The Impact of Maternal Nutrition on the Offspring Nestlé Nutrition Workshop Series
Transcription
The Impact of Maternal Nutrition on the Offspring Nestlé Nutrition Workshop Series
Nestlé Nutrition Workshop Series Pediatric Program Volume 55 The Impact of Maternal Nutrition on the Offspring Information for the medical profession only Printed in Switzerland art. 4391 GB © 2004, Nestec Ltd., avenue Nestlé 55, CH-1800 Vevey, Switzerland. Printed by Les Presses de la Venoge S.A., CH-1026 Denges, Switzerland. All rights reserved. Unless special permission in writing is obtained, no part of this publication may be reproduced, stored in a retrieval system, or be transmitted in any form or by any means, electronic, mechanical, photocopying or otherwise. The material contained in this issue was submitted as previously unpublished material, except in the instances in which credit has been given to the source from which some of the illustrative material was derived. Nestec Ltd. cannot be held responsible for errors or omissions, or for any consequences arising from the use of the information contained herein. © 2004, Nestec Ltd., Vevey, Switzerland Nestlé Nutrition Workshop Series Pediatric Program Volume 55 The Impact of Maternal Nutrition on the Offspring Beijing, April 25–29, 2004 Editors G. Hornstra R. Uauy X. Yang Contents iv Foreword 1 Maternal Nutrition and Adverse Pregnancy Outcomes: Lessons from Epidemiology M.S. Kramer 2 Nutrients Effects upon Embryogenesis: Folate, Vitamin A and Iodine T.H. Rosenquist, J.G. van Waes, G.M. Shaw and R. Finnell 5 Energy Requirements during Pregnancy and Consequences of Deviations from Requirement on Fetal Outcome N.F. Butte 7 Essential Fatty Acids during Pregnancy: Impact on Mother and Child G. Hornstra 11 Dietary Essential Fatty Acids in Early Postnatal Life: Long-Term Outcomes R. Uauy, C. Rojas, A. Llanos and P. Mena 19 Nutrient-Induced Maternal Hyperinsulinemia and Metabolic Programming in the Progeny M.S. Patel, M. Srinivasan and S.G. Laychock 22 Maternal Malnutrition and the Risk of Infection in Later Life S.E. Moore, A.C. Collinson, P.T. N’Gom and A.M. Prentice 27 Size and Body Composition at Birth and Risk of Type-2 Diabetes: A Critical Evaluation of ‘Fetal Origins’ Hypothesis for Developing Countries C.S. Yajnik ii 28 Cardiovascular Diseases in Survivors of the Dutch Famine O.P. Bleker, T.J. Roseboom, A.C.J. Ravelli, G.A. van Montfrans, C. Osmond and D.J.P. Barker 30 The Relationship between Maternal Obesity and Adverse Pregnancy Outcomes D.K. Waller and T.E. Dawson 32 Special Problems of Nutrition in the Pregnancy of Teenagers P.B. Pencharz 33 Dietary Intervention during Pregnancy and Allergic Disease in the Offspring S. Salvatore, K. Keymolen, R.K. Chandra and Y. Vandenplas 35 List of Speakers iii Foreword For this 55th Nestlé Pediatric Nutrition Workshop, which took place in April 2004 in Beijing, the topic ‘The Impact of Maternal Nutrition on the Offspring’ was chosen. We know a lot about the appropriate nutrition of infants and children. When it comes to the point whether the nutritional status of a pregnant mother has an impact on the development of the fetus in the womb and subsequently on that of her child, there are little data except some very fundamental ones; most knowledge derives from animal studies. The intention of this workshop was to learn more about the effects of maternal nutrition on fetal growth, metabolic programming, the requirements of energy and various nutrients as well as the effects of under- and overnutrition during pregnancy. Finally, the question of whether a distinct diet during pregnancy could reduce food allergy in the offspring was addressed. I would like to thank the three chairmen, Prof. Gerard Hornstra, Prof. Ricardo Uauy and Prof. Xiaoguang Yang, who are recognized experts in this field, for putting the program together and inviting the opinion leaders in the field of maternal and infant nutrition as speakers. Pediatricians from 18 countries contributed to the discussions that are published in the book, which will be published after this booklet. Mrs. Kelan Liu and her team from Nestlé China provided all the logistic support, enabling the participants to enjoy the Chinese hospitality. Dr. Philippe Steenhout from Nestlé’s Nutrition Strategic Business Division in Lausanne, Switzerland, was