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Milk folate but not milk iron concentrations may be inadequate for some infants in a rural farming community in San Mateo, Capulhuac, Mexico^1,2,3

¹ From the Basic Nutrition Division, Instituto Nacional de Salud Publica, Cuernavaca, Mexico (SV, GR, and MJI); the Nutrition Department, Pennsylvania State University, University Park (MEL and MFP); and The Hospital for Sick Children and University of Toronto, Toronto (DLO).

² Supported by Nacional de Ciencia y Tecnologia, Mexico.

³ Address reprint requests to DL O’Connor, Department of Nutritional Sciences, University of Toronto, 555 University Avenue, Toronto, Ontario, Canada M5G 1X8. E-mail: deborah_l.o\|[rsquo ]\|connor{at}sickkids.ca.

	ABSTRACT

TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 
Background: We were interested in identifying possible nutritional reasons for growth faltering among breastfed infants in the rural farming community of San Mateo, Capulhuac, Mexico (2800 m above sea level).

Objective: We examined the prevalence of inadequate iron and folate status among lactating Otomi women and determined to what extent their iron and folate nutriture influenced the milk concentrations of these nutrients.

Design: Lactating women (n = 71) provided blood and milk samples and dietary information at a mean (± SD) of 22 ± 13 d postpartum. Blood indexes included hemoglobin, hematocrit, serum iron, total-iron-binding capacity, ferritin, transferrin receptor, mean cell volume, plasma folate, and erythrocyte folate.

Results: Approximately 62% and 58% of the women had nutritional anemia defined as a hemoglobin concentration 133 g/L and a hematocrit value of 41.0%, respectively. With the use of a 3-index iron assessment model, 2 of the 66 women whose iron status was assessed (3%) had iron-deficient erythropoiesis, and 24 (36%) had iron deficiency anemia. Among the 67 women whose folate status was assessed, 29 (43%) had a low plasma folate concentration, and 13 (19%) had a low blood folate concentration in conjunction with a low hemoglobin concentration. Milk iron content was unrelated to maternal iron status, and the milk provided more than adequate amounts of iron to the infants. In contrast, the infants’ predicted folate intake was 45 µg/d, or 70% of the current recommended intake.

Conclusion: Milk folate concentrations in Otomi women are low and may not support optimal folate status in all breastfed infants.

Key Words: Iron status • folate status • lactation • milk folate • milk iron • iron-folate interaction

	INTRODUCTION

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Although the predicted prevalence of iron deficiency with or without anemia varies widely, it is clear that a disproportionate number of reproducing women throughout the world show evidence of iron deficiency (50–60% compared with 20–30% of nonpregnant, nonlactating women) (1–3). Similarly, up to one-third of reproducing women are estimated to have some degree of folate undernutrition (4). Even well-nourished women develop a certain degree of folate depletion (eg, an increase in serum homocysteine concentration) during lactation (5, 6). Nonetheless, milk folate concentrations are conserved at the expense of maternal body reserves (5, 7). As such, it is generally accepted that during maternal folate deficiency, folate intakes in breastfed infants are protected until the introduction of solid foods (8). Results from animal studies in our laboratories suggest, however, that maternal iron deficiency may be detrimental to both maternal and infant folate nutriture. We reported that milk collected from iron-deficient rats and pigs contains up to 50% less folate than that collected from iron-sufficient animals (9–12). This reduction in milk folate content was sufficient to impair folate status and growth in nursing rats and pigs. Matoth et al (13) showed that folic acid supplementation of apparently healthy infants who were fed a low-folate boiled cow milk diet had better growth than did infants fed the same diet without supplemental folic acid.

Milk iron content is unaffected by iron intake in well-nourished women; however, no information is available to confirm that this relation holds true in undernourished women (14, 15). To our knowledge, the possible consequences of maternal iron deficiency alone, or in combination with folate deficiency, on milk folate and iron concentrations in humans has not been studied.

We were interested in determining whether maternal iron or folate deficiency, or an interaction between the 2, could be contributing to the disproportionate decline in growth velocity and National Center for Health Statistics z scores among healthy Otomi breastfed infants (4–6 mo of age) from San Mateo, Capulhuac, Mexico, relative to their US counterparts (16, 17). Preliminary data collected from blood samples of lactating women in this community provide biochemical evidence of iron and folate deficiency (18).

Although variations in the energy density of milk are present, Otomi infants meet their energy demands by increasing their milk intake, so that corresponding infant intakes of energy, protein, and carbohydrates from milk are comparable with those of US breastfed infants having normal growth (19). Similarly, mean calcium, magnesium, phosphorous, copper, and zinc concentrations in milk produced by Otomi women at 4 and 6 mo postpartum have been shown to be comparable with those in milk secreted by healthy American women (20). Except for zinc, estimated intakes of each nutrient would meet or exceed adequate daily intakes for term infants up to 6 mo of age (19–22). The purpose of the present study was to use sensitive and specific indexes of iron and folate status to assess the extent to which iron status and folate status affect milk folate and iron content in Otomi women.

