Retinol levels in human colostrum: influence of child, maternal and socioeconomic variables

Dimenstein, Roberto; Simplício, Janicéia L.; Ribeiro, Karla D. S.; Melo, Illana L. P.

doi:10.1590/S0021-75572003000600009

Abstracts

OBJECTIVES: To determine colostrum retinol levels in breastfeeding women from the city of Natal, state of Rio Grande do Norte, Brazil, and to investigate the relationship between retinol levels in colostrum and child, maternal and socioeconomic variables. METHODS: Forty-two healthy women aged 18 to 39 years were evaluated 48 hours after delivery. Socioeconomic, anthropometric, and dietary data were collected by means of a questionnaire. Body mass index was used to determine nutritional status. The Virtual Nutri software was used to analyze data on daily intake of vitamin A collected by a dietetic history. Retinol levels were determined in 2 ml of colostrum using high-performance liquid chromatography. RESULTS: Most women were of low socioeconomic and educational backgrounds. Vitamin A intake was adequate in 55% of the women (mean intake = 1,398.8 µg RE/day). The mean amount of retinol in colostrum was 93.1+51.1 µgRE/100 ml. No significant differences were found in terms of milk retinol levels for the variables income (p = 0.503), educational level (p = 0.708) and birth weight (p = 0. 499). However, a statistically significant difference was observed for nutritional status during pregnancy (0.016). CONCLUSION:The lack of influence of socioeconomic factors on colostrum retinol levels suggests the existence of an adaptive mechanism of the mammary gland to maintain adequate retinol levels that meet the infant's daily needs.

Retinol; human colostrum; socio-economic variables; maternal-child health variables

OBJETIVO: Determinar os níveis de retinol no colostro de lactantes moradoras da cidade de Natal (RN) e sua relação com as variáveis socioeconômicas e de saúde materno-infantil. MÉTODOS: Foram avaliadas 42 nutrizes saudáveis, entre 18 e 39 anos, até 48 horas pós-parto. Foram aplicados questionários para a coleta de dados socioeconômicos, antropométricos e dietéticos. O estado nutricional antropométrico foi determinado pelo índice de massa corpórea e os dados de consumo alimentar em vitamina A foram obtidos pelo inquérito dietético de história alimentar, sendo a análise realizada pelo programa Virtual Nutri. Foram coletados 2 ml de colostro, e a determinação do retinol foi realizada por cromatografia líquida de alta eficiência. RESULTADOS: A maioria das nutrizes apresentou baixa condição socioeconômica e baixo grau de escolaridade. Entre as nutrizes, 55% apresentavam um consumo de vitamina A adequado, com uma média de ingestão de 1.398,8 µgRE/dia. O valor médio de retinol no colostro foi 93,1+51,1 µgRE/100 ml. Quando relacionado aos níveis de retinol no leite, as variáveis renda (p = 0,503), escolaridade (p = 0,708) e peso ao nascer do bebê (p = 0,499) não apresentaram diferenças significativas. Entretanto, houve diferença estatisticamente significativa entre o nível de retinol no leite e o estado nutricional na gestação (p = 0,016). CONCLUSÃO: A não-influência de variações socioeconômicas nos níveis de retinol do colostro sugere a existência de um mecanismo de adaptação da glândula mamária na manutenção dos níveis adequados de retinol para atender às necessidades diárias do lactente.

Retinol; colostro humano; indicadores socioeconômicos; indicadores de saúde materno-infantil

ORIGINAL ARTICLE

Retinol levels in human colostrum: influence of child, maternal and socioeconomic variables

Roberto Dimenstein^I; Janicéia L. Simplício^II; Karla D. S. Ribeiro^II; Illana L. P. Melo^II

^IPhD. Associate professor, Department of Biochemistry, Universidade Federal do Rio Grande do Norte (UFRN), Natal, RN, Brazil

^IINutrition student, Universidade Federal do Rio Grande do Norte (UFRN), Natal, RN, Brazil

^{Correspondence} Correspondence to Roberto Dimenstein Avenida Praia de Genipabu, 2100/1402 CEP 59094010 - Natal, RN, Brazil Phone: + 55 (84) 219.4340 E-mail: robertod@ufrnet.br

ABSTRACT

OBJECTIVES: To determine colostrum retinol levels in breastfeeding women from the city of Natal, state of Rio Grande do Norte, Brazil, and to investigate the relationship between retinol levels in colostrum and child, maternal and socioeconomic variables.

