Hostname: page-component-cd9895bd7-dzt6s Total loading time: 0 Render date: 2024-12-18T07:15:28.720Z Has data issue: false hasContentIssue false

Serum retinol in 1–6-year-old children from a low socio-economic South African community with a high intake of liver: implications for blanket vitamin A supplementation

Published online by Cambridge University Press:  23 August 2011

Martha E van Stuijvenberg*
Affiliation:
Nutritional Intervention Research Unit, Medical Research Council, PO Box 19070, Tygerberg 7505, Cape Town, South Africa
Serina E Schoeman
Affiliation:
Nutritional Intervention Research Unit, Medical Research Council, PO Box 19070, Tygerberg 7505, Cape Town, South Africa
Carl J Lombard
Affiliation:
Biostatistics Unit, Medical Research Council, Cape Town, South Africa
Muhammad A Dhansay
Affiliation:
Nutritional Intervention Research Unit, Medical Research Council, PO Box 19070, Tygerberg 7505, Cape Town, South Africa Executive Directorate Research, Medical Research Council, Cape Town, South Africa
*
*Corresponding author: Email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective

To assess serum retinol, liver intake patterns, breast-feeding history and anthropometric status in pre-school children of a low socio-economic community where liver is regularly consumed.

Design

Cross-sectional study.

Setting

Northern Cape Province, South Africa.

Subjects

Children aged 1–6 years (n 243) who attended the local primary health-care facility and had not received a vitamin A supplement in the 6 months preceding the study. Non-pregnant female caregivers (n 225), below 50 years of age, were also assessed.

Results

Despite stunting, underweight and wasting being prevalent in 40·5 %, 23·1 % and 8·4 % of the children, only 5·8 % had serum retinol concentrations < 20 μg/dl, which is in sharp contrast to the national prevalence of 63·6 %. None of the caregivers were vitamin A deficient. Liver was eaten by 89·2 % of children, with 87 % of households eating liver at least once monthly and 30 % eating it at least once weekly; liver was introduced into the diet of the children at a median age of 18 months. Ninety-three per cent of the children were being breast-fed or had been breast-fed in the past; children were breast-fed to a median age of 18 months. A significant negative correlation was found between educational level of the caregiver and frequency of liver intake (r = −0·143, P=0·032). There was no correlation between serum retinol and indicators of anthropometric or socio-economic status.

Conclusions

The blanket approach in applying the national vitamin A supplementation programme may not be appropriate for all areas in the country, even though the community may be poor and undernourished.

Type
Research paper
Copyright
Copyright © The Authors 2011

Vitamin A deficiency continues to be a public health problem in many developing countries and is estimated to affect 190 million pre-school children globally(1). The primary cause of vitamin A deficiency is insufficient intake of animal products containing preformed vitamin A or plant foods containing β-carotene. Supplementing children between 6 months and 5 years of age with vitamin A has been shown to reduce all-cause mortality by 23–34 %(Reference Beaton, Martorell and Aronson2Reference Glasziou and Mackerras4). As a result, periodic high-dose vitamin A supplementation has been recommended in countries where more than 15 % of the under-5 population have serum retinol concentrations below 20 μg/dl(Reference Sommer and Davidson5), or where the under-5 mortality rate exceeds 70 deaths per 1000 live births(6). In South Africa, a national high-dose vitamin A supplementation programme, targeting 6–59-month-old children at public health facilities, as well as postpartum women within 6–8 weeks after delivery, was introduced in 2002(7).

While vitamin A supplementation undoubtedly has benefits and has been shown to save lives in severely vitamin-A-deficient children(Reference West, Klemm and Sommer8), there are indications that high-dose vitamin A supplementation may increase morbidity in children who are not deficient in vitamin A, especially with regard to lower respiratory tract infections(Reference Chen, Zhuo and Yuan9). Concerns regarding the universal application of vitamin A supplementation have been expressed by several authors in the past(Reference Dhansay10Reference Grotto, Mimouni and Gdalevich12), and more recently in a comprehensive commentary by Latham(Reference Latham13), in which he challenges the wisdom and validity of regularly providing massive doses of vitamin A to children, especially those who are not vitamin A deficient. Latham argues that vitamin A capsules were originally intended as a short-term emergency measure for areas where severe vitamin A deficiency is present, that it is not sustainable, and that it may act as a policy barrier impeding more sustainable food-based approaches. He further maintains that vitamin A programmes do not reach the 10–20 % in greatest need and moreover that there is no certainty that vitamin A programmes are not doing harm in populations where vitamin A status is sufficient(Reference Latham13).