	SUBJECTS AND METHODS

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Subjects
Lactating women (n = 71) residing in the rural, farming, Indian community of San Mateo, Capulhuac, Mexico, which is located 2800 m above sea level, furnished blood and milk samples, as well as dietary and demographic information, at 22 ± 13 ( ± SD) d postpartum. A detailed description of this community and the dietary habits of its residents was published previously (19). Briefly, Otomi women subsist on a maize-predominant diet, and the proportion of meat included in the diet is limited. Protein from animal sources (mostly eggs) makes up only 30% of all protein consumed. Dark leafy vegetables and legumes are frequently eaten after prolonged boiling, and hence the folate content of these usually good sources of folate is low (23). The calculated dietary intake of phytic acid is very high because of the consumption of corn (65% of energy intake) and other phytate-containing vegetables. In most cases, exclusive breastfeeding extends for 4 mo. In the few cases in which infants are not exclusively breastfed at 4 mo, foods other than human milk constitute only 2% of total energy intake (16). The total duration of breastfeeding averages 18 mo.

Women who were willing to exclusively breastfeed their offspring were recruited from the local medical clinic and enrolled in the study if they met the eligibility requirements. The eligibility requirements included the following: 1) having an age between 17 and 37 y, 2) being free of chronic diseases, 3) not currently taking any medication, 4) not consuming alcoholic beverages, 5) being free of pregnancy complications, 6) having given birth to a term infant of appropriate length and weight, and 7) being willing to comply with the experimental protocol. The participation of human subjects was approved by the Institutional Review Boards of both the Instituto Mexicano del Seguro Social, Mexico City, and the Pennsylvania State University, State College.

Anthropometric measurements, dietary intakes, and blood sample collection
Maternal weight and height and infant weight and length were measured in the clinic with the use of standardized procedures (24). Weights were measured by using electronic scales with precisions of ± 0.1 g for infants (Sartorious, Gotttingen, Germany) and ± 50 g for women (Tanita W8; Tanita Inc, Tokyo, Japan). Heights and lengths (± 1 mm) were measured with the use of a clinical stadiometer and an infant measuring board (Holtain Ltd, Croswell, Crymych, United Kingdom), respectively. Head circumferences (± 1 mm) were measured with the use of a nonstretchable tape measure (InserTape; Abbott Laboratories, Columbus, OH). For each infant, z scores were calculated for weight-for-age, length-for-age, weight-for-length, and head circumference–for–age by using the year 2000 growth charts from the Centers for Disease Control and Prevention and supporting software (25).

Usual maternal dietary intakes of energy, protein, fat, carbohydrates, iron, folate, and vitamin B-12 were estimated by using 3 d of dietary data collected according to a detailed standardized protocol. Briefly, community workers trained by a nutritionist recorded the dietary intakes of the study participants in their homes for 2 consecutive days. Dietary intakes were assessed during one weekend day by using an interactive 24-h dietary recall method that included information previously collected on standard serving sizes. Nutrient intakes were tabulated by using Mexican food composition tables (26).

After the subjects fasted overnight, blood samples were collected either into tubes containing EDTA or into tubes that were free of trace elements and did not contain an anticoagulant (Vacutainer; Becton Dickinson, Franklin Lakes, NJ). A portion (100 µL) of whole blood was diluted in 10 volumes of a 0.1-mol potassium phosphate/L buffer containing 0.05 mol sodium ascorbate/L. Milk was collected by using an electric breast pump (Egnel, Libertyville, Illinois) to completely express the milk from one breast 2 h after the previous feeding. For folate analyses, 1% sodium ascorbate was dissolved into milk and plasma samples, and all milk and blood samples were frozen at -70 °C. Milk and serum samples for determination of milk and blood indexes of iron status were immediately frozen at -20 °C until analyzed.

Biochemical analyses
A complete blood count analysis, including measurements of hematocrit, hemoglobin concentration, and mean cell volume (MCV), was performed by using fresh blood samples and an electronic particle counter analyzer (ACT8 Coulter Counter; Beckman Coulter, Miami). C-reactive protein concentrations were measured by immunoprecipitation (SANOFI; Pasteur Diagnostic, Mexico City).

To assess folate status, erythrocyte and plasma folate were determined by microbiological assay with cryoprotected Lactobacillus casei (ATCC #7469; American Type Tissue Culture Collection, Manassas, VA) as the test organism (27). Before the microbiological assay, whole blood lysates were incubated for 25 min at 37 °C to convert folates to their microbiologically assayable forms (eg, short-chain folylpolyglutamates). Erythrocyte folate content was determined by using the analyzed whole blood folate concentration minus the plasma folate content corrected for hematocrit. Milk samples were processed with a trienzyme digestion procedure before microbiological assay as described in detail by Mackey and Picciano (6). The accuracy and reproducibility of these assays were assessed by using infant formula with a certified mean (± SD) value of 1.29 ± 0.28 mg folic acid/kg (standard reference material no. 1846; National Institute of Standards and Technology, Gaithersburg, MD). Analysis in our laboratory yielded a folate content of 1.33 ± 0.05 mg folate/kg.