METHODS: Forty-two healthy women aged 18 to 39 years were evaluated 48 hours after delivery. Socioeconomic, anthropometric, and dietary data were collected by means of a questionnaire. Body mass index was used to determine nutritional status. The Virtual Nutri software was used to analyze data on daily intake of vitamin A. Retinol levels were determined in 2 ml of colostrum using high-performance liquid chromatography.

RESULTS: Most women were of low socioeconomic and educational backgrounds. Vitamin A intake was adequate in 55% of the women (mean intake = 1,398.8 µg RE/day). The mean amount of retinol in colostrum was 93.1+51.1 µgRE/100 ml. No significant differences were found in terms of milk retinol levels for the variables income (p = 0.503), educational level (p = 0.708) and birth weight (p = 0. 499). However, a statistically significant difference was observed for nutritional status during pregnancy (0.016).

CONCLUSION: The lack of influence of socioeconomic factors on colostrum retinol levels suggests the existence of an adaptive mechanism of the mammary gland to maintain adequate retinol levels that meet the infant's daily needs.

Retinol, human colostrum, socio-economic variables, maternal-child health variables.

Introduction

Vitamin A is a micronutrient that is essential to health. Dimenstein¹ points out that this vitamin is involved in reproduction, the visual cycle and cellular differentiation, which, in turn, affects physiological processes such as growth, fetal development and the integrity if the immune system. Due to its role in embryo development and in the normal differentiation of epithelial tissues, vitamin A is of fundamental importance during periods of growth and development, such as during gestation and lactation.^2,3

Vitamin A deficiency is a significant public health problem and is the main cause of permanent blindness accompanied by death among children in developing countries.⁴ It also contributes to a significant increase in rates of infant mortality and morbidity associated with infectious processes.⁵ The primary factor which leads to reduced vitamin A levels in children is the absence of maternal breastfeeding during the first six months of life,⁶whether exclusive or complemented.⁷ In addition, children who are exclusively breastfed depend entirely on the concentration of vitamin A and the volume of their mothers' milk to meet their requirements.

Human colostrum, defined as the first lactic secretion of the nursing mother until the 7th day postpartum,⁸ and is particularly rich in vitamin A. It can reach concentrations of approximately 200 µg/100 ml, being, therefore, an excellent dietary source of this vitamin during the first days of the child's life.⁹

In Brazil, little work has been published on the effects of maternal socioeconomic status and health indictors on the levels of vitamin A in colostrum. The objective of this study is to determine retinol levels in the colostrum of nursing mothers resident in the city of Natal (RN) and their relationship with certain variables related to the socioeconomic and health status of mother and child.

