO Technical Consultation on folate and vitamin B12 deficiencies. Food Nutr Bull 29, S238S244.CrossRefGoogle ScholarPubMed
Brown, KH, Rivera, JA, Bhutta, Z, et al. International Zinc Nutrition Consultative Group (IZiNCG) technical document# 1. Assessment of the risk of zinc deficiency in populations and options for its control. Food Nutr Bull 25(1 Suppl 2), S99S203.Google Scholar
McDonald, CM, Suchdev, PS, Krebs, NF et al. (2020) Adjusting plasma or serum zinc concentrations for inflammation: Biomarkers Reflecting Inflammation and Nutritional Determinants of Anemia (BRINDA) project. Am J Clin Nutr 111, 927937.CrossRefGoogle ScholarPubMed
Pfeiffer, CM, Sternberg, MR, Hamner, HC et al. (2016) Applying inappropriate cutoffs leads to misinterpretation of folate status in the US population. Am J Clin Nutr 104, 16071615.CrossRefGoogle ScholarPubMed
WHO (2014) C-Reactive Protein Concentrations as a Marker of Inflammation or Infection for Interpreting Biomarkers of Micronutrient Status. Geneva: World Health Organization; available at http://apps.who.int/iris/bitstream/10665/133708/1/WHO_NMH_NHD_EPG_14.7_eng.pdf?ua=1 (accessed November 2015).Google Scholar
Erhardt, JG, Estes, JE, Pfeiffer, CM et al. (2004) Combined measurement of ferritin, soluble transferrin receptor, retinol binding protein, and C-reactive protein by an inexpensive, sensitive, and simple sandwich enzyme-linked immunosorbent assay technique. J Nutr 134, 31273132.CrossRefGoogle ScholarPubMed
Bain, BJ (2008) Haemoglobinopathy Diagnosis. Oxford, UK: John Wiley & Sons.Google Scholar
UNICEF (1996) The State of the World’s Children. New York, NY: Oxford University Press for UNICEF. https://www.unicef.org/media/84766/file/SOWC-1998.pdf Google Scholar
Bruzzi, P, Green, SB, Byar, DP et al. (1985) Estimating the population attributable risk for multiple risk factors using case-control data. Am J Epidemiol 122, 904914.CrossRefGoogle ScholarPubMed
Bentler, PM (1990) Comparative fit indexes in structural models. Psychol Bull 107, 238246.CrossRefGoogle ScholarPubMed
Tucker, LR & Lewis, C (1973) A reliability coefficient for maximum likelihood factor analysis. Psychometrika 38, 110.CrossRefGoogle Scholar
Lt, Hu & Bentler, PM (1999) Cutoff criteria for fit indexes in covariance structure analysis: conventional criteria v. new alternatives. Struct Equation Modeling: Multidisciplinary J 6, 155.Google Scholar
Steiger, JH (1990) Structural model evaluation and modification: an interval estimation approach. Multivariate Behav Res 25, 173180.CrossRefGoogle ScholarPubMed
Enders, CK & Bandalos, DL (2001) The relative performance of full information maximum likelihood estimation for missing data in structural equation models. Struct Equation Modeling 8, 430457.CrossRefGoogle Scholar
Chaparro, CM & Suchdev, PS (2019) Anemia epidemiology, pathophysiology, and etiology in low-and middle-income countries. Ann NY Acad Sci 1450, 1531.CrossRefGoogle ScholarPubMed
Righetti, AA, Koua, A-YG, Adiossan, LG et al. (2012) Etiology of anemia among infants, school-aged children, and young non-pregnant women in different settings of south-central Côte d’Ivoire. Am J Trop Med Hyg 87, 425.CrossRefGoogle Scholar
Atkinson, SH, Armitage, AE, Khandwala, S et al. (2014) Combinatorial effects of malaria season, iron deficiency, and inflammation determine plasma hepcidin concentration in African children. Blood 123, 32213229.CrossRefGoogle ScholarPubMed
da Silva Lopes, K, Yamaji, N, Rahman, MO et al. (2021) Nutrition-specific interventions for preventing and controlling anaemia throughout the life cycle: an overview of systematic reviews. Cochrane Database Syst Rev issue 9, CD013092.Google Scholar
Nair, KM, Fernandez-Rao, S, Nagalla, B et al. (2016) Characterisation of anaemia and associated factors among infants and pre-schoolers from rural India. Public Health Nutr 19, 861871.CrossRefGoogle ScholarPubMed