Serum iron and total-iron-binding capacity were determined by using the colorimetric method of Fielding (28) modified for determination in microliter sample volumes. Fetal bovine serum with a certified value of 32 ± 2 µmol Fe/L (176 ± 10 µg Fe/dL) (lot #7000C; Atlanta Biologicals, Norcross, GA) was used to verify the accuracy and reproducibility of this method. Analysis in our laboratory yielded an iron content of 30 ± 0.7 µmol/L.

For milk iron measurement, quartz vials containing thawed milk were dried to a constant weight. Samples were heated for 12 h in a muffle furnace at 500 °C, and then the ashes were cooled in a dessicator. The ashes were then dissolved in a 2-mol HNO₃/L solution containing 2% thioglycolic acid for iron reduction. An aliquot of 50 µL was placed in a 96-well plate, and 100 µL chromogen (as for serum iron analysis) was added. Infant formula with a certified value of 11.4 ± 0.7 mmol Fe/kg (63.1 ± 4.0 mg Fe/kg) (standard reference material no. 1846) was used to assess the accuracy and precision of the milk iron assay. Analysis in our laboratory yielded an iron content of 10.7 ± 0.5 mmol/kg (58.9 ± 3.0 mg/kg).

Plasma ferritin concentrations were measured by radioimmunoassay (Diagnostic Products, Los Angeles) and verified with the use of a ferritin standard (19 ± 1.5 µg/L). Results from our laboratory yielded a plasma ferritin concentration of 20 ± 1.1 µg/L. Transferrin receptor concentrations were measured by enzyme immunoassay (Ramco Laboratories Inc, Houston), for which high and low quality-control serum samples were provided.

Maternal iron and folate status assessment models
A 3-index iron assessment model and normative cutoff values for nonpregrant women, including ferritin ( 12 µg/L), transferrin saturation (TS; 16%), and MCV ( 80 fL), which were described by Cook et al (29), were used in the present study. With the use of receiver operating characteristic curve analysis and blood samples from lactating women in this community, a sample-specific hemoglobin cutoff of 133 g/L was derived and reported (30, 31). This hemoglobin cutoff was used in the present study and is in agreement with the World Health Organization (32) recommended value, which was adjusted for altitude (33–35). According to the 3-index model, subjects who were positive for 2 of these iron deficiency measures (ferritin, TS, and MCV) were considered iron deficient. On the basis of this 3-index model and hemoglobin concentrations, the subjects were classified as follows: 1) iron sufficient: adequate iron and adequate hemoglobin, 2) iron-deficient erythropoietic: low iron and adequate hemoglobin, 3) iron-deficient anemic: low iron with low hemoglobin, and 4) indeterminate iron status: one index of iron status (ferritin, TS, or MCV) indicative of iron depletion with or without low hemoglobin.

The following criteria were applied in the assessment of folate status. 1) Folate-sufficient subjects had an erythrocyte folate (EF) concentration > 360 nmol/L (24), a plasma folate (PF) concentration > 10 nmol/L (36), and an MCV < 94 fL (29) with or without adequate hemoglobin. This plasma folate cutoff is based on the use of plasma homocysteine as an indicator of folate undernutrition (36). 2) Folate-deficient subjects had an EF or PF concentration below the respective cutoff value but adequate MCV and hemoglobin. 3) Subjects with a low EF or PF concentration in addition to an elevated MCV but with adequate hemoglobin were classified separately. 4) Subjects with a low EF or PF concentration, an MCV < 94 fL, and low hemoglobin were classifed as folate deficient with a hemoglobin concentration 133 g/L. 5) Finally, subjects with a low EF or PF concentration, an elevated MCV, and low hemoglobin were considered folate-deficient anemic.

Statistical design and analyses
All statistical analyses were performed with SAS for WINDOWS, release 8.1 (SAS Institute Inc, Cary, NC), and unless indicated otherwise, statistical significance was set at P < 0.05. All values in the text are expressed as means ± SDs unless noted otherwise. All variables that were not normally distributed were transformed by using either the natural log or square root. We were unable to produce normal distributions for the following study variables: dietary folate intake, dietary vitamin B-12 intake, and milk iron concentration, and, as appropriate, nonparametric statistics were applied as described below.