In South Africa, according to a recent survey, the national prevalence of vitamin A deficiency (serum retinol <20 μg/dl) in 1–9-year-old children is 63·6 %(Reference Labadarios14). However, South Africa is a country that is diverse in terms of culture, geography and socio-economic status, and this diversity is also reflected in the eating habits of its population. Vitamin A deficiency, for example, varies between provinces, with the prevalence being the highest in KwaZulu-Natal (88·9 %) and the lowest in the Northern Cape (23·0 %)(Reference Labadarios14). There may also be pockets where, due to unique eating patterns, vitamin A deficiency may not be present at all. Baseline data from an Fe fortification trial in 6–9-year-old schoolchildren from a Northern Cape community during 2002 showed that vitamin A deficiency, contrary to expectation, was virtually absent despite high levels of poverty, stunting and underweight(Reference Van Stuijvenberg, Smuts and Wolmarans15). These children were not exposed to vitamin A supplementation during their pre-school years and further investigation revealed a regular intake of liver(Reference Van Stuijvenberg, Smuts and Wolmarans15), which is a concentrated source(Reference Wolmarans, Danster and Dalton16) of preformed vitamin A.

The prevalence of vitamin A deficiency in the under-5 s from this community, i.e. the age group targeted by the vitamin A supplementation programme, is not known. The aim of the present study was to assess serum retinol, liver intake patterns, breast-feeding history and anthropometric status in the pre-school children of this ‘liver eating’ community, and to also obtain information on the vitamin A status of the caregiver.

Methods

Study population and design

The study was undertaken in Calvinia-West. This is the low socio-economic section of the town of Calvinia, which is situated in the Hantam district of the Northern Cape Province and approximately 470 km north of Cape Town. The area is characterised by arid conditions, and plant foods are not cultivated or frequently consumed in the area. Sheep farming is the main industry. The Northern Cape Province is the largest of the nine South African provinces, but the smallest in terms of population size, and has the highest levels of stunting and underweight in the country(Reference Labadarios14).

The study was a cross-sectional one of the pre-school children and their female caregivers attending the primary health-care facility in Calvinia-West during the period April to November 2008. Because national data showed the prevalence of vitamin A deficiency in the 7–9-year-old age group to be also above 60 %(Reference Labadarios14), all pre-school children visiting the health facility, irrespective of age, were included in the study. Assuming a vitamin A deficiency prevalence of 5 %, and specifying the precision level of a two-sided 95 % CI as 3 %, a sample size of 203 was required, using the ‘Large Sample Normal Approximation’. For inclusion in the study, the child should have been accompanied by the caregiver who was responsible for the child's food, and should not have received a vitamin A supplement in the 6 months that preceded the assessment date (i.e. was due for his/her next vitamin A supplement according to national supplementation protocol, whereby children aged 6–11 months should receive a single dose of 100 000 IU (30 000 μg retinol equivalents, RE) and children aged 12–59 months receive a dose of 200 000 IU (60 000 μg RE) every 6 months). The term ‘caregiver’ includes the child's biological mother and is used as such throughout the text. If a child presented with a fever he/she was not recruited for the study. Only non-pregnant caregivers below 50 years of age were included for anthropometric and biochemical measurements. If a caregiver visited the health facility with more than one child, the other children were also included in the study, but the caregiver's anthropometric and vitamin A status was not assessed again. Door-to-door visits, as well as the local radio station, were used to inform mothers and caregivers about the project, and to encourage them to bring their children to the health facility. This resulted in those who do not regularly attend the facility also being surveyed. A nationwide vitamin A supplementation campaign took place during September 2008 but, at the request of the researchers, was postponed in the Calvinia area until after completion of our study.

The study was approved by the Ethics Committee of the South African Medical Research Council, and permission was obtained from both the provincial and national Departments of Health. Written informed consent was obtained from the caregiver of each participant.

