Human milk provides a complex array of lipids that contribute energy, as well as the essential n-6 and n-3 PUFA to support the growth and development of the breast-fed infant. Although the maternal diet has little effect on the amount of fat or the distribution of lipid classes secreted in milk, the levels of unsaturated fatty acids are highly dependent on the types of fatty acids in the maternal diet. Over 200 fatty acids of different chain length and unsaturation have been identified in human milk, and they include the n-6 and n-3 fatty acids linoleic acid (LA; 18:2n-6) and α-linolenic acid (ALA; 18:3n-3) and their longer-chain metabolites arachidonic acid (ARA; 20:4n-6) and EPA (20:5n-3) and DHA (22:6n-3) respectively (Jensen, Reference Jensen1999; Innis, Reference Innis2004). The levels of n-6 and n-3 fatty acids, particularly LA, ALA and DHA, in human milk vary widely within and among different populations, and they are readily changed by the maternal dietary intake of the respective fatty acid (Innis, Reference Innis1992, Reference Innis2004). This variability in human milk fatty acids results in considerable differences in the intake and blood levels of n-6 and n-3 fatty acids among breast-fed infants. The role of DHA in the infant diet has received particular attention because DHA is selectively enriched in a few particular membrane lipids, which include the glycerophospholipids of the visual elements of the retina and brain grey matter. Importantly, DHA plays critical roles in the visual and neural systems, including such roles as protection from oxidative damage, neurogenesis, neurotransmitter metabolism, membrane protein functions, transmission of the visual signal and regulation of gene expression (Innis, Reference Innis2007). The present paper reviews recent understanding of PUFA in human milk, with a focus on maternal dietary lipids and DHA, and the implications for infant development.
Milk fat synthesis and composition
Milk fat consists predominantly of PUFA, which represent about 98 g/100 g milk total fat and are synthesized from glycerol and NEFA in the alveolar cells of the mammary gland (Jensen, Reference Jensen1999; Neville, Reference Neville2001). Fatty acids of C≥16 are taken up from plasma chylomicrons and VLDL-PUFA through the action of the mammary lipoprotein lipase. As such, the fatty acids in human milk may originate either from the recent dietary fatty acid intake, from fatty acids released from maternal adipose tissue or from de novo synthesis or further metabolism of dietary fatty acids in the maternal liver. Fatty acid synthesis in the mammary gland proceeds via the fatty acid synthetase enzyme complex, commencing with acetyl-CoA, followed by sequential addition of C2 units as malonyl-CoA, as in other cells. In tissues other than the mammary gland long-chain acyl thioesterase is part of the fatty acid synthetase complex and cleaves the fatty acyl chain at C16 to give rise to the SFA palmitic acid (16:0). In the mammary gland the cytosolic medium-chain acyl thioesterase, thioesterase 11, cleaves the fatty acyl chain at C14 to generate myristic acid (14:0), which explains the presence of medium-chain fatty acids in human milk and their increase during high-carbohydrate diets (Hachey et al. Reference Hachey, Silber, Wong and Garza1989). Conversion of acetyl-CoA to malonyl-CoA catalysed by acetyl-CoA carboxylase is the rate-limiting step in fatty acid synthesis and is regulated by insulin in a similar manner to that in other tissues. Several important differences in mammary gland fatty acid synthesis and in the effect of dietary lipids on milk fatty acids occur between ruminants and non-ruminants. In ruminants the primary sources of C for mammary-gland fatty acid synthesis are acetate and β-hydroxybutyrate, and as a result of metabolism by the rumen bacteria dietary fatty acids have little influence on the composition of cow's milk fatty acids (Jensen et al. Reference Jensen, Ferris, Lammi-Keefe and Henderson1990). Cow's milk typically contains <2 g LA and ALA/100 g total fatty acids and has negligible amounts of EPA and DHA. In man glucose-derived acetyl-CoA is the major source of C2 units for fatty acid synthesis, and the maternal dietary intake of PUFA has a marked effect on the amounts of n-6 and n-3 fatty acids secreted in milk (Innis, Reference Innis1992, Reference Innis2004; Jensen, Reference Jensen1999).