Pearson correlation coefficients were computed to assess whether and to what extent relations existed between normally distributed or normalized infant anthropometric, blood iron, and blood folate measures. Dietary intakes of energy, iron, folate, and vitamin B-12 were divided into quartiles. Milk and blood iron and folate measures were compared across these energy and nutrient quartiles by using either analysis of covariance controlled for days postpartum and energy or Kruskal-Wallis tests of statistical significance. Likewise, either analysis of covariance or Kruskal-Wallis statistics were used to compare milk folate and milk iron concentrations between the women categorized as iron sufficient, iron deficient, or of indeterminate iron status. Pairwise comparisons of milk and blood iron and folate measures across quartiles of dietary nutrient intake or categories of maternal iron status (eg, iron sufficient, iron deficient, indeterminate iron status) were performed by using least significant difference tests if a P value for analysis of covariance statistics was < 0.05. No P values < 0.05 were generated for Kruskal-Wallis statistics, and hence pairwise comparisons were not performed. A Bonferroni-adjusted -value (0.05/6, or 0.0083) was assigned as the level of statistical significance for these post hoc pairwise comparisons (37).

	RESULTS

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Subject characteristics
Seventy-one women aged 24 ± 5 y (range: 17–37 y) were recruited. All had exclusively breastfed their infants from birth. A complete set of biochemical data for determination of iron status and folate status was available for 66 and 67 women, respectively. The average weight and height of the women in the sample was 53 ± 7.6 kg (range: 38–77 kg) and 1.5 ± 0.1 m (range: 1.3–1.7 m), respectively. All but 9 of the subjects were stunted (height < 152.7 cm), but none were wasted [body mass index (in kg/m²) < 17.8] (25). Twelve percent of the subjects were overweight (body mass index > 26.5) (25). The average parity was 3, and 17 (24%) of the women were primiparous. Almost 90% of the women had < 3 y of education. Evidence of infection or inflammation was apparent in 6 subjects on the basis of a C-reactive protein concentration > 11 mg/L. The average weight and length of study infants at the postpartum clinic visit was 3.5 ± 0.6 kg (range: 2.3–5.4 kg) and 51 ± 2.4 cm (range: 47–58 cm), respectively. As shown in Table 1, the infants were small in comparison with the 2000 reference population from the Centers for Disease Control and Prevention (25).

Evaluation of blood indexes of iron and folate status
Approximately 62% and 58% of the women had signs of nutritional anemia on the exclusive basis of either a hemoglobin concentration 133 g/L (31, 33, 34) or a hematocrit < 41.0% (31, 35) (Tables 3 and 4). The prevalence of low serum iron ( 11 µmol/L), TS ( 16%), and ferritin ( 12 µg/L) each approached 50%. Using the 3-index iron assessment model with and without hemoglobin, 2 women (3%) were classified as having iron deficient erythropoiesis, 24 (36%) had iron deficiency anemia, and 19 (29%) had indeterminate iron status. The latter category included women who had at least one of the following in the range indicative of iron deficiency: ferritin, TS, or MCV, with or without a low hemoglobin concentration. Exclusion of women who had an elevated C-reactive protein concentration did not appreciably alter the aforementioned results.

Maternal plasma folate concentrations were associated with the length-for-age z scores of the infants at 22 d postpartum (r = 0.34, P = 0.0007), which suggests a relation between maternal folate status and infant birth size. This observation is consistent with the results of several reports in the literature that link maternal folate status in both developed and developing countries with infant birth size (42). Maternal folate status was not related to the infants’ weight-for-age, weight-for-length, or head circumference–for–age. Likewise, no significant associations were found between maternal indexes of iron status and infant size.

Correlation of iron and folate status measures
The measures of biochemical iron status (ie, hemoglobin, hematocrit, MCV, serum iron, TS, and ferritin) were strongly correlated (r: 0.51–0.96, P < 0.0001). As anticipated, these iron indexes were inversely correlated with transferrin receptor concentrations (hemoglobin: r = -0.60, P < 0.0001; hematocrit: r = -0.57, P < 0.0001; MCV: r = -0.39, P = 0.0009; serum iron: r = -0.22, P = 0.0659; TS: r = -0.27, P = 0.03; ferritin: r = -0.49, P < 0.0001). The expression of this receptor is known to increase with diminution of iron status. Total-iron-binding capacity did not correlate with other measures of iron status and decreased with the number of days postpartum, regardless of iron status. Plasma and erythrocyte folate concentrations were positively correlated (r = 0.524, P < 0.0001).

Neither plasma nor erythrocyte folate concentrations were correlated with any biochemical index of iron status when subjects with a C-reactive protein concentration > 11 mg/L were included in the analysis. Once these latter 6 subjects were removed, inverse correlations of erthyrocyte folate concentrations with serum iron and TS were found (r = -0.27 and -0.25, respectively, P < 0.05).

Dietary intakes, blood indexes of iron and folate status, and their effect on the iron and folate content of milk
Biochemical blood indexes of iron and folate status were compared across quartiles of dietary intakes of energy, iron, folate, and vitamin B-12. As appropriate, the analyses were controlled for days postpartum. There were no differences in any biochemical index of iron or folate status across quartiles of dietary intakes of energy, iron, folate, and vitamin B-12. Likewise, there was no relation of dietary intakes of energy, iron, folate, and vitamin B-12 with milk iron concentrations. As summarized in Table 5, milk folate concentrations were found to be related to dietary iron intake after women with a C-reactive protein concentration > 11 mg/L were removed from the analysis (P = 0.02). In this latter model, both energy intake (P = 0.0101) and the number of days postpartum (P = 0.01) were also predictive of milk folate concentration. The women in the lowest quartile of dietary iron intake had significantly lower milk folate concentrations than did those in the second and third quartiles, at an -level < 0.05. The milk folate concentrations in the women in the highest quartile of dietary iron intake did not differ significantly from those in the women in the other quartiles. Only the difference between the lowest quartile and the third quartile remained significant after the use of a Bonferroni-adjusted -value (0.05/6, or 0.0083) to address the issue of multiple comparisons (37).