responsible for the scientific coordination. His cooperation with the chairpersons was essential to the success of this workshop. Prof. Wolf Endres, MD Vice-President Nestec Ltd., Lausanne, Switzerland iv Maternal Nutrition and Adverse Pregnancy Outcomes: Lessons from Epidemiology Michael S. Kramer This chapter reviews the epidemiologic evidence concerning the role of maternal nutrition in the etiology of adverse pregnancy outcomes. Descriptive epidemiologic studies are used to summarize geographic and temporal occurrence patterns in preterm birth, intrauterine growth restriction (IUGR), mean birth weight, and fetal and infant mortality. Rates of most adverse pregnancy outcomes are falling in both developed and developing countries, but rates of preterm birth and large-for-gestational-age (LGA) infants are on the rise. Observational studies are reviewed to summarize the evidence concerning the effects of maternal anthropometry (height, pre-pregnancy body mass index, and gestational weight gain). All of these maternal anthropometric factors are associated with fetal growth, with reduced risks of IUGR but increased risks of LGA birth in mothers who are taller, heavier, or have higher weight gains. Importantly, maternal obesity is also strongly associated with an increased risk of stillbirth. As revealed in observational studies of famine and controlled supplementation trials, energy intake is clearly associated with fetal growth. Energy supplementation may also reduce the risk of stillbirth and neonatal death. Other than iodine for preventing cretinism in iodine-deficient geographic regions and folic acid for preventing neural defects, supplementation with micronutrients, either in isolation or combination, has not been clearly demonstrated to be beneficial for pregnancy outcomes. Calcium and fish oil supplementation, however, show promise for reducing preterm birth and justify additional randomized trials. 1 Nutrients Effects upon Embryogenesis: Folate, Vitamin A and Iodine T h o m a s H . R o s e n q u i s t , J a n e e G e l i n e a u v a n Wa e s , Gary M. Shaw and Richard Finnell Deficiencies of folic acid, vitamin A, and iodine are widespread. An insufficient supply of any of these nutrients during embryogenesis may result in major developmental anomalies including neural tube closure defects, orofacial defects, and conotruncal heart defects. These are among the most common and devastating of developmental anomalies, and each is the result of perturbed development of cells of the embryonic neural crest and neural tube. Folic Acid Perinatal folic acid (folate) supplementation is especially effective in reducing the rate of neural tube and neural crest abnormalities. Folate is a cofactor in two metabolic processes that are vitally important to normal embryonic development, DNA synthesis and gene methylation. These processes may be impaired in embryos with a folate deficit. If that deficit results from abnormal uptake of folate by the embryo itself, perinatal folate supplementation my offer protection to the embryo even when conventional tests may indicate that maternal folate status is normal. Supplementary folic acid may also protect embryos by reducing their exposure to homocysteine, which rises inversely with folic acid, and has been shown by both epidemiological and experimental evidence to induce abnormal development of the neural crest and neural tube. Vitamin A Vitamin A is required for pattern formation during embryogenesis, and it regulates key developmental processes: apoptosis, proliferation, 2 Thymidylate Folate DNA Methylation Homocysteine Maternal diet Vit A Mitosis ret RA nm Gene regulation RXR/RAR Early brain development Transthyretin Iodine TR RXR/TR Late brain development Fig. 1. Mechanisms for the regulation of developmental processes by folate, vitamin A and iodine, and interactions among these key nutrients. This figure highlights brain development during embryogenesis when neural tube closure occurs (Early brain development) and after week 15 of gestation (Late brain development) when neurogenesis, cell migration and synaptogenesis are the dominant processes. Folate metabolism may impact upon retinoic acid (RA) synthesis when elevated homocysteine interferes with the processing of retinal. Elevated homocysteine also may provoke dysregulation