The long-chain SFA, cis-MUFA, trans-fatty acids and n-6 and n-3 PUFA are taken up by the mammary gland and then acylated into PUFA for secretion in milk. Mammary gland-specific acyl transferases preferentially esterify 16:0 and 18:0 at the centre sn-2 position of the human-milk PUFA, rather than at the sn-1 or sn-3 positions, as in other tissues (Jensen et al. Reference Jensen, Ferris, Lammi-Keefe and Henderson1990; Innis, Reference Innis2004). The products of hydrolysis of human-milk PUFA hydrolysis by gastric and pancreatic lipases are NEFA released from the PUFA sn-1 and sn-3 positions and sn-2 monoacylglycerols enriched in 16:0 and 18:0 (Innis et al. Reference Innis, Dyer and Nelson1994). This unusual structure of human-milk PUFA is believed to be important because non-esterified 16:0 and 18:0 have melting points (about 63°C and 69°C respectively) that are considerably above body temperatures and readily form insoluble soaps with Ca and other divalent cations at the pH of the intestine, resulting in faecal loss of both fat and important minerals (Kennedy et al. Reference Kennedy, Fewtrell, Morely, Abbott, Quinlan, Wells, Bindels and Lucas1999). Whether in breast-fed infants the distribution of fatty acids in the plasma chylomicron PUFA with 16:0 and 18:0 in the centre position also influences tissue n-6 and n-3 fatty acid delivery is not known. After absorption sn-2 monoacylglycerols are re-esterfied mainly via the 2-monoacylglycerol pathway, thus preserving the unusual position of fatty acids in human milk fat (Innis et al. Reference Innis, Dyer and Nelson1994).
LA and ALA cannot be formed by mammalian cells, and as a result all the n-6 and n-3 fatty acids secreted in milk must be derived from the maternal diet, either directly or after storage or further metabolism in maternal tissues. LA and ALA are present in the diet in greatest amounts in unsaturated plant, seed and nut oils, although different oils vary considerably in their LA and ALA content (Innis, Reference Innis2004). Once obtained from the diet LA and ALA can be further metabolized by Δ6-desaturation, elongation and Δ5-desaturation to form ARA and EPA respectively. The generally-accepted pathway for further metabolism of EPA to DHA is that proposed by Sprecher (1999). It involves two successive elongations of EPA to form 24:5n-3, then desaturation at position 6 to yield 24:6n-3, which is then translocated to the peroxisomes where a single cycle of β-oxidation generates 22:6n-3 (Innis, Reference Innis2003). Further metabolism of n-6 fatty acids to form docosapentaenoic acid (22:5n-6) is believed to occur through an analogous pathway. A characteristic feature of animals fed an n-3 fatty acid-deficient n-6 fatty acid-sufficient diet is a decrease in tissue levels of DHA and an increase in n-6 docosapentaenoic acid (Innis, Reference Innis1991, Reference Innis2003). Essential fatty acid deficiency involving an inadequate intake of both n-6 and n-3 fatty acids, on the other hand, results in a decrease in ARA and DHA and increased desaturation and elongation of the n-9 fatty acid oleic acid (18:1n-9) to give increased levels of 20:3n-9 and 22:3n-9 (Innis, Reference Innis1991).
As the synthesis of ARA, EPA, DHA and their intermediates is limited to animal cells, they are found in the diet only as part of animal tissue lipids (Innis, Reference Innis2003). While the richest dietary source of EPA and DHA is fish, most dietary ARA is derived from poultry and other meats (Kris-Etherton et al. Reference Kris-Etherton, Taylor, Yu-Poh, Huth, Moriarty, Fishell, Hargrove, Zhoa and Etherton2000; RW Freisen and SM Innis, unpublished results). ARA, EPA and DHA secreted into milk may originate either from the maternal diet or as a result of synthesis from their LA and ALA precursors respectively in the maternal tissues. In vitro the Δ6-desaturase that catalyses the first step in fatty acid desaturation shows substrate preference in the order ALA>LA>oleic acid (Innis, Reference Innis1991). However, in vivo a considerable proportion of ALA undergoes β-oxidation for energy, rather than undergoing desaturation and elongation, and as a result only small amounts of ALA are converted to DHA. The conversion of ALA to EPA and DHA in man, when estimated on the basis of the appearance of products of stable-isotope tracers of ALA in plasma, is very low, with <1% of the ALA converted to EPA and <0·1% converted to DHA (Williams & Burdge, Reference Williams and Burdge2006). Δ6- and Δ5-desaturases are expressed in rat mammary gland and enzyme expression is reduced by a maternal diet high in LA (Rodriguez-Cruz et al. Reference Rodriguez-Cruz, Tovar, Palacios-Gonzalez, del Prado and Torres2006). Currently, it is not known whether mammary gland LA or ALA desaturation contributes to the levels of longer-chain n-6 and n-3 fatty acids in human milk, or if such pathways, if present, are influenced by the maternal dietary LA intake. At present, there is no indication that mammary gland fatty acid desaturases contribute physiologically-relevant amounts of DHA to human milk.