Comparison of mean milk folate concentrations between women who were categorized as iron sufficient, iron deficient, or iron indeterminate with the use of the 3-index model did not show any significant differences even after the number of days postpartum and energy intake were controlled for. Likewise, no significant differences in mean milk iron concentration were detected between women classified as iron sufficient, iron deficient, or iron indeterminate.

	DISCUSSION

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A significant proportion of lactating Otomi women in this study had compromised biochemical indexes of iron status. On the basis of a 3-index iron assessment model, 26 women (39%) had either iron-deficient erythropoiesis (n = 2) or iron deficiency anemia (n = 24). Fifty-four percent of the women had low iron stores (ferritin concentration 12 µg/L). The women’s absolute dietary iron intakes exceeded the 2001 recommended dietary allowance for this nutrient during lactation (9 mg/d) (21). The disjuncture between adequate iron intakes and the high prevalence of iron deficiency probably reflects the low bioavailability of iron in the diets consumed and the net maternal iron deficit accrued during pregnancy (2001 recommended dietary allowance for pregnancy = 27 mg/d). Indeed, it is well documented that the typical Mexican rural diet contains predominately nonheme sources of iron rather than the more bioavailable heme iron, is high in phytate and oxalate (iron-absorption inhibitors), and is low in ascorbic acid (iron-absorption enhancer) (43).

In addition to the high prevalence of iron deficiency, 43% of the women showed evidence of folate depletion. Dietary intakes of folate were extremely low: the median intake was 86 µg/d (first and third quartiles: 40, 137 µg/d), compared with the currently recommended intake during lactation of 500 µg/d (39). These intakes may, in fact, overestimate actual folate intakes because vegetables in this community are typically boiled for long periods, a practice that probably destroys heat-labile folates (23). Twenty-nine women (43%) had a low plasma folate concentration. Thirteen subjects (19%) had a low blood folate concentration in conjunction with a hemoglobin concentration 133 mg/L.

The iron concentrations in the milk produced by the women in this study were well within the range of those reported for milk from well-nourished women in the United States (21), and this milk would provide 0.37 g highly available iron/d to an infant consuming 0.85 L human milk/d. The latter milk volume was previously shown to be the mean quantity of milk consumed by infants in this community (21). The current adequate intake of iron for breastfed infants aged 0–6 mo is 0.27 g/d. In contrast with milk iron, the folate content of the milk collected from the Otomi women was considerably lower than that reported for milk from American women (40, 41). The mean folate concentration in the milk collected from the Otomi women (120 ± 129 nmol/L) was 60% of the 192 nmol/L that we reported for well-nourished American women by using optimized assay conditions (44–46). The latter value of 192 nmol/L was used to calculate the adequate intake of folate for infants aged 0–6 mo in the dietary reference intakes for folate (39). With the assumption of an average milk intake of 0.85 L/d for Otomi infants aged 0–5 mo (16), the mean folate intake of the infants in this community is 45 µg/d, or 70% of the currently recommended intake (39). Consequently, some infants in this community may be ingesting insufficient folate to maintain appropriate tissue concentrations.

The mechanisms for the low milk folate concentrations observed in the present study are not clear. In well-nourished women, milk folate concentrations are believed to be fairly well preserved across a range of maternal folate intakes and blood folate concentrations (6, 7, 47). In the case of severe maternal folate deficiency, as evidenced by megaloblastic anemia, milk folate concentrations decrease precipitously (7). The prevalence of folate depletion was widespread in this sample but was infrequently associated with megaloblastic anemia, although megaloblastic anemia may have been masked in many instances by a concomitant iron deficiency. The fact that milk folate concentrations were associated neither with dietary folate intake nor with plasma or erythrocyte indexes of folate status makes it difficult to absolutely conclude that inadequate maternal dietary folate intakes per se were responsible for the lower-than-expected milk folate concentrations reported in the present study.

In the present study, there was evidence of an interaction between iron and folate metabolism, although this relation was much more complex than previously observed in our animal studies (9–12). Specifically, maternal hematocrit values and hemoglobin concentrations were inversely related to milk folate concentrations (r = -0.39 and -0.36, respectively, P < 0.005), even after energy intake and the number of days postpartum were controlled for. In addition, after subjects with evidence of infection were removed from the statistical analysis, an inverse correlation of erthyrocyte folate concentrations with serum iron and TS was found (r = -0.27 and -0.25, respectively, P < 0.05).