of genes in early development via its effect upon the calcium channel of the N-methylD-aspartate type of glutamate receptor (nm) on neural crest or neural tube cells. Vitamin A (Vit A) is transported in the serum bound by transthyretin in common with thyroid hormone. In the cell nucleus, a retinoid X receptor/ triiodothyronine heterodimer (RXR/TR) may regulate gene expression related to both early and late brain development. RAR Retinoic acid receptor. differentiation, and migration. By a complex interactive set of receptors, vitamin A as retinoic acid regulates the expression of early-acting genes that are fundamental to normal development. These include the retinolbinding proteins on the plasma membrane; the cytoplasmic retinolbinding proteins and the cytoplasmic retinoic acid-binding proteins, and in the nucleus, the retinoic receptors (RARs) and the retinoid X receptors (RXRs). An RXR may form a heterodimer with another RXR, an RAR, a nuclear thyroid receptor, or a nuclear vitamin D receptor; and these heterodimers regulate the expression of early-expressed genes that are the basis for normal development, especially the Hox family of genes. The temporal and spatial distribution of these receptors during embryogenesis determines the ultimate phenotype of the embryo, 3 fetus and neonate. By altering their expression, both hypo- and hypervitaminosis A can disrupt the elegant hierarchy that is required for normal development, especially of the neural crest and neural tube: hypo-vitaminosis A by failure to activate, and hyper-vitaminosis A by inappropriately activating one or more of the key Hox or related genes. Iodine The only known biological function of iodine in humans is its role in the synthesis of the thyroid hormones triiodo-L-thyronine (T3) and tetraiodo-L-thyronine (T4), and all adverse developmental effects of iodine deficiency are the result of hypothyroidism. The most wellknown of these adverse effects involve disordered brain development, for example cretinism, and they arise principally during stages of development that are later than embryogenesis. However, there is growing evidence that an adequate supply of maternal hormone also may be essential during embryogenesis. Embryos express thyroxin receptors during early embryogenesis, and experimentally increased or decreased exposure to thyroxin during embryogenesis can induce major structural defects of neural tube derivatives. However, unlike the case for folic acid or vitamin A, the mechanism by which maternal thyroxin might contribute directly to the regulation of early developmental events is not yet known. In addition to their separate effects upon early development, folic acid, vitamin A and thyroid hormone may interact in complex ways to maintain normal developmental potentials in the early embryo; and conversely, a reduction in the availability of one of these key nutrients may produce an unexpected impact upon the availability or synthesis of another. These relationships are outlined in figure 1. 4 Energy Requirements during Pregnancy and Consequences of Deviations from Requirement on Fetal Outcome N a n c y F. B u t t e Energy requirements of pregnancy are comprised of the energy deposited in maternal and fetal tissues, and the rise in energy expenditure attributable to basal metabolism and physical activity. Because of uncertainties regarding desirable gestational weight gain (GWG), maternal fat deposition, putative reductions in physical activity and energetic adaptations to pregnancy, controversy remains regarding the energy requirements during pregnancy. The objectives of this chapter are to review: (1) energy requirements during pregnancy; (2) energetic adaptations to pregnancy, and (3) the consequences of deviations from maternal energy requirement on fetal outcome. Energy requirements during pregnancy in healthy, normal-weight women were estimated factorially from the increment in basal metabolic rate (BMR) and from the increment in total energy expenditure (TEE), plus the energy deposition associated with a mean GWG of 13.8 kg. Energy deposition was determined from fat (4.3 kg) and protein (686 g) accretion. BMR increased on average over pre-gravid values by 4, 10 and 24% in the first, second and third trimesters, respectively. Freeliving TEE increased on average by 1, 6 and 19% across