Maternal dietary lipids and their effect on the composition of milk fat
The presence in human milk of a large number of fatty acids of different chain length and unsaturation, including many geometric and positional isomers, and the wide variability in milk fatty acid compositions among women have been known for many years. However, only recently has interest been directed towards the possibility that maternal lipid nutrition may adversely effect, as well as promote, the growth and development of the breast-fed infant. Observational and intervention studies have shown that levels of trans-fatty acids, oleic acid, LA, ALA and DHA in human milk show considerable variability, explained largely by the amount of the respective fatty acid in the maternal diet. For example, levels of trans-fatty acids derived from industrial hydrogenation of cis-unsaturated vegetable oils are higher in human milk in North America than in Europe, with levels as high as 18 g trans-fatty acids/100 g total fatty acids in the milk fat of some women (Innis, Reference Innis2006). High amounts of trans-fatty acids in human milk have raised concerns because of the possible adverse effects on essential fatty acid and lipid metabolism, as well as incorporation of unusual fatty acid isomers into the infant's tissues (Innis, Reference Innis2006). The levels of trans-fatty acids in human milk in Canada have now decreased with the introduction of food labelling and regulations to restrict the amounts of trans-fatty acids in retail foods (Friesen & Innis, Reference Friesen and Innis2006).
The effects of maternal dietary fat composition on the n-6 and n-3 fatty acid composition of human milk fatty acids are clearly shown by: a consideration of the changes in human-milk fatty acids over the last 50 years; a comparison of human milk fatty acids among women following vegan or mixed diets of different fat composition; the results of controlled interventions to alter maternal dietary fat intake. Early studies by Insull et al. (Reference Insull, Hirsch, James and Ahrens1959) have shown an LA content (g/100 g total fatty acids) of 7·7 in milk from women following their usual diet, which increases 4-fold to 41·4 when the diet is changed to 40% energy from maize oil (usual LA content of about 52) and to 10·4 when the diet has 40% energy from lard (LA content of about 10). Later studies in the 1960s have noted mean concentrations of 9·5 g LA/100 g total fatty acids in human milk (Tomarelli et al. Reference Tomarelli, Myer, Weaber and Bernhart1968). The mean levels of LA in human milk among women in the USA, Canada and Europe in most studies conducted from 1980 onwards are 12–16 g/100 g total fatty acids (Innis, Reference Innis1992; Jensen, Reference Jensen1999). However, the amount of LA in human milk varies widely among individual women, from about 6 g/100 g total fatty acids to >30 g/100 g total fatty acids in the milk fat of vegetarians (Innis & King, Reference Innis and King1999; Jensen, Reference Jensen1999; Sanders & Reddy, Reference Sanders and Reddy1992). In the population studied in Vancouver, Canada, LA in human milk (g/100 g total fatty acids) ranges from 6 to 22 (Innis & King, Reference Innis and King1999). Assuming an average of 3·7 g fat and 315 kJ (75 kcal)/100 ml milk and an intake of 780 ml/d by the infant, then the average and range of LA intake (g/d) among breast-fed infants are 3·46 and 1·73–6·20 respectively, equivalent to 5·3 and 2·7–9·5% total energy intake respectively. There is a high positive correlation between the LA content of human milk and the LA levels in the plasma PUFA and phospholipids in the recipient breast-fed infant (Innis & King, Reference Innis and King1999). Several conclusions can be drawn. First, all human milk meets and exceeds the dietary requirements for n-6 fatty acids, which is met by an intake of only 1–2% energy from LA (Innis, Reference Innis1991). Second, the intake of LA by the breast-fed infant is similar to that of adults in the same population. The high level of LA in Western diets has led to concern, particularly in relation to the concurrent low intake of n-3 fatty acids and the increasing prevalence of many inflammatory and immune disorders (Simopoulos, Reference Simopoulos1999; Calder, Reference Calder2006). Consequently, this area of infant nutrition is now becoming the subject of increasing interest, which should be extended to human milk lipids and the impact on the breast-fed infant (Calder et al. Reference Calder, Krauss-Etschmann, de Jong, Dupont, Frick and Frokiaer2006; Innis et al. Reference Innis, Pinsk and Jacobson2006).