Methods

The study was approved by the Committee for Ethics in Research of the Universidade Federal do Rio Grande do Norte. The sample was selected by convenience, with 42 nursing mothers taking part aged from 18 to 39. They were seen at the Escola Januário Cicco Maternity Unit, Natal-RN, during the period between January and March 2002, and were breastfeeding exclusively. The mothers were selected to meet the following criteria: resident in the city of Natal-RN, normal delivery, full term gestational period, single conception pregnancy and absence of chronic disease during pregnancy. After the mothers had given informed consent, questionnaires were filled out to obtain data on socioeconomic, anthropometric and dietary factors. The data on nutritional status was obtained from prenatal care records. Anthropometric nutritional status was calculated using the Rosso weight-gain chart and weight/gestational age curves.¹⁰ Thus, with the aid of a ruler, the height of the expectant mother can be related to the ideal value for her weight. The value is then applied to the diagram and correlated with gestational age. Both instruments allow maternal weight gain to be established and the mothers classified as of normal weight normal, overweight and low weight. The socioeconomic variables studied were level of education and income. Data on income was expressed in terms of multiples of the national minimum monthly salary received by the family and divided to represent income per capita. The cut-off for a definition of a low income was set at 0.5 minimum salaries per capita, keeping in mind that when the minimum salary was created by Brazilian legislation it was intended to meet the basic needs of a "standard" family. All colostrum samples were obtained within 48 hours of birth, by manual expression of both breasts, twice during the day (morning and evening) to reduce variations that occur during the day, until a volume of 2 ml of milk was reached. The milk was collected in a polypropylene tube duly protected with aluminum foil to impede vitamin A degradation from the action of light. The samples were stored at 20 °C until analysis.

Dietary investigation to establish vitamin A nutritional history was by dietary recall of the last three months of pregnancy, and in order to calculate the resultant ingestion of vitamin A in the diet Virtual Nutri version 1.0 for Windows-1996 from USP¹¹ was used. Certain alterations were made to vitamin A concentrations for some foodstuffs according to the 1999 Food Composition Table, Brazilian Institute of National Statistics and Geography IBGE.¹² The estimated total vitamin A was compared with dietary reference values (770 µgEqR/day for Vitamin A), from the Food and Nutrition Board.¹³ No correlation was sought between vitamin A ingestion data and colostrum retinol concentrations, since a historical dietary enquiry is not the best instrument for analyzing micronutrients.

Retinol was extracted from the colostrum by the method described by Giuliano et al.,¹⁴ the phases were separated and hexane evaporated in a nitrogen atmosphere, in a water bath at 37 °C. Extracts were re-suspended in 1 ml of methanol (HPLC grade) and centrifuged for 1 minute. The retinol concentration of the samples was measured by HPLC with a Shimadzu LC-10 AD Chromatograph, coupled to a Shimadzu SPD-10 A UV-VIS Detector and a Shimadzu C-R6A Chromatopac Integrator with a Shim-pack CLC-ODS analytical conditions column (4.6 mm x 25 cm). The chromatogram developed under the following mobile phase conditions: methanol 100% and flow 1.0 ml/min. The retinol in the samples was identified and quantified by comparison with their respective standard retention times and areas. Standard concentrations were confirmed by the specific extinction coefficient (e1%, 1 cm = 1850) in absolute ethanol and with a wavelength of 325 nm.¹⁵For this study the following cut-off points were used for colostrum retinol levels: < 30 µg/100 ml (low retinol level); 30 59 µg/100 ml (low level in relation to mature milk) and < 60µg/100 ml (normal level for colostrum).

Data was processed by the CONSULEST laboratory at the Department of Statistics of the Universidade Federal do Rio Grande do Norte. Numerical data was processed for linear correlation, while the influence of socioeconomic and maternal health variables on colostrum vitamin A concentrations were subjected to non-parametric analysis of variance by the Kruskal-Wallis test. Retinol values were expressed as mean and standard deviation and to test the differences between the averages of numerical data the Student t test was used. Differences at p < 0.05 were considered significant.

Results

According to the questionnaire on socioeconomic status and mother-baby health, the majority of nursing mothers had a per capita family income of less than 0.5 minimum salaries (55%), 74% had completed the first level of national education and 90% had given birth to babies weighing <2,500 g. Employing Virtual Nutri¹¹ to analyze vitamin A ingestion, it was observed that 55% of the mothers presented adequate vitamin A consumption, with an average ingestion of 1,398.8 µgRE/day, according to the DRI.¹³ When anthropometric nutritional status of the expectant mothers was analyzed by means of the weight/gestational age curve, it was found that 45% of the expectant mothers were within the limits of normality (Table 1).