Ndiaye, NF, Idohou-Dossou, N, Diouf, A et al. (2018) Folate deficiency and anemia among women of reproductive age (15–49 Years) in Senegal: results of a national cross-sectional survey. Food Nutr Bull 39, 6574.CrossRefGoogle ScholarPubMed
Arsenault, JE, Mora-Plazas, M, Forero, Y et al. (2009) Hemoglobin concentration is inversely associated with erythrocyte folate concentrations in Colombian school-age children, especially among children with low vitamin B12 status. Eur J Clin Nutr 63, 842849.CrossRefGoogle ScholarPubMed
Morris, MS, Jacques, PF, Rosenberg, IH et al. (2007) Folate and vitamin B-12 status in relation to anemia, macrocytosis, and cognitive impairment in older Americans in the age of folic acid fortification. Am J Clin Nutr 85, 193200.CrossRefGoogle ScholarPubMed
FFI (2018) Country Profile - Colombia. Food Fortification Initiative. =http://ffinetwork.org/country_profiles/country.php?record=44 (accessed August 2018).Google Scholar
Caicedo, O, Villamor, E, Forero, Y et al. (2010) Relation between vitamin B12 and folate status, and hemoglobin concentration and parasitemia during acute malaria infections in Colombia. Acta Trop 114, 1721.CrossRefGoogle ScholarPubMed
Woeller, CF, Fox, JT, Perry, C et al. (2007) A ferritin-responsive internal ribosome entry site regulates folate metabolism. J Biol Chem 282, 2992729935.CrossRefGoogle ScholarPubMed
Shayeghi, M, Latunde-Dada, GO, Oakhill, JS et al. (2005) Identification of an intestinal heme transporter. Cell 122, 789801.CrossRefGoogle ScholarPubMed
Qiu, A, Jansen, M, Sakaris, A et al. (2006) Identification of an intestinal folate transporter and the molecular basis for hereditary folate malabsorption. Cell 127, 917928.CrossRefGoogle ScholarPubMed
Pellis, L, Dommels, Y, Venema, D et al. (2008) High folic acid increases cell turnover and lowers differentiation and iron content in human HT29 colon cancer cells. Br J Nutr 99, 703708.CrossRefGoogle ScholarPubMed
Reissman, K (1964) Protein metabolism and erythropoiesis. II. Erythropoietin responsiveness and erythropoietin formation in protein deprived rats. Blood 23, 146153.CrossRefGoogle Scholar
Scrimshaw, NS (1977) Effect of infection on nutrient requirements. Am J Clin Nutr 30, 15361544.CrossRefGoogle ScholarPubMed
Dewey, KG & Mayers, DR (2011) Early child growth: how do nutrition and infection interact? Matern Child Nutr 7, 129142.CrossRefGoogle ScholarPubMed
Kotze, SR, Pedersen, OB, Petersen, MS et al. (2016) Low-grade inflammation is associated with lower haemoglobin levels in healthy individuals: results from the Danish blood donor study. Vox Sang 111, 144150.CrossRefGoogle ScholarPubMed
Nemeth, E, Tuttle, MS, Powelson, J et al. (2004) Hepcidin regulates cellular iron efflux by binding to ferroportin and inducing its internalization. Science (New York, NY) 306, 20902093.CrossRefGoogle ScholarPubMed
Karakochuk, CD, Whitfield, KC, Barr, SI et al. (2015) Genetic hemoglobin disorders rather than iron deficiency are a major predictor of hemoglobin concentration in women of reproductive age in rural prey Veng, Cambodia. J Nutr 145, 134142.CrossRefGoogle Scholar
Lauderdale, JM, Caminade, C, Heath, AE et al. (2014) Towards seasonal forecasting of malaria in India. Malar J 13, 120.CrossRefGoogle ScholarPubMed
Ahmed, SF, Farheen, A, Muzaffar, A et al. (2008) Prevalence of diarrhoeal disease, its seasonal and age variation in under-fives in Kashmir, India. Int J Health Sci 2, 126.Google ScholarPubMed
Maxwell, SE & Cole, DA (2007) Bias in cross-sectional analyses of longitudinal mediation. Psychol Method 12, 23.CrossRefGoogle ScholarPubMed
Goyal, M, Garg, A, Goyal, MB et al. (2015) Newborn screening for G6PD deficiency: a 2-year data from North India. Indian J Public Health 59, 145148.Google ScholarPubMed
Figure 0