pregnancy. The incremental cost of pregnancy was 371 MJ, distributed as 430, 1,375 and 2,245 kJ/day for the first, second and third trimesters, respectively. Incremental cost of pregnancy predicted for women with a mean GWG of 12.0 kg, as found in the WHO Collaborative Study on Maternal Anthropometry and Pregnancy Outcomes, was 323 MJ, distributed as 375, 1,200 and 1,950 kJ/day for the first, second and third trimesters, respectively. Energetic adaptations in basal metabolism, energetic efficiency and physical activity can occur to meet the increased energy needs of pregnancy. Suppression of BMR, increased energetic efficiency in 5 weight-bearing activity, and declines in physical activity as pregnancy progresses, all act to conserve energy. Although these adaptations may protect the fetus from environmental and nutritional stresses, they may not totally prevent adverse pregnancy outcomes. Negative deviations from maternal energy requirement (dietary energy deficiency) can perpetuate low maternal weights and inadequate weight gains during pregnancy. Failure of the materno-placental supply to satisfy fetal energy and nutrient requirements can result in intrauterine growth retardation, increased perinatal and neonatal morbidity and mortality, and a range of adaptations and developmental changes which may lead to permanent structural and metabolic alterations which may influence metabolic diseases later in life. In the WHO Collaborative Study on Maternal Anthropometry and Pregnancy Outcomes, pre-pregnancy weight and attained weight at 36 weeks of gestation were the most significant predictors of low-birth weight infants. Positive deviations from maternal energy requirement can result in excessive GWG. High GWG is associated with high-birth weight, which can secondarily lead to prolonged labor, cesarean delivery, shoulder dystocia, birth trauma and asphyxia. Women who are overweight are much more likely to have gestational diabetes and glucose intolerance, and in turn produce larger infants with a propensity to childhood obesity and adolescent-onset of type-2 diabetes. Although energetic-sparing adaptations can occur during pregnancy to protect the fetus from environmental and nutritional stresses, they may not totally prevent adverse maternal and fetal outcomes. Every effort should be made to provide pregnant women with sufficient but not excessive food to meet the substantial energy demands of pregnancy. 6 Essential Fatty Acids during Pregnancy: Impact on Mother and Child Gerard Hornstra Essential fatty acids (EFAs) and their longer chain, more unsaturated derivatives, the so-called LCPUFAs, are indispensable for human development and health. Since these essential polyunsaturated fatty acids (EPUFAs) cannot (EFAs) or hardly (LCPUFAs) be synthesized by man, they need to be consumed with the diet. Consequently, the LCPUFA status of the developing fetus depends on that of its mother, as is also suggested from the positive relation observed between maternal EPUFA consumption and neonatal EPUFA status. Pregnancy is associated with increasing amounts of LCPUFAs in maternal plasma phospholipids (PLs). However, a relatively stronger increase in the amounts of EPUFA ‘shortage markers’ indicates that the increased LCPUFA demand during pregnancy is not adequately covered. In figure 1 this is shown for docosahexaenoic acid (DHA; 22:6n-3), the major LCPUFA in the central nervous system, and its shortage marker Osbond acid (ObA; 22:5n-6). The ratio between DHA and ObA (100) indicates the functional DHA status, which decreases continuously during pregnancy. A reduction in the maternal LCPUFA status during pregnancy is also suggested by the decrease in the relative amounts of most maternal LCPUFAs during pregnancy. For the most important LCPUFAs, DHA and arachidonic acid (AA; 20:4n-6), this decrease is more pronounced the higher the neonatal birth weight. Nonetheless, in term neonates the DHA and AA contents of umbilical plasma PL are negatively related to birth weight. This suggests that the maternal-to-fetal fatty acid transfer is limited, as a result of which the neonatal essential PUFA status may not be optimal. This latter suggestion is supported by the high amounts of LCPUFA shortage markers in neonatal blood and tissue and by the lower neonatal LCPUFA status after multiple