Measurements

Biochemical indicators

Blood (5 ml) from the caregiver and child was obtained via antecubital venepuncture, before the child received a vitamin A supplement as per protocol. Blood was centrifuged at the site, using a portable centrifuge, and serum removed and stored at −20°C until collected by a member of the research team who visited the study site at regular intervals. Care was taken throughout the process to protect blood samples from direct sunlight. At the Medical Research Council in Cape Town, samples were stored at −80°C until analysed. Serum retinol was determined, under dimmed light, by a reversed-phase HPLC method which is based on the method described by Catignani and Bieri(Reference Catignani and Bieri17). The CV (intra- and inter-assay) for this method is <4 %. Serum C-reactive protein (CRP) was measured as an indicator of infection by means of an ELISA method (DRG Diagnostics, Marburg, Germany).

Anthropometric indicators

Weight was measured in light clothing and without shoes to the nearest 0·05 kg using an electronic load cell scale (UC-321 Personal Precision Health Scale; A&D Company, Ltd., Tokyo, Japan). The accuracy of the scale was checked against a standard weight at regular intervals. Recumbent length of children younger than 2 years was measured to the nearest 0·1 cm on a horizontally placed measuring board with a fixed headboard and a moveable foot-piece. Height of the caregivers and children aged ≥ 2 years was measured to the nearest 0·1 cm using a wooden board with a fitted measuring tape and a moveable head-piece. Measurements were taken by trained fieldworkers whose measurements and technique were validated against that of a researcher. Height and weight were expressed as height-for-age, weight-for-age and weight-for-height Z-scores using the WHO growth standards(18). Date of birth and birth weight were obtained from the child's Road to Health card (RTHC).

Questionnaire information

A questionnaire, administered through an interview with the caregiver, was used to obtain information on socio-economic status, liver intake and breast-feeding history. History of vitamin A supplementation (dosage and date) was obtained from the child's RTHC.

Statistical analysis

Data were checked for normal distribution by using the Kolmogorov–Smirnov test for normality and analysed using the PASW (formerly SPSS) statistical software package version 18·0 (SPSS Inc., Chicago, IL, USA). Continuous data were expressed as mean (standard deviation or 95 % confidence interval) or when not normally distributed as median (interquartile range). Categorical data were reported as percentages. Spearman's correlation coefficients were used to test for correlations between continuous variables. P values below 0·05 were considered statistically significant.

Results

The study comprised 243 pre-school children and 225 caregivers. The characteristics and socio-economic status of the study population is given in Table 1. The majority (89·3 %) of the caregivers were the biological mother of the child. The age of the children ranged between 1 and 6 years, with the majority being between 2 and 4 years old. Approximately half of the caregivers were single, i.e. had never been married nor lived with a partner. Only 15 % completed high school, while 33 % had 7 years or less of schooling. About 72 % were unemployed, and about 37 % were dependent on a relative or social grant as their main source of income.

Table 1 Characteristics and socio-economic status of the study population: children and their female caregivers visiting a primary health-care facility in a low socio-economic area in the Northern Cape Province, South Africa, April–November 2008

The anthropometric status of the children and caregivers is shown in Table 2. The prevalence of stunting, underweight and wasting was approximately double the national prevalence and, according to WHO criteria, can be classified as ‘very high’, ‘high’ and ‘medium to high’, respectively. Birth weight was below 2500 g in 28·1 % of the children. Only 12·2 % of caregivers were underweight (BMI < 18·5 kg/m2), but 28·8 % were stunted using the WHO height-for-age reference median for 18-year-old girls and assuming the caregiver's height had not changed since.

Table 2 Anthropometric status of children and their female caregivers visiting a primary health-care facility in a low socio-economic area in the Northern Cape Province, South Africa, April–November 2008

*South African national food consumption survey[Reference Labadarios14].

†Height-for-age (n 232), ‡weight-for-age (n 242) and §weight-for-height (n 191) Z-scores <−2 sd of the WHO reference median; the National Center for Health Statistics reference standards were used in the national survey and, when applied to our study population, the prevalence of stunting, underweight and wasting was 33·6 %, 26·0 % and 10·3 %, respectively.

∥Height-for-age Z-score <−2 sd of the WHO reference median for girls aged 18 years.