In contrast with our experiments using iron-deficient animal models, in which an ample supply of dietary folate was typically provided, the mothers in the present study had both poor iron status and poor folate status. As we reviewed in detail elsewhere, observations both in humans and in animal models suggest that iron and folate deficiencies can develop independently of each other, secondary to poor dietary sources of each, or that iron deficiency, particularly during reproduction, can negatively alter folate metabolism (48). Yet, several circumstances have been described in which correction of a primary iron deficiency either causes folate deficiency or exacerbates a mild form of this disorder (48–50). We suggest that in the present study, the inverse relation of milk and erythrocyte folate concentrations with some biochemical indexes of iron status reflects the latter situation. In the present study, a significant percentage of the women showed evidence of iron deficiency, folate deficiency, or both. Among the iron-depleted women, a sufficient supply of folate appeared to be available to support the reduced level of erythropoiesis. In contrast, the negative interaction between some biochemical indexes of iron status and erythocyte folate status suggests that when iron is no longer limiting, there is a greater demand for folate, which reflects a lower erythrocyte folate concentration and reduced secretion of folate into milk.

The possibility that poor maternal vitamin B-12 status is responsible, at least in part, for the low milk folate concentrations reported in the present study cannot be discounted. Although the amount of vitamin B-12 consumed by the Otomi women in this study was not related to milk folate content, the median vitamin B-12 intake of the lactating Otomi women was 50% of that recommended and was considerably less than that of women in the US (40, 41). The low dietary vitamin B-12 intakes reported in the present study are consistent with those previously reported among rural Mexican and periurban Guatemalan lactating women (51, 52). Vitamin B-12 serves as a cofactor for the conversion of methyltetrahydrofolate to tetrahydrofolate. The latter is believed to be a preferred substrate for folylpolyglutamate synthetase, an enzyme responsible for attaching glutamate residues onto folate, which is a critical step in maintaining and concentrating this vitamin within mammary epithelial cells (48).

We acknowledge that the previously reported growth faltering of otherwise healthy breastfed infants in this rural farming community between 4 and 6 mo of age is probably due to many factors, including both nutritional and nonnutritional factors (eg, altitude, infection, etc) (16, 17). As previously shown, milk concentrations of energy, protein, carbohydrates, calcium, magnesium, phosphorus, and copper are probably not responsible for growth faltering because intakes appear to be comparable with those of healthy, breastfed American infants and exceed adequate intakes (16, 20–22). Although the zinc concentration in the milk of Otomi women at 4 and 6 mo postpartum is comparable with that in the milk of American women (20), there is controversy in the literature about whether either is sufficient to fully meet the growth requirements of rapidly growing infants after 4 mo of age (21). On the basis of unpublished data collected from 40 lactating Otomi women, we suspect that zinc intakes are low ( ± SEM = 2.6 ± 2.5 mg/d) relative to the recommended intake of 12 mg/d (21). National data from Mexico suggest that the median zinc intake of females aged 12–49 y is 6 mg/d (first, third quartile: 4.2, 8.2 mg/d) (43). Thus, Otomi infants may be born with low zinc stores and, as a consequence, may be disproportionately vulnerable to low milk zinc concentrations.

The relatively high altitude of Capulhuac (2800 m) may also influence the physical growth of Otomi infants. Birth weight and postnatal body size are lower at altitudes > 1500 m than at lower altitudes (53, 54). Although there appears to be some controversy as to whether postnatal weights are affected once they are adjusted for birth weight, there does appear to be a greater effect on linear growth after birth length is controlled for.

In conclusion, results from the present study suggest a high prevalence of suboptimal iron status, folate status, or both among lactating women in the rural farming community of San Mateo, Capulhuac, Mexico. In addition, median vitamin B-12 intakes were markedly lower than the intakes recommended during lactation. Despite poor maternal iron status, the milk iron concentrations reported in the present study would provide more than adequate amounts of bioavailable iron for breastfed infants. In contrast, milk folate concentrations may be limiting for some infants. Whether the milk folate concentrations reported in the present study are indeed sufficient to alter the folate metabolism and growth of exclusively breastfed infants in this community is worthy of further investigation.

	ACKNOWLEDGMENTS

 
SV and MFP designed the study. MEL, GR, and MJI collected the data and performed biochemical analyses. MEL and DLO performed data analysis and wrote the article. SV and MFP contributed significantly to the execution of the study and provided editorial assistance in writing the manuscript. None of the authors had any personal or financial conflicts of interest with the sponsoring institution.