as compared to single births. For most maternal EPUFA levels, normalization after delivery is complete within 32 weeks. However, 7 ObA DHA Ratio100 % of 10th pregnancy week 200 150 100 50 0 10 20 30 40 Weeks of pregnancy Fig. 1. Plasma phospholipid amounts (mg/l) of DHA (䉱) and its functional shortage marker Osbond acid (ObA; 䊏) during pregnancy in percent of their values at week 10 of gestation. The ratio between both values ([DHA/ObA] 100) represents the functional DHA status (䊉) which reduces steadily during pregnancy. maternal DHA concentrations are lower with each following pregnancy, suggesting a long-lasting effect of pregnancy on LCPUFA metabolism or mobilization. As a result, the amount of DHA in plasma PL of first-born neonates is higher than that of their later born siblings. Breast-feeding compromises normalization of the maternal LCPUFA status after delivery and is associated with a lower maternal DHA status than bottle-feeding. Neonatal DHA levels and head circumference are negatively related with maternal linoleic acid consumption during pregnancy. This indicates that for an optimum perinatal DHA status, the EPUFA balance of the maternal diet needs to be optimized. Maternal supplementation with EPUFA during pregnancy mitigates the reduction of the maternal EPUFA status and increases the neonatal LCPUFA status. Since both EPUFA families compete with each other, an overall increase in the maternal and, consequently, neonatal LCPUFA status requires an increased maternal consumption of both LCPUFA families (fig. 2). Maternal and neonatal LCPUFA status is thought to be associated with certain pregnancy complications and certain aspects of the 8 Supplementation with linoleic acid 25.0 7.0 25.0 Control Fish oil 22.5 20.0 17.5 15.0 Cord vein Cord arteries Cord vein n-3 fatty acids 6.0 5.0 4.0 % of fatty acids 30.0 20.0 % of fatty acids Control LA n-6 fatty acids 8.0 % of fatty acids % of fatty acids 35.0 Supplementation with fish oil n-6 fatty acids Cord vein Cord arteries Cord arteries n-3 fatty acids 7.0 6.0 5.0 4.0 Cord vein Cord arteries Fig. 2. Maternal supplementation during pregnancy with linoleic acid (LA) increases the fetal n-6 status at the expense of the n-3 status, whereas supplementation with fish oil increases the fetal n-3 status at the expense of the n-6 PUFA. Fatty acid concentrations (% of fatty acids) in cord venous and arterial tissue phospholipids of neonates born to control or supplemented mothers. pregnancy outcome, but data are not consistent. Evidence that a low maternal DHA status is associated with a high risk of post partum depression is becoming rather strong, however. The growth spurt of the developing brain takes place during late pregnancy and early extrauterine life. However, no significant associations were observed between the perinatal DHA or AA availability to infants and their cognitive performance at 3.5 and 7 years of age. On the other hand, movement quality (which is another marker of brain maturity and has been shown to be a significant predictor of later developmental problems like attention deficit hyperactivity disorder) was significantly and positively related to DHA status at birth, as was visual acuity and speed of visual information processing. None of the functional outcome measures were significantly associated with neonatal AA levels or with DHA or AA concentrations at follow-up. Concentrations in cord plasma PL of -linolenic acid (GLA; 18:3n-6) and dihomo--linolenic acid (DGLA; 20:3n-6) were negatively related to plasma triglyceride levels, fasting insulin concentrations, and calculated insulin resistance at 7 years of age. In addition, GLA concentrations at 9 birth were negatively related to body fatness and plasma leptin concentrations at age 7 years. This suggests that a low intrauterine availability of (D)GLA could be one of the factors predisposing individuals to obesity and insulin resistance later in life. If confirmed, maternal (D)GLA supplementation during pregnancy to improve the fetal GLA status may present a simple and safe way to lower the risk of newborns for later insulin resistance and obesity. 