None of the children were exposed to vitamin A supplementation in the 6 months before the study, and almost 40 % had never received a vitamin A supplement; 77 % received no supplements in the past 18 months (Table 3). There was no correlation between supplementation history (months since last supplement) and serum retinol levels of the child. The serum retinol status of the children and their caregivers is shown in Table 4 and Fig. 1. Mean serum retinol in the children was 31·3 μg/dl, and only 5·8 % were vitamin A deficient (serum retinol < 20 μg/dl), which is considerably lower than the national prevalence of 63·6 %. None of the children had serum retinol concentrations < 10 μg/dl. In the caregivers, mean serum retinol was 55·1 μg/dl, which is double the national mean. None had serum retinol concentrations < 20 μg/dl, while 9 % (nineteen individuals) presented with serum retinol concentrations in excess of 75 μg/dl, and two individuals with levels above 100 μg/dl. There was a significant positive correlation between the serum retinol concentration of the caregiver and that of the child (r = 0·156; P = 0·023). CRP concentrations were raised in 6·4 % of the children and in 16·3 % of the caregivers, which was similar to the national figures (Table 4). Morbidity data, retrospectively collected during the survey, showed diarrhoea to have occurred in 2·9 % and acute respiratory infections in 16·0 % of the children during the 4 weeks that preceded the study. A significant negative correlation between CRP and serum retinol levels in both the child and the caregiver was found (r = −0·225; P = 0·001 and r = −0·181; P = 0·011, respectively). When CRP concentrations ≥ 10 mg/l were excluded from the data set, the prevalence of vitamin A deficiency in the children was 4·9 %. There was no significant correlation between serum retinol levels and the age or anthropometric status of the child, or any of the measured indicators of socio-economic status.

Table 3 History of vitamin A supplementation according to the clinic card (n 243) among children visiting a primary health-care facility in a low socio-economic area in the Northern Cape Province, South Africa, April–November 2008

Table 4 Serum retinol concentrations of children and their female caregivers visiting a primary health-care facility in a low socio-economic area in the Northern Cape Province, South Africa, April–November 2008

CRP, C-reactive protein.

*South African national food consumption survey[Reference Labadarios14].

†1 μg/dl = 0·035 μmol/l.

‡Mean and 95 % CI.

§Prevalence and 95 % CI.

∥For CRP, n 220 (children); n 196 (caregivers); n 1429 (SA children); n 1939 (SA women).

Fig. 1 (a) Distribution of serum retinol in pre-school children visiting a primary health-care facility in a low socio-economic area in the Northern Cape Province of South Africa, April–November 2008 (n 243). None of these children received a vitamin A supplement in the preceding 6 months and were therefore eligible for vitamin A supplementation according to national vitamin A supplementation guidelines; blood was taken before the child received the vitamin A capsule. (b) Distribution of serum retinol in female caregivers of the preschool children visiting the primary health-care facility (n 202)

The liver-eating patterns of the study population are shown in Table 5 and Fig. 2. Liver was eaten in almost all households (98·2 %), while almost 90 % of the pre-school children reportedly ate liver; 57 % of households ate liver during the 2 weeks that preceded the study. Liver was introduced into the diet of the child at a median age of 18 months, and 45 % had been eating liver from the age of 12 months or younger. The majority of households (87 %) ate liver at least once monthly while as many as 30 % reported eating liver at least once weekly (Fig. 2). There was a significant negative correlation between educational level of the caregiver and the frequency of liver intake in the household (r = −0·143; P = 0·032), but no correlation between the frequency of liver intake and serum retinol in either the mother or the child. Ninety-three per cent of the children were either being breast-fed at the time of the study or had been breast-fed in the past. Children were breast-fed to a median age of 18 months (Table 6). The liver-eating patterns of the breast-feeding mothers did not differ from those of the mothers not breast-feeding at the time of the study.

Table 5 Liver-eating patterns in the study population: children and their female caregivers visiting a primary health-care facility in a low socio-economic area in the Northern Cape Province, South Africa, April–November 2008

Fig. 2 Distribution of the frequency of liver consumption at household level among pre-school children and their female caregivers visiting a primary health-care facility in a low socio-economic area in the Northern Cape Province of South Africa, April–November 2008 (n 225)

Table 6 Current or past breast-feeding practices in the study population: children and their female caregivers visiting a primary health-care facility in a low socio-economic area in the Northern Cape Province, South Africa, April–November 2008

Discussion

Vitamin A deficiency is usually associated with low socio-economic conditions and poor anthropometric status(1, Reference Labadarios14, 19, Reference Ahmed, Azim and Akhtaruzzaman20). However, in the present study, despite high levels of poverty, stunting and underweight, subclinical vitamin A deficiency was prevalent in only 5·8 % of the pre-school population. No correlation was found between serum retinol and socio-economic or anthropometric status. The virtual absence of vitamin A deficiency in this Northern Cape community is in sharp contrast to the national prevalence of 63·6 %(Reference Labadarios14), and likely to be due to a regular consumption of liver by both the mother and the child, as well as a breast-feeding prevalence of more than 90 %.