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The average of the values for retinol found in colostrum was 93.1+51.1 µgRE/100 ml, and when analyzed by cut-off points, 71% of the nursing mothers had ideal values or values above 60 µgRE/100 ml (Table 2). Women who were underweight, normal and overweight during pregnancy had average retinol levels of 63.3+37.9, 95.6+43.9 and 116.5+57.4 µgRE/100 ml, respectively (Table 3). Mothers with low incomes had an average of 99.5+54.6 gRE/100 ml, and those with high incomes 85.4+46.8 µgRE/100 ml. However no significant differences were found between retinol levels and variables relating to socioeconomic status and mother-baby health, except when the group that was underweight during pregnancy was compared with the overweight group (p < 0.05) (Table 3).

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Discussion

During pregnancy, ingestion and hepatic reserves of maternal vitamin A are essential to guarantee the transference of this micronutrient to the fetus, and are its first source of the nutrient.¹⁶ The observed average vitamin A ingestion of women in developing countries (660 µgRE/day) is less than half that found in developed countries (1,540 µgRE/day).¹⁷ Among pregnant women registered with the public health system in Rio de Janeiro, average vitamin A ingestion was 2,692 µgRE/dia,¹⁸ while in deprived populations in Campinas-SP, an average was found that was below that of the developing countries.¹⁹ This study found an adequate average vitamin A consumption, in common with Ortega,²⁰ despite the majority of the nursing mothers belonging to the group with lower socioeconomic status. However, only 55% of the women were consuming sufficient quantities of the micronutrient to meet their needs (770 µgRE/day, DRI 2001), a fact which was also encountered by Moura²¹ in São Paulo, indicating a low consumption of vitamin A rich foods on a populational level.

Maternal socioeconomic status has been implicated as being associated with vitamin A concentrations in milk. Newman¹⁷ found that the level of this nutrient is lower in the milk of nursing mothers from developing countries when compared with that of women from developed countries. Studies of Swedish and Ethiopian women, privileged and under privileged, found retinol values of 40-53.2 and 28.3-33.2 µgRE/100 ml, respectively.²²Income also affected retinol concentration in the milk of nursing mothers in Bangladesh.²³

In Brazil, and certain countries in Latin America, vitamin A deficiency is considered a public health problem with a high frequency of sub-clinical manifestations.²⁴ This situation exists in populations that habitually ingest quantities close to minimum requirements or below the recommended levels and becomes of concern in critical situations, particularly during periods of growth and development, such as during pregnancy and lactation. Sub-clinical vitamin A deficiencies, common in our region, mask the real clinical condition without provoking hypovitaminosis A symptoms. This is perhaps the explanation for the absence of a correlation between low socioeconomic status and vitamin A concentration in breastmilk found in our study. Income and education, far from having the expected effect on retinol levels in colostrum, actually presented an inverse relationship with lower average concentrations among women with higher levels of education or income. This effect was also observed by Vitolo et al.¹⁹ among women in Campinas SP. Notwithstanding, the studies that found maternal socioeconomic status to have an influence on the concentration of vitamin A in milk were mainly carried out in populations living in extreme poverty, with a high frequency of clinical manifestations of hypovitaminosis A.

In addition the average colostrum retinol level was 93.1+51.1 µg/100 ml, which agrees with levels found by Macias²⁵ in Cuban women. Adopting the cut-off points already mentioned, we observed that only 7.1% of the nursing mothers presented a retinol deficiency (< 30 µg/100 ml), while the majority had levels above 60 µg/100 ml (Table 2). This data provides evidence that even in the face of poor socioeconomic conditions, colostrum vitamin A levels are maintained at an adequate level when compared with populations in better socioeconomic conditions. When maternal nutritional status is analyzed by anthropometric indicators, however, there are significant differences between the underweight and overweight groups, suggesting that the adaptive mechanisms that ensure breastmilk retinol levels, irrespective of socioeconomic conditions, are fragile and are probably associated with factors such as malnutrition. Accioly¹⁸ did not observe significant associations between anthropometric values or nutritional status and the vitamin A levels of expectant mothers in Rio de Janeiro, drawing attention to qualitative dietary factors, which are very different in different regions of Brazil. This demonstrates that in a state of partial poverty, in contrast with extreme deprivation, vitamin A levels in breastmilk tend towards normality.