10 Dietary Essential Fatty Acids in Early Postnatal Life: Long-Term Outcomes R i c a r d o U a u y, C e c i l i a R o j a s , A d o l f o L l a n o s and Patricia Mena Introduction The formation of long-chain polyunsaturated fatty acids (LCPs) from the parent essential fatty acids (EFAs) in early life is limited, thus infants are dependent on the exogenous provision of LCPs from human milk or supplemented formula. LCPs are structural components of all tissues, they are indispensable for cell membrane synthesis and for the function of key organelles such as mitochondria, endoplasmic reticulum and synaptic vesicles, and also for membrane receptors and signal transduction systems. The brain, retina and other neural tissues are particularly rich in LCPs; if diet is deficient in LCPs during early life, neural structural development and function is affected. LCPs also serve as specific precursors for 20-carbon eicosanoid production (prostaglandins, prostacyclins, thromboxanes, and leukotrienes). Recently docosanoids derived from 22-carbon LCPs have been identified and their capacity to protect neural tissue from hypoxia-reperfusion injury characterized. Eicosanoids and docosanoids act as autocrine and paracrine mediators. They are powerful regulators of numerous cell and tissue functions (e.g. thrombocyte aggregation, inflammatory reactions and leukocyte functions, cytokine release and action, vasoconstriction and vasodilatation, blood pressure control, bronchial constriction, uterine contraction). Metabolism and Dietary Requirements The need to include linoleic acid (LA), the parent n-6 EFA in the early diet, has been recognized for over 50 years. Over the past decades the need to provide -linolenic acid (LNA; 18:3n-3) as a source of the n-3 EFAs has been recognized. A need for LCPs (18-carbon chain 11 length) derived from EFAs has only recently been established, based on studies of preterm and term human infants. Animal tissues, especially the liver, can further elongate and desaturate the parent EFAs, generating a family of compounds for the respective families. The competitive desaturation of the n-3 and n-6 series by 6-desaturase is of major significance because this is the controlling step of the pathway leading to the formation of arachidonic acid (AA; 20:4n-6) and docosahexaenoic acid (DHA; 22:6n-3) from LA (18:2n-6) and LNA (18:3n-3) respectively, further details can be found in recent reviews. The n-6 polyunsaturated fatty acids (PUFAs) are abundant in commonly used vegetable oils (corn, sunflower, safflower), whereas n-3 PUFAs are relatively low except in soy, canola and linseed oils. Presently, most infant formulas are designed to provide a similar fatty acid (FA) composition to that found in mature human milk from omnivorous women. The EFA content of human milk, especially the LCP content, will change according to the maternal diet. The evidence indicates that in early life 18n-3 precursors are not sufficiently converted to DHA to allow biochemical and functional normalcy. Thus, not only LA and LNA but DHA and AA are now considered necessary nutrients for normal eye and brain development in the human. Up to a few years ago, the metabolism of LCPs beyond the 20-carbon step leading to the formation of DHA was considered to be an apparently simple reaction catalyzed by a 4-desaturase forming DHA from 22: 5n-3. Sprecher’s group after conducting detailed analytical work using isotopic tracers and gas chromatography-mass spectrometry found evidence that in fact what was apparently a 4-desaturase was really a 3-step pathway. Effect of LCP Deficiency The evidence to date indicates that human infants who receive an inadequate supply of LCPs have altered retinal rod function, delayed maturation of the visual cortex, and poorer auditory discrimination as compared to the infants fed human milk or LCP-supplemented formula. Some studies have also revealed altered mental development and cognitive function. Over recent years, the role of LCPs in modulating signal transduction and regulating gene expression have been described, emphasizing the complexity of FA effects on biological systems. Dietary FAs, especially LCPs, have potentially significant effects in the modulation of developmental processes affecting shortand long-term health outcomes related to growth, body composition, mental development, immune and allergic responses, and prevalence of nutrition-related chronic disease. Figure 1 illustrates the shortand long-term effects of nutrients, in this case LCPs, on