Sheep farming is the main industry in the area and abattoir activities take place on a daily basis. Owing to this there is a regular surplus of organ meat, which is not exported to other parts of the country, resulting in liver being available in this community at low cost (<$US 0·5/kg liver) and often distributed via informal trading. The inverse relationship between educational level and frequency of liver consumption suggests that it is the poorer people, i.e. those most vulnerable to vitamin A deficiency, who consume liver most. It would thus appear as if this impoverished community has an inherent ‘survival mechanism’ that protects them against vitamin A deficiency. This regular consumption of liver by the poor is in contrast to elsewhere in Africa where cost was shown to be a major factor limiting liver consumption(Reference Nana, Brouwer and Zagré21). The lack of correlation between frequency of liver intake and serum retinol concentrations is probably a reflection of the adequate vitamin A status of this population; serum retinol is known to be homeostatically controlled and reflects body stores only when the latter are very low or very high(19).

In the South African national survey(Reference Labadarios14), children were included for vitamin A measurements irrespective of whether they received a high-dose vitamin A supplement during the previous 6 months or not. One of the strengths of our study is that children who received a vitamin A supplement during the preceding 6 months, according to their health card records, were not included in the study. The adequate vitamin A status in this population is therefore unlikely to be attributed to the vitamin A supplementation programme. This is further supported by the fact that 77 % of the children had not received a vitamin A supplement during the last 18 months, and that as many as 40 % had never been exposed to vitamin A supplementation in the past.

Liver is an excellent, but often underappreciated, source of preformed vitamin A, with sheep liver containing approximately 7800 μg retinol activity equivalents (RAE)/100 g(Reference Wolmarans, Danster and Dalton16). The estimated average daily requirement (EAR) for children aged 1–3 and 4–8 years is 210 and 275 μg RAE, respectively(22). This translates into a liver intake of only 3·5 g/d (or the equivalent of only 98 g liver/month) necessary to meet the vitamin A requirement of a 4–8-year-old child. We did not quantify liver intake but, based on previous unpublished observations, as well as preliminary data from a current study quantifying dietary intake in this population, an average portion size of 60 g in this age group was assumed. A 4–8-year-old child who consumes liver twice monthly would thus have 121 % (334 μg RAE) of his/her daily vitamin A needs met by the liver intake alone. Those who consume liver once weekly would have 243 % (669 μg RAE) of their vitamin A needs met, while those who consume liver twice weekly or more would have a vitamin A intake of at least 1337 μg RAE/d, i.e. 4·9 times the EAR and exceeding the upper intake level (UL) of 900 μg RAE by 48 %. These estimates do not take into account the contribution of other foods containing vitamin A, such as bread or maize meal, which are fortified with vitamin A and several other micronutrients, according to the national food fortification regulations(23). Bread is a staple food in this community, and assuming a consumption of 4 slices daily, an additional 80–90 μg RAE would be provided by bread.

Liver is also a good source of other micronutrients such as Fe, Zn and B-vitamins(Reference Wolmarans, Danster and Dalton16). However, in relation to its vitamin A content, liver contains considerably less of these micronutrients, and to meet the EAR for Fe and Zn, for example, liver would have to be consumed on a daily basis. Besides this not being feasible, liver, if eaten every day, may lead to an overload of vitamin A, as seen in case reports where liver, eaten several times a week for extended periods, resulted in severe cases of toxicity in young children(Reference Carpenter, Pettifor and Russel24, Reference Mahoney, Margolis and Knauss25) and adults(Reference Selhorst, Waybright and Jennings26).