No alterations to colostrum retinol levels were observed among the nursing mothers studied in terms of socioeconomic variables and birth weight. This result suggests the existence of an adaptive mechanism maintaining mammary glandular levels of retinol at an adequate level to meet the daily needs of the infant. The variations that were observed in retinol levels between underweight and overweight groups should be better investigated in order to evaluate the influence of factors such as malnutrition and qualitative dietary factors.

References

Manuscript received Mar 10 2003, accepted for publication Aug 20 2003.

1. Dimenstein R. Estudo da transferência materno fetal de vitamina A e carotenóides sob condições adequadas e sub-adequadas do estado nutricional materno em vitamina A [tese]. Rio de Janeiro (RJ): Universidade Federal do Rio de Janeiro; 1999.
2. Maden M. Vitamin A in embryonic development. Nutr Rev. 1994;52(2 Pt 2):S3-12.
3. Azais-Braesco V, Pascal G. Vitamin A in pregnancy: requirements and safety limits. Am J Clin Nutr. 2000;71(5 Suppl):S1325-33.
4. Sauders C, Ramalho RA, Leal MC. Estado nutricional de vitamina A no grupo materno-infantil. Rev Bras Saúde Materno-Infantil. 2001;1: 21-9.
5. Mclaren DS, Frigg M. Manual de ver y vivir sobre los transtornos por deficiencia de vitamina A (VADD). Washington: Organizacion Panamericana de La Salude; 1999.
6. Euclydes MP. Nutrição do Lactente: Base científica para uma alimentação adequada. 2^a ed. Viçosa (MG): Ed. Metha; 2000.
7. World Health Organization (WHO). Indicators for assessing breastfeeding practices. Geneva: WHO; 1991 (Document WHO/ CDD/SER/91.14).
8. Brasil, Ministério da Saúde. Normas gerais para bancos de leite humano. 2^a ed. Brasília: Ministério da Saúde; 1993.
9. Stoltzfus RJ, Underwood BA. Breast-milk vitamin A as an indicator of the vitamin A status of women and infants. Bull World Health Organ 1995;73:703-11.
10. Vasconcelos FAG. Avaliação nutricional de coletividades. 2^a ed. Florianópolis: Ed. UFSC; 1995.
11. Philippi ST, Szarfarc SC, Latterza AR. Virtual Nutri [software], versão 1.0, for Windows. São Paulo: Departamento de Nutrição/Faculdade de Saúde Pública/USP; 1996.
¹²
Instituto Brasileiro de Geografia e Estatística (IBGE). Tabela de Composição dos Alimentos. 5^a ed. Rio de Janeiro: IBGE; 1999. 137p.
¹³
Food and Nutrition Board. Institute of Medicine. Dietary Reference Intake for vitamin A, vitamin K, Arsenic, boron, chromium, copper, iodine, iron, manganese, molybdenum, nickel, silicon, vanadium and zinc. Prepublication report. Washington, DC: National Academy Press; 2001.
14. Giuliano AR, Neilson EM, Yap H, Baier M, Canfield LM. Quantitation of and inter/intra-individual variability in major carotenoids of mature human milk. J Nutr Biochem. 1994;5:551-6.
15. Nierenberg DW, Nann SL. A method for determining concentrations of retinol, tocopherol, and five carotenoids in human plasma and tissue samples. Am J Clin Nutr. 1992;56:417-26.
16. Coelho CSP, Ramalho RA, Accioly E. O inquérito dietético na avaliação do estado nutricional de vitamina A em gestantes. ARS CVRANDI Clínica Médica. 1995;6:44-60.
17. Newman V. Vitamin A and breastfeeding: a comparison of data from developed and developing countries-summary. San Diego: Wellstart International; 1993.
18. Accioly E, Souza-Queiróz S. Deficiencia de vitamina A en embarazadas atendidas en una maternidad publica en Rio de Janeiro, Brasil. Rev Chilena Nutrición. 2000;27:352-7.
19. Vitolo MR, Accioly E, Ramalho RA, Soares AG, Cardoso CB, Carvalho EB. Níveis de vitamina A no leite maduro de nutrizes adolescentes e adultas de diferentes estratos socioeconômicos. Rev Ciências Médicas. 1999;8:3-10.
20. Ortega RM, Andrés P, Martínez RM, López-Sobaler AM. Vitamin A status during the third trimester of pregnancy in Spanish women: influence on concentration of vitamin A in breast milk. Am J Clin Nutr. 1997;66:564-8.
21. Moura EC, Rossi AVT, Sanches AL, Vendramini CM, Françoso TA. Perfil nutricional de gestantes atendidas no Centro de Saúde Escola Jardim Novo Campos Elíseos da PUCCAMP. Rev Nutr PUCCAMP. 1990;3:113-26.
22. Gebre-Medhin M, Vahlquist A, Hofvander Y, Upsali L, Vahlquist B. Breast milk composition in Ethiopian and Swedish mother. I. Vitamin A and b-carotene. Am J Clin Nutr. 1976;29:441-51.
23. Barua S, Tarannum S, Nahar L, Mohiduzzaman M. Retinol and alpha-tocopherol content in breast milk of Bangladesh mothers under low socio-economic status. Int J Food Sci. 1997;48:13-8.
24. Mora JO. Situación actual de la deficiencia de vitamina A en América Latina y el Caribe. Arch Latin Nutr. 1992;42:108S-116S.
25. Macias C, Schuweigert FJ. Changes in the concentration of carotenoids, vitamin A, alpha-tocopherol and total lipids in human milk throughout early lactation. Ann Nutr Metab. 2001;45:82-5.