Similar to LA, the levels of DHA in human milk also vary widely within and among populations (Innis, Reference Innis1992, Reference Innis2004), which again results in differences in the plasma and cell membrane levels of DHA among breast-fed infants (Gibson et al. Reference Gibson, Neuman and Makrides1997; Innis & King, Reference Innis and King1999; Jensen et al. Reference Jensen, Maude, Anderson and Heird2000; Innis et al. Reference Innis, Gilley and Werker2001). Milk fat from women following vegan diets, which lack DHA, contains <0·1 g DHA/100 g total fatty acids (Sanders & Reddy, Reference Sanders and Reddy1992), whereas much higher amounts, often >1 g DHA/100 g total fatty acids, are found in the milk of women consuming diets high in fish and other marine animals (Innis, Reference Innis1992, Reference Innis2004). The mean levels of DHA (g/100 g total fatty acids) in milk from women in Canada, the USA, Europe and Australia is 0·2–0·3 (Jensen, Reference Jensen1999; Innis, Reference Innis1992, Reference Innis2004), while population averages range from 0·07 in milk fat from women in some areas of Africa to 1·0 in milk fat of women in Japan (Innis, Reference Innis2004; Yukas et al. Reference Yukas, Pramul and Lien2006). In the study centre in Vancouver lactating women who exclusively breast-feed their healthy term infants and consume about 81 mg DHA/d have 0·17 g DHA/100 g total fatty acids in their milk fat at 30 d postnatally, while women who consume 131 mg DHA/d have 0·32 g DHA/100 g total fatty acids (Fig. 1). Studies in Norway, on the other hand, have shown mean levels of 0·5 g DHA/100 g total fatty acids in milk fat at 1 month post partum among women with a dietary intake of 200 mg DHA/d (Helland et al. Reference Helland, Saugstad, Smith, Saarem, Solvoll, Ganes and Drevon2001).
Similarly to LA, the consideration of mean levels of DHA in milk among groups of women hides the wide variability among individuals, which in the Vancouver study population extends from <0·1 g DHA/100 g total fatty acids to 1·0 g DHA/100 g total fatty acids in the milk fat of women who are not taking DHA supplements (Innis & King, Reference Innis and King1999; Friesen & Innis, Reference Friesen and Innis2006). This range in mean values is similar across different countries (Innis, Reference Innis1992, Reference Innis2004; Jensen, Reference Jensen1999; Yukas et al. Reference Yukas, Pramul and Lien2006). Assuming an average of 3·7 g fat and 315 kJ (75 kcal)/100 ml milk and an intake of 780 ml/d by the infant, then the average intake of DHA among breast-fed infants consuming milk with 0·2 g DHA/100 g total fatty acids is 0·056 g/d, representing 0·086% total energy. A range of 0·1–1·0 g DHA/100 g total fatty acids in human milk fat is equivalent to a potential DHA intake ranging from 0·028 g/d to 0·280 g/d, or from 0·04% total energy intake to 0·4% total energy intake from DHA among breast-fed infants. Although theoretical, these estimations illustrate a very wide variation in n-3 fatty acid intakes, as well as n-6 fatty acid intakes, among breast-fed infants.
An increase in DHA intake among lactating women through supplementation with fish, fish oils, single-cell PUFA, DHA-enriched eggs or other sources of DHA increases the secretion of DHA in milk, and increases the plasma and erythrocyte (RBC) levels of DHA in the recipient breast-fed infant (Henderson et al. Reference Henderson, Jenson, Lammi-Keefe, Ferris and Dardick1992; Gibson et al. Reference Gibson, Neuman and Makrides1997; Fidler et al. Reference Fidler, Sauerwald, Pohl, Demmelmair and Koletzko2000; Jensen et al. Reference Jensen, Maude, Anderson and Heird2000). Increased intakes of ALA, however, have been shown in an intervention study using supplements of ALA and supplements of DHA to have little or no effect in increasing the secretion of DHA in human milk (see Innis, Reference Innis2004). In summary, observational and intervention studies concur that the most important factor determining the secretion of DHA in human milk is the mother's intake of DHA. Since maternal fatty acid nutrition impacts on the quality of human milk fatty acids, consideration is needed as to what lipid nutrition meets the needs of the mother herself and that required to support optimal growth and development of her infant.