health 12 Early diet Short-term Neurosensory development Growth muscle/bone Body composition Other epigenetic factors Metabolic programming CHO, lipids, proteins Hormone, receptor, genes Long-term Cognitive capacity & education Immunity Work capacity Diabetes Obesity Cardiovascular disease, stroke Hypertension Cancer Aging Fig. 1. Short- and long-term effects of nutrients. outcomes related to neurodevelopment, growth and body composition and nutrition-related chronic diseases. Mechanisms for Biological Effects Changes in Lipid Membrane Properties The FA composition of structural membrane lipids can affect membrane function by modifying overall membrane fluidity, by affecting membrane thickness, by changing lipid phase properties, by specific changes in the membrane microenvironment, or by interaction of FAs with membrane proteins. Most dietary n-3 FA-induced membrane changes are not reflected by an overall change in membrane fluidity but rather result in selective changes in membrane micro-domains affecting specific functions. Gene Expression Over the past decade the role of LCPs in regulating gene expression has been extensively studied given the potentially of dietary FAs to affect several developmental and metabolic processes with relevant short- and long-term health outcomes. The mechanism for the regulation of gene expression by FAs involves members of the superfamily of nuclear receptors that function as transcription factors. Two types of transcription factors account for the main transcriptional effects of PUFAs, namely the peroxisome proliferator-activated receptor (PPAR) and the hepatic nuclear factor-4a. The superfamily of nuclear receptors also includes steroid hormone receptors, the glucocorticoid receptor, vitamin D receptor, the thyroxine receptor, the retinoic acid receptor, 13 and the retinoid receptor. The effect of LCPs on gene expression may have profound and long-lasting implications for human health. LCPs affect the expression of genes that regulate cell differentiation and growth; therefore, early diet may influence structural development of organs, as well as neurologic and sensory functions. Specifically, a possible role of DHA on retinal and neuronal differentiation has been proposed. Effects Mediated by Eicosanoid and Docosanoid Production The effect of LCPs in the early diet can modulate eicosanoid (derived from 20-carbon FAs, AA and eicosapentaenoic acid (EPA)) and possibly docosanoid (derived from 22-carbon FAs, DHA) production affecting multiple physiologic functions that may explain both acute and long-term health effects. Membrane phospholipases liberate, depending on the nature of the dietary supply, AA and/or EPA from phospholipids. Thus, through the action of cycloxygenase or lipoxygenase, LCPs form eicosanoid products (prostaglandins, prostacyclins, thromboxanes and leukotrienes) that play key roles in modulating inflammation, cytokine release, immune response, platelet aggregation, vascular reactivity, thrombosis, and allergic phenomenon. The balance between AA (n-6) and EPA (n-3) in biological membranes is regulated based on dietary supply and tissue-specific factors. The n-6/n-3 ratio in phospholipids modulates the balance between prostanoids of the 2 and 3 series derived from AA and EPA, respectively. The n-3/n-6 balance affects health outcomes modifying the severity, progression and recovery from diseases that are mediated by prostanoids. Growth and Body Composition The classic LA deficit is accompanied by growth failure. In fact, recent studies suggest that if the LA:LNA ratio is very low, LA may be insufficient to support normal growth. Observational studies from malnourished populations are not conclusive of EFA deficiency as evidenced by plasma and red blood cell FA composition. Studies in Sudan compared EFA blood levels in normal children under 4 years of age to those suffering from marasmic protein energy malnutrition or Kwashiorkor. The n-6 EFAs, including LA and AA, were significantly lower in plasma phospholipids and cholesterol esters. Relative to controls, there was a corresponding increase in the non-EFAs such as oleic (18:1n-9) in the malnourished. No differences were found for the n-3 series EFAs. Studies from rural China, where soy oil is consumed and diets are low in total protein and energy, human milk