The food-based approach is being advocated as the preferred way to prevent and control micronutrient deficiencies(Reference Thompson and Amoroso27). In the study community, liver is a favourite food, especially among poorer people, and a sustainable food-based vitamin A ‘intervention’ is therefore already in place. A concern in this low socio-economic Northern Cape community, however, is the high levels of stunting and underweight compared with the rest of South Africa. While vitamin A requirements are being met by the intake of liver, the children from this community are likely to suffer deprivation of various other nutrients, including Ca. There are, for example, indications of limited intakes of milk (other than breast milk), fresh fruit and vegetables in this population (J Nel, unpublished results). Providing children with regular high-dose vitamin A capsules – which they do not need – may lull health authorities into a false sense of security, believing that the children's nutritional needs are being attended to and that no further intervention is required. It also raises concerns of vitamin A excess in those sections of the population that eat liver at least once weekly and, in addition, regularly receive vitamin A capsules.

High-dose vitamin A supplementation is not without risk. Apart from the transient effects such as headache, nausea, vomiting, fever, diarrhoea and bulging of the anterior fontanel(Reference Sommer and West28), there are indications that vitamin A supplementation may increase respiratory tract infections in vitamin-A-sufficient children(Reference Chen, Zhuo and Yuan9). It is hypothesised that pharmacological doses of vitamin A given to children with adequate vitamin A stores may cause temporary dysregulation of the immune system, leading to increased susceptibility to infections(Reference Grotto, Mimouni and Gdalevich12). In mice, excessive intake of vitamin A has been shown to increase the risk and severity of asthma by exacerbating allergic airway inflammation and pulmonary hyper-responsiveness(Reference Schuster, Kenyon and Stephensen29). Accidental overdosing during vitamin A campaigns is also a risk, as was seen in India where thirty deaths were reported in children receiving higher than the recommended dosage during a nationwide campaign(Reference Kapil30). Recently there has been growing concern regarding the chronic effects of subclinical vitamin A toxicity. In adults, a long-term intake of preformed vitamin A of only twice the RDA has been associated with osteoporosis and hip fractures, presumably by stimulating bone resorption and inhibiting the ability of vitamin D to prevent Ca loss from the bone(Reference Penniston and Tanumihardjo31Reference Michaëlsson, Lithell and Vessby33). The long-term effect of periodic high-dose vitamin A supplements on the bone health of young children is not known, especially those who are vitamin A sufficient but compromised in terms of other micronutrients.

A limitation of the present study is that it does not include data from children below 1 year of age. It was, however, difficult to obtain blood from this age group. This is unfortunate, because younger children usually have a greater vulnerability to infections and vitamin A deficiency. However, the adequate vitamin A status of the mothers, and the fact that children are being breast-fed for extended periods, makes severe vitamin A deficiency in the under-1 children from this community unlikely.

Conclusions

The virtual absence of vitamin A deficiency in the study community highlights the fact that, although national data from a country indicate a public health problem, there may be pockets within that country that are different due to unique eating habits and local circumstances. Although the results of the present study pertain to only a small section of the South African population, there are indications that people from surrounding areas, where sheep farming is a major activity, have similar levels of liver consumption. An extensive survey is currently underway to establish how many of these ‘liver eating’ pockets exist in the country and where. Our results have important implications for the national vitamin A supplementation programme, in that the blanket approach in applying the programme may not be appropriate for all areas in the country, even though the community may be poor and undernourished.

Acknowledgements

Sources of funding: This work was supported by the Medical Research Council, Cape Town, South Africa, as well as by a grant from SIGHT AND LIFE, Basel, Switzerland. Conflict of interest: The authors have no conflict of interest. Authors’ contributions: M.E.v.S. and S.E.S. conceptualised and designed the study, collected and analysed the data, and wrote the manuscript; C.J.L. was responsible for the statistical aspects of the study; M.A.D. contributed to the conceptualisation and design of the study, and writing of the manuscript. Acknowledgements: The authors thank the mothers and children who participated in the study; the staff of the Calvinia-West primary health-care facility; J. Nel, D. Sass, A. van Jaarsveld, S. van Zyl, M. Cloete, Y. Hannah and F. Venter who assisted with the fieldwork; E. Harmse and M. Marais who analysed the blood samples; and the Department of Health for giving permission to conduct the study.