PUFA in human milk and the breast-fed infant
Human milk provides the only source of n-6 and n-3 fatty acids to support the growth and development of the breast-fed infant during breast-feeding and for much of early infancy, when foods such as Fe-fortified infant cereals, vegetables, fruits and dairy products, all of which are low in n-6 and n-3 fatty acids unless fortified, are added to the infant diet.
Particularly high concentrations of DHA are present in phosphatidylserine and the ethanolamine phosphoacylglycerols (ethanolamine plasmalogen and phosphatidylethanolamine (PE)) of brain grey matter and the outer segments of rod and cone photoreceptors in the retina (Innis, Reference Innis2003). DHA comprises ⩽80% of the PUFA in the retina outer segment disks, and phospholipids are present in which both fatty acids are DHA. In vitro studies have provided evidence that DHA plays a role in photoreceptor signal transduction by influencing the ability of photons to transform rhodopsin to the activated meta-rhodopsin ll state and the efficiency of G-protein-coupled receptor signalling (Niu et al. Reference Niu, Mitchell, Lim, Wen, Kim, Salmen and Litman2004). More recently, it has been shown (Soubias et al. Reference Soubias, Teaque and Gawrish2006) that there are specific binding sites for DHA in the rhodopsin molecules. In the brain DHA is enriched in synaptic terminal membranes and has diverse roles in brain growth and function and in protecting against oxidative stress (Innis, Reference Innis2007). Although much remains to be understood, recent experimental studies have shown (Bazan, Reference Bazan2006; Innis, Reference Innis2007) that reduced levels of DHA in the brain impair neurogenesis and neurite outgrowth and alter the metabolism of several neurotransmitters, including dopamine, serotonin and acetylcholine. DHA is also a ligand for nuclear hormone transcription factors, targets for which include genes involved in synaptic plasticity, endocytosis, signal transduction and synaptic vesicle recycling, and the precursor to resolvins and neuroprotectins that protect against oxidative damage.
Thus, DHA is important in the central nervous system, is present in human milk and early deficiencies in key nutrients have the potential to result in long-term effects on cognitive and behavioural functions. These factors have stimulated intense interest in the role of DHA in infant nutrition, particularly in relation to the fatty acid composition of infant formulas (Lauritzen et al. Reference Lauritzen, Hansen, Jorgensen and Michaelsen2001; Heird & Lapillonne, Reference Heird and Lapillonne2005; Fewtrell, Reference Fewtrell2006; Uauy & Dangour, Reference Uauy and Dangour2006). Growth of membrane structures, involving cell division, myelination and such processes as neurite extension and dendritic arborization, requires the synthesis of large amounts of new membrane material, which results in a high demand for DHA. The rate of brain growth is at peak velocity during the last 3 months of gestation and the first few months after birth (Innis, Reference Innis1991), leading to a general concept that DHA requirements in the human infant may be particularly high during the later stage of gestation and in early infancy.