Table 1 Descriptive characteristics of non-pregnant mothers of reproductive age and preschool-age children living in Uttar Pradesh*

Figure 1

Table 2. Health and nutrition characteristics of preschool-age children living in Uttar Pradesh*

Figure 2

Table 3 Health and nutrition characteristics of mothers of reproductive age living in Uttar Pradesh

Figure 3

Table 4 Multivariable analysis of the risk factors for anaemia and their population attributable fraction in preschool-age children*

Figure 4

Table 5 Multivariable analysis of the risk factors for anaemia and their population attributable fraction in mothers of reproductive age*

Figure 5

Fig. 1 Path model of the predictors of Hb concentration in preschool-age children living in Uttar Pradesh.Note: Results are presented as standardised estimates, adjusted for age in months. The model utilised log transformed Zn, folate, vitamin B12, retinol, CRP and AGP. WASH is represented in quintiles; all other variables are continuous scores or concentrations. Thin grey arrows represent non-significant associations; thick black arrows represent significant associations. Model fit statistics: RMSEA = 0·057; CFI = 0·960; TLI = 0·836; SRMR = 0·0034. Direct associations between inflammation biomarkers and nutritional biomarkers were estimated, but not all are presented; significant direct associations were also found between AGP and Zn (β = –0·15*), AGP and vitamin B12 (β = 0·02*), and CRP and vitamin B12 (β = –0·01*). AGP, α-1 acid glycoprotein; CRP, C-reactive protein; DD, dietary diversity score; FI, food insecurity score; WASH, water, sanitation and hygiene; RMSEA, root mean square error of approximation; CFI, comparative fit index; TLI, Tucker Lewis index; SRMR, standardised root mean squared residual. † Zn adjusted for time of processing and fasting. *P < 0·05. **P < 0·01. ***P < 0·001

Figure 6

Fig. 2 Path model of the predictors of Hb concentration in mothers of reproductive age living in Uttar Pradesh.Note: Results are presented as standardised estimates. The model utilised log transformed Zn, folate, vitamin B12, retinol, CRP and AGP. WASH is represented in quintiles; all other variables are continuous scores or concentrations. Thin grey arrows represent non-significant associations; thick black arrows represent significant associations. Model fit statistics: RMSEA = 0·058; CFI = 0·926; TLI = 0·773; SRMR = 0·036. Direct associations between inflammation biomarkers and nutritional biomarkers were estimated, but not all are presented; significant associations were also found between AGP and vitamin B12 (β = 0·11*) and CRP and folate (β = 0·09**). AGP, α-1 acid glycoprotein; CRP, C-reactive protein; DD, dietary diversity score; FI, food insecurity score; WASH, water, sanitation and hygiene; RMSEA, root mean square error of approximation; CFI, comparative fit index; TLI, Tucker Lewis index; SRMR, standardised root mean squared residual. † Zn adjusted for time of processing and fasting. *P < 0·05. **P < 0·01. ***P < 0·001

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