	REFERENCES

TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 

1. Stoltzfus RJ. Defining iron-deficiency anemia in public health terms: a time for reflection. J Nutr 2001;131:565S–7S.[Abstract/Free Full Text]
2. Yip R. Iron deficiency. Bull World Health Organ 1998;76(suppl):121–3.
3. DeMaeyer E, Adiels-Tegman M. The prevalence of anaemia in the world. World Health Stat Q 1985;38:302–16.[Medline]
4. Sauberlich H. Folate status of US population groups. In: Bailey L, ed. Folate in health and disease. New York: Marcel Dekker, 1995:171–94.
5. O’Connor DL, Green T, Picciano MF. Maternal folate status and lactation. J Mammary Gland Biol Neoplasia 1997;2:279–89.[Medline]
6. Mackey AD, Picciano MF. Maternal folate status during extended lactation and the effect of supplemental folic acid. Am J Clin Nutr 1999;69:285–92.[Abstract/Free Full Text]
7. Metz J. Folate deficiency conditioned by lactation. Am J Clin Nutr 1970;23:843–7.[Abstract/Free Full Text]
8. Picciano MF. Folate nutrition in infancy. In: Picciano MF, Gregory J, Stokstad REL, eds. Folic acid metabolism in health and dsease. New York: Wiley-Liss and Sons, Inc, 1990:237–51.
9. O’Connor DL, Picciano MF, Sherman AR, Burgert SL. Depressed folate incorporation into milk secondary to iron deficiency in the rat. J Nutr 1987;117:1715–20.
10. O’Connor DL, Picciano MF, Sherman AR. Milk folate secretion and folate status of suckling pups during iron deficieny. Nutr Res 1989;9:301–18.
11. O’Connor DL, Picciano MF, Tamura T, Shane B. Impaired milk folate secretion is not corrected by supplemental folate during iron deficiency in rats. J Nutr 1990;120:499–506.
12. O’Connor DL, Picciano MF, Roos MA, Easter RA. Iron and folate utilization in reproducing swine and their progeny. J Nutr 1989;119:1984–91.
13. Matoth Y, Zehavi I, Topper E, Klein T. Folate nutrition and growth in infancy. Arch Dis Child 1979;54:699–702.[Abstract]
14. Vuori E, Makinen SM, Kara R, Kuitunen P. The effects of the dietary intakes of copper, iron, manganese, and zinc on the trace element content of human milk. Am J Clin Nutr 1980;33:227–31.[Abstract/Free Full Text]
15. Celada A, Busset R, Gutierrez J, Herreros V. No correlation between iron concentration in breast milk and maternal iron stores. Helv Paediatr Acta 1982;37:11–6.[Medline]
16. Butte NF, Villalpando S, Wong WW, et al. Human milk intake and growth faltering of rural Mesoamerindian infants. Am J Clin Nutr 1992;55:1109–16.[Abstract/Free Full Text]
17. Hernandez-Beltran M, Butte N, Villalpando S, Flores-Huerta S, Smith EO. Early growth faltering of rural Mesoamerindian breast-fed infants. Ann Hum Biol 1996;23:223–35.[Medline]
18. Picciano MF, Villalpando S, Fonseca C. Iron and/or folate deficiency is evident in lactating Mexican Otomi women.FASEB J 1998;12:A1170 (abstr).
19. Villalpando SF, Butte NF, Wong WW, et al. Lactation performance of rural Mesoamerindians. Eur J Clin Nutr 1992;46:337–48.[Medline]
20. Villalpando S, Butte NF, Flores-Huerta S, Thotathuchery M. Qualitative analysis of human milk produced by women consuming a maize-predominant diet typical of rural Mexico. Ann Nutr Metab 1998;42:23–32.[Medline]
21. National Research Council, Food and Nutrition Board. 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, 2001.
22. National Research Council, Food and Nutrition Board. Dietary reference intakes for calcium, phosphorus, magnesium, vitamin D, and fluoride. Washington, DC: National Academy Press, 1999.
23. Bindra GS, Gibson RS. Vitamin B12 and folate status of East Indian immigrants living in Canada. Nutr Res 1987;7:365–74.
24. Gibson RS. Principles of nutritional assessment. New York: Oxford University Press, 1990.
25. Kuczmarski RJ, Ogden CL, Grummer-Strawn LM, et al. CDC growth charts: United States. Adv Data 2000;314:1–27.[Medline]
26. Hernandez M, Bourges H. Valor nutritivo de los alimentos Mexicanos. Tables de uso pratico. (Nutritional values of foods. Tables for practical use.) Mexico City, National Institute of Nutrition, 1977 (in Spanish).
27. Tamura T. Microbiological assay of folate. In: Picciano MF, Gregory J, Stokstad REL, eds. Folic acid metabolism in health and disease. New York: Wiley-Liss and Sons, Inc, 1990:121–37.
28. Fielding J. Serum and iron binding capacity. In: Cook J, ed. Iron. New York: Churchill Livingstone, 1980.
29. Cook JD, Skikne BS. Iron deficiency: definition and diagnosis. J Intern Med 1989;226:349–55.[Medline]
30. Campbell M, Machin D. Medical statistics: a commonsense approach. Chichester, United Kingdom: John Wiley and Sons, Inc, 1993.