Correspondence to

Roberto Dimenstein

Avenida Praia de Genipabu, 2100/1402

CEP 59094010 - Natal, RN, Brazil

Phone: + 55 (84) 219.4340

E-mail:

robertod@ufrnet.br

Publication Dates

Publication in this collection
09 Aug 2004
Date of issue
Nov 2003

History

Received
10 Mar 2003
Accepted
20 Aug 2003

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

[1] 1. Dimenstein R. Estudo da transferência materno fetal de vitamina A e carotenóides sob condições adequadas e sub-adequadas do estado nutricional materno em vitamina A [tese]. Rio de Janeiro (RJ): Universidade Federal do Rio de Janeiro; 1999.

[2] 2. Maden M. Vitamin A in embryonic development. Nutr Rev. 1994;52(2 Pt 2):S3-12.

[3] 3. Azais-Braesco V, Pascal G. Vitamin A in pregnancy: requirements and safety limits. Am J Clin Nutr. 2000;71(5 Suppl):S1325-33.

[4] 4. Sauders C, Ramalho RA, Leal MC. Estado nutricional de vitamina A no grupo materno-infantil. Rev Bras Saúde Materno-Infantil. 2001;1: 21-9.

[5] 5. Mclaren DS, Frigg M. Manual de ver y vivir sobre los transtornos por deficiencia de vitamina A (VADD). Washington: Organizacion Panamericana de La Salude; 1999.

[6] 6. Euclydes MP. Nutrição do Lactente: Base científica para uma alimentação adequada. 2^a ed. Viçosa (MG): Ed. Metha; 2000.

[7] 7. World Health Organization (WHO). Indicators for assessing breastfeeding practices. Geneva: WHO; 1991 (Document WHO/ CDD/SER/91.14).

[8] 8. Brasil, Ministério da Saúde. Normas gerais para bancos de leite humano. 2^a ed. Brasília: Ministério da Saúde; 1993.