It is now well known that the inclusion of DHA in infant formulas increases DHA in a dose-dependent manner in the blood lipids of infants fed formula (Makrides et al. Reference Makrides, Neumann, Simmer and Gibson1995; Carlson et al. Reference Carlson, Ford, Werkman, Peeples and Koo1996; Innis et al. Reference Innis, Auestad and Siegman1996; Birch et al. Reference Birch, Hoffman, Uauy, Birch and Prestidge1998). In addition, some studies (Birch et al. Reference Birch, Hoffman, Uauy, Birch and Prestidge1998, Reference Birch, Garfield, Hoffman, Uauy and Birch2000; Hoffman et al. Reference Hoffman, Birch, Castaneda, Fawcett, Wheaton, Birch and Uauy2003) have reported that the addition of DHA to infant formulas increases visual and neural system maturation in term-gestation infants who are fed formula from birth or after initial breast-feeding. Similarly, although less well appreciated, the circulating blood levels of DHA in breast-fed infants depend on the concentration of DHA in the mother's milk, which in turn depends on the amount of DHA in the mother's diet (Gibson et al. Reference Gibson, Neuman and Makrides1997; Innis & King, Reference Innis and King1999; Fidler et al. Reference Fidler, Sauerwald, Pohl, Demmelmair and Koletzko2000; Jensen et al. Reference Jensen, Maude, Anderson and Heird2000; Innis et al. Reference Innis, Gilley and Werker2001). Early studies by Sanders & Reddy (Reference Sanders and Reddy1992) have shown levels of 1·9 (se 0·32) g DHA/100 g RBC total fatty acids in breast-fed infants whose mothers followed a vegan diet (and thus devoid of DHA) compared with 6·2 (se 0·41) g DHA/100 g RBC total fatty acids in breast-fed infants whose mothers followed mixed diets. In the same study the RBC fatty acids of infants fed formula with no DHA were found to contain 3·7 (se 0·21) g DHA/100 g. As in adults, increasing the dietary intake of ALA has no measurable effect in increasing blood levels of DHA in young infants (Ponder et al. Reference Ponder, Innis, Benson and Siegman1992). These findings suggest that DHA intake, either from the mother's breast milk or infant formula, is the most important determinant of the infant's blood levels of DHA. Research by the author's group in Canada has focused on the variability in maternal dietary DHA intake, and the implications for infant development of low maternal DHA status during both gestation and lactation.
A prospective approach has first addressed whether the variability in human milk DHA is likely to be related to visual and neural development among breast-fed infants (Innis et al. Reference Innis, Gilley and Werker2001; Innis, Reference Innis2003). Healthy term-gestation infants (n 88) were assessed using measures of visual acuity, language, mental and motor skill development from birth to 18 months of age, and the Standford-Binet intelligence test was undertaken at 5 years of age. Milk samples and infant blood samples were collected at 60 d after birth, at which time all the infants were exclusively breast-fed. The results show that infants in the lowest tertile of RBC PE-DHA at 60 d of age have significantly lower visual acuity at 60 and 365 d of age than infants in the highest tertile of RBC PE-DHA (Innis et al. Reference Innis, Gilley and Werker2001; Fig. 2). The analysis of the mother's milk fat indicates that infants in lowest, middle and highest tertile of DHA status were fed milk containing mean levels of DHA of 0·17, 0·20 and 0·31 g/100 g total fatty acids respectively. Multivariate analysis controlling for environmental, maternal and infant variables that are known to influence infant development shows that infant DHA status at 60 d of age is related to language development at 9 and 18 months of age, although there are no significant relationships with scores for the Bayley Scales of Mental or Motor Skill Development at 18 months of age or with tests of novelty preference at 9 months of age (Innis et al. Reference Innis, Gilley and Werker2001; Innis, Reference Innis2003). In agreement with this work, studies in other countries (Jorgensen et al. Reference Jorgensen, Hernell, Hughes and Michaelsen2001; Lauritzen et al. Reference Lauritzen, Jorgensen, Mikkelsen, Skovgaard, Straarup, Olsen, Hoy and Michaelsen2004) have also shown a positive relationship between human milk levels of DHA and visual function maturation in breast-fed infants. Some studies (Helland et al. Reference Helland, Smith, Saarem, Saugstad and Drevon2003; Jensen et al. Reference Jensen, Voigt, Prager, Zou, Fraley, Rozelle, Turcich, Llorente, Anderson and Heird2005) have reported an association between infant DHA status at birth or during breast-feeding and scores for tests of cognitive function when measured later in early childhood. In a follow-up of fifty-five infants from the Vancouver studies (Innis et al. Reference Innis, Gilley and Werker2001; Innis, Reference Innis2003), however, correction could not be made for the concurrent child diet at 5 years of age, and it was found that mothers with low milk levels of DHA whose children had a low DHA during breast-feeding also fed their child diets low in DHA. It is recognized that, although consistent with an important role of DHA in retinal and neural function, other dietary or lifestyle variables could explain the statistical associations between DHA and infant development (Innis et al. Reference Innis, Gilley and Werker2001; Innis, Reference Innis2003). Also evident is the strong probability that women with low intakes of DHA during lactation also have low intakes of DHA in gestation, which could have long-term effects secondary to the role of DHA in neurogenesis (Innis, Reference Innis2007).