References

1.World Health Organization (2009) Global Prevalence of Vitamin A Deficiency in Populations at Risk 1995–2005. WHO Global Database on Vitamin A Deficiency. Geneva: WHO.Google Scholar
2.Beaton, GH, Martorell, R, Aronson, KJ et al. (1993) Effectiveness of Vitamin A Supplementation in the Control of Young Child Morbidity and Mortality in Developing Countries. Nutrition Policy Discussion Paper no. 13. Toronto: Canadian International Development Agency.Google Scholar
3.Fawzi, WW, Chalmers, TC, Herrera, G et al. (1993) Vitamin A supplementation and child mortality. A meta-analysis. JAMA 269, 898903.CrossRefGoogle ScholarPubMed
4.Glasziou, PP & Mackerras, DEM (1993) Vitamin A supplementation in infectious diseases: a meta-analysis. BMJ 306, 366370.CrossRefGoogle ScholarPubMed
5.Sommer, A & Davidson, FR (2002) Assessment and control of vitamin A deficiency: the Annecy Accords. J Nutr 132, 9 Suppl., S2845S2850.CrossRefGoogle ScholarPubMed
6.UNICEF (2007) Vitamin A Supplementation. A Decade of Progress. New York: UNICEF.Google Scholar
7.Department of Health (2004) Guidelines for the Implementation of Vitamin A Supplementation. Pretoria: Nutrition Directorate, Department of Health.Google Scholar
8.West, KP Jr, Klemm, RDW & Sommer, A (2010) Vitamin A saves lives. Sound science, sound policy. World Nutr 1, 211229.Google Scholar
9.Chen, H, Zhuo, Q, Yuan, W et al. (2008) Vitamin A for preventing acute lower respiratory tract infections in children up to seven years of age. Cochrane Database Syst Rev. issue 1, CD006090.Google ScholarPubMed
10.Dhansay, MA (2003) Vitamin A supplementation: a case of not seeing the wood for the trees? S Afr J Clin Nutr 16, 116117.Google Scholar
11.Fawzi, WW (2006) The benefits and concerns related to vitamin A supplementation. J Infect Dis 193, 756759.CrossRefGoogle ScholarPubMed
12.Grotto, I, Mimouni, M, Gdalevich, M et al. (2003) Vitamin A supplementation and childhood morbidity from diarrhea and respiratory infections: a meta-analysis. J Pediatr 142, 297304.CrossRefGoogle ScholarPubMed
13.Latham, M (2010) The great vitamin A fiasco. World Nutr 1, 1245.Google Scholar
14.Labadarios, D (editor) (2007) National Food Consumption Survey: Fortification Baseline South Africa, 2005. Pretoria: Department of Health.Google Scholar
15.Van Stuijvenberg, ME, Smuts, CM, Wolmarans, P et al. (2006) The efficacy of ferrous bisglycinate and electrolytic iron as fortificants in bread in iron-deficient school children. Br J Nutr 95, 532538.CrossRefGoogle ScholarPubMed
16.Wolmarans, P, Danster, N, Dalton, A et al. (editors) (2010) Condensed Food Composition Tables for South Africa. Cape Town: Medical Research Council.Google Scholar
17.Catignani, GL & Bieri, JG (1983) Simultaneous determination of retinol and α-tocopherol in serum or plasma by liquid chromatography. Clin Chem 29, 708712.CrossRefGoogle ScholarPubMed
18.World Health Organization (2006) Child Growth Standards. Length/Height-for-Age, Weight-for-Age, Weight-for-Length, Weight-for-Height and Body Mass Index for age. Methods and Development. Geneva: WHO.Google Scholar
19.World Health Organization (1996) Indicators for Assessing Vitamin A Deficiency and Their Application in Monitoring and Evaluating Intervention Programmes. Geneva: WHO.Google Scholar
20.Ahmed, F, Azim, A & Akhtaruzzaman, M (2003) Vitamin A deficiency in poor, urban, lactating women in Bangladesh: factors influencing vitamin A status. Public Health Nutr 6, 447452.CrossRefGoogle ScholarPubMed
21.Nana, CP, Brouwer, ID, Zagré, NM et al. (2006) Impact of promotion of mango and liver as sources of vitamin A for young children: a pilot study in Burkina Faso. Public Health Nutr 9, 808813.CrossRefGoogle ScholarPubMed
22.Food and Nutrition Board, Institute of Medicine (2001) Dietary Reference Intakes for Vitamin A, Vitamin K, Arsenic, Boron, Chromium, Copper, Iodine, Iron, Manganese, Molybdenum, Nickel, Silicon, Vanadium, and Zinc. Washington, DC: National Academy Press.Google Scholar
23.Department of Health (2003) Regulations relating to the fortification of certain foodstuffs. http://www.doh.gov.za/docs/regulations/2003/ffortification.html (accessed January 2011).Google Scholar
24.Carpenter, TO, Pettifor, JM, Russel, RM et al. (1987) Severe hypervitaminosis A in siblings: evidence of variable tolerance to retinol intake. J Pediatr 111, 507512.CrossRefGoogle ScholarPubMed
25.Mahoney, PC, Margolis, MT, Knauss, TA et al. (1980) Chronic vitamin A intoxication in infants fed chicken liver. Pedriatrics 65, 893897.CrossRefGoogle ScholarPubMed
26.Selhorst, JB, Waybright, EA, Jennings, S et al. (1984) Liver lover's headache: pseudotumor cerebri and vitamin A intoxication. JAMA 252, 3365.CrossRefGoogle ScholarPubMed
27.Thompson, B & Amoroso, L (editors) (2011) Combating Micronutrient Deficiencies: Food-Based Approaches. Rome: FAO and CABI.CrossRefGoogle Scholar
28.Sommer, A & West, KP Jr (editors) (1996) Supplementation. In Vitamin A Deficiency. Health, Survival, and Vision, pp. 388409. New York: Oxford University Press.CrossRefGoogle Scholar
29.Schuster, GU, Kenyon, NJ & Stephensen, CB (2008) Vitamin A deficiency decreases and high dietary vitamin A increases disease severity in the mouse model of asthma. J Immunol 180, 18341842.CrossRefGoogle ScholarPubMed
30.Kapil, U (2004) Update on vitamin A-related deaths in Assam, India. Am J Clin Nutr 80, 10821083.CrossRefGoogle ScholarPubMed
31.Penniston, KL & Tanumihardjo, SA (2006) The acute and chronic toxic effects of vitamin A. Am J Clin Nutr 83, 191201.CrossRefGoogle ScholarPubMed
32.Promislow, JHE, Goodman-Gruen, D, Slymen, DJ et al. (2002) Retinol intake and bone mineral density in the elderly: the Rancho Bernardo study. J Bone Miner Res 17, 13491358.CrossRefGoogle ScholarPubMed
33.Michaëlsson, K, Lithell, H, Vessby, B et al. (2003) Serum retinol levels and risk of fracture. N Engl J Med 348, 287294.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Characteristics and socio-economic status of the study population: children and their female caregivers visiting a primary health-care facility in a low socio-economic area in the Northern Cape Province, South Africa, April–November 2008