[9] 9. Stoltzfus RJ, Underwood BA. Breast-milk vitamin A as an indicator of the vitamin A status of women and infants. Bull World Health Organ 1995;73:703-11.

[10] 10. Vasconcelos FAG. Avaliação nutricional de coletividades. 2^a ed. Florianópolis: Ed. UFSC; 1995.

[11] 11. Philippi ST, Szarfarc SC, Latterza AR. Virtual Nutri [software], versão 1.0, for Windows. São Paulo: Departamento de Nutrição/Faculdade de Saúde Pública/USP; 1996.

[12] ¹²
Instituto Brasileiro de Geografia e Estatística (IBGE). Tabela de Composição dos Alimentos. 5^a ed. Rio de Janeiro: IBGE; 1999. 137p.

[13] ¹³
Food and Nutrition Board. Institute of Medicine. Dietary Reference Intake for vitamin A, vitamin K, Arsenic, boron, chromium, copper, iodine, iron, manganese, molybdenum, nickel, silicon, vanadium and zinc. Prepublication report. Washington, DC: National Academy Press; 2001.

[14] 14. Giuliano AR, Neilson EM, Yap H, Baier M, Canfield LM. Quantitation of and inter/intra-individual variability in major carotenoids of mature human milk. J Nutr Biochem. 1994;5:551-6.

[15] 15. Nierenberg DW, Nann SL. A method for determining concentrations of retinol, tocopherol, and five carotenoids in human plasma and tissue samples. Am J Clin Nutr. 1992;56:417-26.

[16] 16. Coelho CSP, Ramalho RA, Accioly E. O inquérito dietético na avaliação do estado nutricional de vitamina A em gestantes. ARS CVRANDI Clínica Médica. 1995;6:44-60.

[17] 17. Newman V. Vitamin A and breastfeeding: a comparison of data from developed and developing countries-summary. San Diego: Wellstart International; 1993.

[18] 18. Accioly E, Souza-Queiróz S. Deficiencia de vitamina A en embarazadas atendidas en una maternidad publica en Rio de Janeiro, Brasil. Rev Chilena Nutrición. 2000;27:352-7.

[19] 19. Vitolo MR, Accioly E, Ramalho RA, Soares AG, Cardoso CB, Carvalho EB. Níveis de vitamina A no leite maduro de nutrizes adolescentes e adultas de diferentes estratos socioeconômicos. Rev Ciências Médicas. 1999;8:3-10.

[20] 20. Ortega RM, Andrés P, Martínez RM, López-Sobaler AM. Vitamin A status during the third trimester of pregnancy in Spanish women: influence on concentration of vitamin A in breast milk. Am J Clin Nutr. 1997;66:564-8.

[21] 21. Moura EC, Rossi AVT, Sanches AL, Vendramini CM, Françoso TA. Perfil nutricional de gestantes atendidas no Centro de Saúde Escola Jardim Novo Campos Elíseos da PUCCAMP. Rev Nutr PUCCAMP. 1990;3:113-26.

[22] 22. Gebre-Medhin M, Vahlquist A, Hofvander Y, Upsali L, Vahlquist B. Breast milk composition in Ethiopian and Swedish mother. I. Vitamin A and b-carotene. Am J Clin Nutr. 1976;29:441-51.

[23] 23. Barua S, Tarannum S, Nahar L, Mohiduzzaman M. Retinol and alpha-tocopherol content in breast milk of Bangladesh mothers under low socio-economic status. Int J Food Sci. 1997;48:13-8.

[24] 24. Mora JO. Situación actual de la deficiencia de vitamina A en América Latina y el Caribe. Arch Latin Nutr. 1992;42:108S-116S.

[25] 25. Macias C, Schuweigert FJ. Changes in the concentration of carotenoids, vitamin A, alpha-tocopherol and total lipids in human milk throughout early lactation. Ann Nutr Metab. 2001;45:82-5.

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Retinol levels in human colostrum: influence of child, maternal and socioeconomic variables

Abstracts

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History