The current studies in Vancouver are investigating whether women with low levels of DHA in their milk also have a low DHA status in gestation. Using dietary intervention with DHA, these studies are also investigating whether n-3 fatty acid deficiency occurs among pregnant and lactating women and whether it poses a risk of reduced visual and neural system maturation among infants in the study population. Women are asked to take a supplement of 400 mg DHA/d from single-cell PUFA or a maize–soybean oil placebo from 16 weeks of gestation until delivery. Maternal dietary intake and blood lipid DHA are determined at 16 and 36 weeks of gestation, milk fatty acids are analysed at 30 d after delivery and infant visual, mental and motor skill development are assessed to 18 months of age. Several concepts not previously considered in studies on DHA and infant development, but which are important in nutritional studies in individuals not known to have deficiency, are included. First, because the relationship between the intake of an essential dietary factor and functions dependent on that factor is not linear but plateaus at intakes equal to and above need, only the individuals who are deficient can benefit from intervention. However, since blood levels of DHA continue to increase with increasing DHA intake, a linear relationship between DHA intake or blood levels of DHA and measures of functions dependent on DHA can occur only when all or almost all individuals in the group are deficient. Careful studies in animals have shown that dietary n-3 fatty acid deficiency results in reduced retinal and visual acuity (Innis, Reference Innis1991), and clinical studies concur that infant visual acuity at 60 d of age is the most robust reproducible measure of inadequate DHA (SanGiovanni et al. Reference SanGiovanni, Berkey, Dwyer and Colditz2000). Different from drug studies, in the Vancouver dietary study the placebo group is not a non-exposure group, and overlap will occur between individuals in the placebo group with a high habitual DHA intake and deficient individuals in the DHA intervention group with a low DHA intake. Analysis of the RBC-membrane PE is used as a measure of DHA status because it avoids problems in the analysis of fatty acids in plasma total lipids or phospholipids that results from short-term dietary effects and heterogeneity in plasma lipoproteins (VLDL, LDL and HDL) in which lipids (cholesteryl esters, TAG, phospholipids) are carried. Maternal blood is collected at 36 weeks of gestation to avoid possible variables associated with labour and delivery.
Whether women with low levels of DHA in their milk also have a low DHA status in gestation is demonstrated by the milk fat levels of 0·17 and 0·32 g DHA/100 g total fatty acids at 30 d postnatally for women who had an RBC PE-DHA of <8·5 (n 17) and >8·5 (n 22) g/100 g total fatty acids at 36 weeks of gestation respectively (P<0·05; Fig. 1). Dietary analyses show that the intakes of DHA are also different (81 (se 2) and 131 (se 2) mg/d respectively for the two groups; P<0·05). These prospective studies establish that women with low DHA levels in their milk also have low blood levels of DHA and low DHA intakes in gestation. The presence of n-3 fatty acid deficiency is revealed by the effect of DHA intervention on the maternal blood lipid fatty acids and infant visual acuity scores. Women in the placebo group who took the maize–soybean oil placebo were found to have RBC PE-DHA levels at 16 and 36 weeks of gestation of 9·0 (se 0·31) and 8·6 (se 0·31) g/100 g total fatty acids, respectively. However, women assigned to 400 mg DHA/d were found to have a 42% higher RBC PE-DHA level (12·3 (se 0·31) g/100 g total fatty acids; P<0·001) at 36 weeks. An increase in C22n-6 fatty acids, particularly docosapentaenoic acid, occurs in animals fed an n-3 fatty acid-deficient diet (Innis, Reference Innis1991). Women in the placebo group were found to show a significant increase in docosapentaenoic acid (g/100 g total fatty acids) between 16 and 36 weeks of gestation (from 0·82 (se 0·05) to 1·08 (se 0·05); n 50; P<0·01), as compared with the DHA intervention group (0·95 (se 0·06) and 0·73 (se 0·03) respectively (n 49); P<0·005). The increase in n-6 docosapentaenoic acid with no change in DHA in the placebo group is consistent with increased fatty acid desaturation in pregnancy (Williams & Burdge, Reference Williams and Burdge2006), but proceeding with n-6 fatty acids because of inadequate n-3 fatty acid nutrition. In the absence of n-3 fatty acid deficiency visual acuity scores should not differ among 60-d-old infants grouped into tertiles based on their mother's DHA status during