31. Latulippe ME, Rosas MG, Villalpando S, Picciano MF. Utility of TfR and TfR-ferritin index for assessment of iron deficiency is not complicated by folate deficiency in lactating women.FASEB J 2000;14:A508 (abstr).
32. WHO. Nutritional anaemias. Geneva: World Health Organization, 1968.
33. Yip R. Altitude and hemoglobin elevation: implications for anemia screening and health risk of polycythemia (abstract). In: Sutton JR, ed. Hypoxia and the brain: proceedings of the 8th International Hypoxia Symposium. Burlington, VT: Charles Houston, 1993.
34. Dirren H, Logman MH, Barclay DV, Freire WB. Altitude correction for hemoglobin. Eur J Clin Nutr 1994;48:625–32.[Medline]
35. Centers for Disease Control and Prevention. CDC criteria for anemia in children and childbearing-aged women. MMWR Morb Mortal Wkly Rep 1989;38:400–4.[Medline]
36. Brouwer DA, Welten HT, Reijngoud DJ, van Doormaal JJ, Muskiet FA. Plasma folic acid cutoff value, derived from its relationship with homocyst(e)ine. Clin Chem 1998;44:1545–50.[Abstract/Free Full Text]
37. Holm S. A simple sequentially rejective multiple test procedure. Scand J Stat 1979;6:65–70.
38. National Research Council, Food and Nutrition Board. Dietary reference intakes for energy, carbohydrates, fiber, fat, protein, and amino acids (macronutrients). Washington, DC: National Academy Press, 2002.
39. National Research Council, Food and Nutrition Board. Dietary reference intakes for thiamin, riboflavin, niacin, vitamim B6, folate, vitamin B12, pantothenic acid, biotin, and choline. Washington, DC: National Academy Press, 1998.
40. Borrud LG, Krebs-Smith SM, Friedman L, Guenther PM. Food and nutrient intakes of pregnant and lactating women in the United States. J Nutr Educ 1993;25:176–85.
41. Mackey AD, Picciano MF, Mitchell DC, Smiciklas-Wright H. Self-selected diets of lactating women often fail to meet dietary recommendations. J Am Diet Assoc 1998;98:297–302.[Medline]
42. Scholl TO, Johnson WG. Folic acid: influence on the outcome of pregnancy. Am J Clin Nutr 2000;71(suppl):1295S–303S.[Abstract/Free Full Text]
43. Villalpando S, Rivera J, Shamah T, Sepulveda J. Micronitrimentos. (Micronutrients.) In: Rivera R, Shamah, T, Villapando S, Gon’zalez T, Hernandez B, Sepulveda J, eds. Encuesta Nacional de Nutrición 1999. Estado nutriciio de niños y mujeres in Mexico. (National Nutrition Survey 1999. Nutritional status of children and women in Mexico.) Cuernavaca, Mexico: Instituto Nacional de Salud Publica, 2001.
44. Lim H, Mackey A, Tamura T, Wong S, Picciano MF. Measurable folates in human milk are increased by treatment with alpha-amylase and protease in addition to folate conjugase. Food Chem 1998;63:401–7.
45. Brown CM, Smith AM, Picciano MF. Forms of human milk folacin and variation patterns. J Pediatr Gastroenterol Nutr 1986;5:278–82.[Medline]
46. O’Connor D, Tamura T, Picciano MF. Pteroylpolyglutamates in human milk. Am J Clin Nutr 1991;53:930–4.[Abstract/Free Full Text]
47. Smith AM, Picciano MF, Deering RH. Folate supplementation during lactation: maternal folate status, human milk folate content, and their relationship to infant folate status. J Pediatr Gastroenterol Nutr 1983;2:622–8.[Medline]
48. O’Connor DL. Interaction of iron and folate during reproduction. Prog Food Nutr Sci 1991;15:231–54.[Medline]
49. Omer A, Finlayson ND, Shearman DJ, Samson RR, Girdwood RH. Plasma and erythrocyte folate in iron deficiency and folate deficiency. Blood 1970;35:821–8.[Abstract/Free Full Text]
50. Das K, Herbert V, Colman N, Longo DL. Unmasking covert folate deficiency in iron-deficient patients with neutrophil hypersegmentation: dU suppression tests on lymphocytes and bone marrow. Br J Haematol 1978;39:357–75.[Medline]
51. Black AK, Allen LH, Pelto GH, de Mata MP, Chavez A. Iron, vitamin B-12 and folate status in Mexico: associated factors in men and women and during pregnancy and lactation. J Nutr 1994;124:1179–88.
52. Casterline JE, Allen LH, Ruel MT. Vitamin B-12 deficiency is very prevalent in lactating Guatemalan women and their infants at three months postpartum. J Nutr 1997;127:1966–72.[Abstract/Free Full Text]
53. Yip R, Binkin NJ, Trowbridge FL. Altitude and childhood growth. J Pediatr 1988;113:486–9.[Medline]
54. Haas JD, Moreno-Black G, Frongillo EA Jr, et al. Altitude and infant growth in Bolivia: a longitudinal study. Am J Phys Anthropol 1982;59:251–62.[Medline]

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