Figure 1

Table 2 Anthropometric status of children and their female caregivers visiting a primary health-care facility in a low socio-economic area in the Northern Cape Province, South Africa, April–November 2008

Figure 2

Table 3 History of vitamin A supplementation according to the clinic card (n 243) among children visiting a primary health-care facility in a low socio-economic area in the Northern Cape Province, South Africa, April–November 2008

Figure 3

Table 4 Serum retinol concentrations of children and their female caregivers visiting a primary health-care facility in a low socio-economic area in the Northern Cape Province, South Africa, April–November 2008

Figure 4

Fig. 1 (a) Distribution of serum retinol in pre-school children visiting a primary health-care facility in a low socio-economic area in the Northern Cape Province of South Africa, April–November 2008 (n 243). None of these children received a vitamin A supplement in the preceding 6 months and were therefore eligible for vitamin A supplementation according to national vitamin A supplementation guidelines; blood was taken before the child received the vitamin A capsule. (b) Distribution of serum retinol in female caregivers of the preschool children visiting the primary health-care facility (n 202)

Figure 5

Table 5 Liver-eating patterns in the study population: children and their female caregivers visiting a primary health-care facility in a low socio-economic area in the Northern Cape Province, South Africa, April–November 2008

Figure 6

Fig. 2 Distribution of the frequency of liver consumption at household level among pre-school children and their female caregivers visiting a primary health-care facility in a low socio-economic area in the Northern Cape Province of South Africa, April–November 2008 (n 225)

Figure 7

Table 6 Current or past breast-feeding practices in the study population: children and their female caregivers visiting a primary health-care facility in a low socio-economic area in the Northern Cape Province, South Africa, April–November 2008