gestation. However, as shown in Fig. 3, mean visual acuity scores (expressed in cycles per degree and sd expressed in octaves, where one cycle per degree is equivalent to 0·301 octaves) were found to be significantly lower among infants in the lowest tertile of maternal DHA status compared with those in the highest tertile (2·21 (sd 0·51; n 22 comprising n 21 for placebo and n 1 for DHA intervention) v. 2·44 (sd 0·48; n 17 comprising n 2 for placebo and n 15 for DHA intervention); P<0·05). The mean visual acuity scores were 2·33 cycles per degree (sd 0·59 octaves; n 50 comprising n 27 for placebo and n 23 for DHA intervention) for infants in the middle tertile of maternal DHA status. Multivariate analyses, including maternal DHA status, supplement group, infant gender, birth weight, length, gestational age at birth, breast-feeding, breast-feeding duration and maternal ethnicity, which together account for 86% of the variability in infant visual acuity at 60 d of age, show that infants in the placebo group have a 2-fold greater risk (OR 2:1) of having a visual acuity score of <2·32 cycles/degree (the mean score of the study population; n 99). The mean visual acuity scores of infants in the DHA intervention and placebo group were not significantly different (cycles per degree; 2·40 (sd 0·53 octaves) and 2·24 (sd 0·53 octaves) respectively; P>0·05), which is explained by the large overlap of sufficient and deficient individuals in the placebo and DHA group respectively. As maternal DHA supplementation decreases the risk of low infant visual acuity, it is likely that the higher proportion of infants with low visual acuity scores in the placebo group is explained by inadequate n-3 fatty acid nutrition among pregnant and lactating women in the study population. However, the studies do not separate the effects of low maternal DHA status in gestation and lactation. While it is of biological interest to separate the effects of maternal fatty acid nutrition on infant development before and after birth, and this approach does have relevance to the design of human milk substitutes, in practice women with low intakes of DHA in lactation also have low intakes of DHA in gestation. The results of the observational and intervention studies could suggest that increased risk of inadequate maternal n-3 fatty acid nutrition to support optimal infant development occurs at maternal intakes of ⩽80 mg DHA/d and milk levels of <0·2 g DHA/100 g total fatty acids. Data derived from autopsy analysis indicate that the fetus accumulates about 70 mg DHA/d during the last trimester of gestation (Clandinin et al. Reference Clandinin, Chappell, Helm, Swyer and Chance1981), and DHA accretion in the human forebrain follows a linear pattern through at least the 12 months after birth (Martinez, Reference Martinez1992). Assuming an average of 37 g fat/l milk, a daily intake of 780 ml human milk with 0·2 g DHA/100 g total fatty acids will provide 56 mg DHA/d to the infant, which is less than projected requirements.
In summary, while the importance of the differences in n-6 and n-3 fatty acids, particularly differences in DHA between human milk and infant formulas, has been the subject of intense clinical research, the n-6 and n-3 fatty acids in human milk also vary widely. As a result, there are marked differences in n-6 and n-3 fatty acid intake among breast-fed infants. Dietary patterns in relation to selection of fats and oils and the choice of whether or not to eat fish appear to be relatively stable. As a result, differences in the n-6 and n-3 fatty acids in human milk affect not only differences in the supply of n-6 and n-3 fatty acids to the breast-fed infant, but also differences in the supply of these fatty acids to the infant before birth. The dependence of human milk LA and DHA on the maternal dietary fat composition shows that for infant feeding human milk is not a gold standard for these fatty acids. Dietary guidelines aimed at reducing risk of chronic disease need to be cognisant that when followed by pregnant and lactating women they also have a marked effect on the amount and balance of n-6 and n-3 fatty acids transferred to the infant before and after birth. The Vancouver studies emphasize the need for dietary fat recommendations for pregnancy and lactation, specific stages of the life cycle involving anabolism and transfer of nutrients to the developing infant. In the absence of dose–response studies to determine safe upper limits for fatty acid supplements during pregnancy, a practical approach, if supplements are to be used, is to use a supplement within the range that would be achieved by currently-recommended intakes of fish (1 g fish oil/d).