has a low DHA 14 content (0.2%) with a AA to DHA ratio of 2.4 to 3.1 revealing a relationship between growth and the EFA content of human milk. At 3 months of age weight gain was significantly related to the AA content of human milk (r 0.46) while linear growth was related to DHA content (r 0.80). This issue has recently been addressed by conducting a meta-analysis of all available studies in both term and preterm infants. Randomized trials involving 1,680 term infants and 1,647 preterm infants met criteria for inclusion in the meta-analysis. Term infants allocated to any type of LCP supplementation were not statistically different at 4 or 12 months of age. A subgroup analysis of infants allocated to an n-3 LCP alone group (no AA) also showed no effect of supplementation on any growth parameter at either 4 or 12 months of age. Preterm trials provided raw data for 1,624 preterm infants; the growth of preterm infants was explored through the generation of growth curves of infants in control, n-3 LCP AA treatment and n-3 LCP alone treatment. No difference in the pattern of growth for weight, length or head circumference was noted. A multiple regression analysis to assess the determinants of growth in these infants at 40, 57 and 92 weeks post-menstrual age found a significant effect of size at birth, gender and the actual age of assessment. The overall influence of LCPUFA supplementation accounted for less than 3% of the variance in growth. Allergic and Inflammatory Responses Asthma is considered a good example of allergic disease. The main features of obstructive airway disease are related to alterations in the airway and air trapping in the lung. Airway obstruction due to bronchoconstriction and increased mucous production leads to air trapping and loss of gas exchange. Virtually all these features correspond to the known actions of AA metabolites, prostanoids and leukotrienes C4, D4, E4. Moreover, leukotrienes have been postulated to amplify oxygen radical-mediated lung injury by inducing chemotactic mediators, which attract polymorphonuclear cells and increase vascular permeability. These findings indicate an important role for inflammatory mediators in the pathophysiology of this disease. Neurologic and Sensory Development The effect of LCPs on brain development was the topic of a recent meeting published as a supplement to the Journal of Pediatrics (October 2003), thus we will only discuss selected aspects. Preterm Infants are considered particularly vulnerable to EFA deficiency given 15 the virtual absence of adipose tissue at birth, the possible immaturity of the FA elongation/desaturation pathways and the inadequate LNA and DHA intake provided by formula. Over the past decades, several studies have examined effect of LCPs on plasma and tissue lipid composition, retinal electrophysiological function, on the maturation of the visual cortex as measured by pattern reversal visual evoked potentials and behaviorally by the forced-choice preferential looking visual acuity response. The largest collaborative multicenter study of a large group of preterm infants included 450 preterm infants fed LCPUFA formula supplemented with different AA and DHA sources: fish oil and egg phospholipids or fungal oil. Significant differences were found in sweep visual evoked potentials at 6 months favoring the LCP-supplemented formula group as compared to the control formula group. Term Infants The question of whether healthy full-term infants need LCPUFAs in their formula has received great attention over the past decade. The finding of lower plasma DHA concentrations in infants fed formula compared to that of breast-fed infants suggests that formulas provide insufficient LNA or that chain elongation-desaturation enzymes are not sufficiently active during early life to support optimal tissue accretion of DHA. Full-term infants also appear to be dependent on dietary DHA for optimal functional maturation of the retina and visual cortex. Several studies have demonstrated significant effects of dietary LCPUFAs on visual maturation in the first 4 months of life but in most cases the delayed response becomes normal at 6 months or at most by 1 year of age. The duration and reversibility of diet-induced effects are important considerations in evaluating diet-induced changes in developmental outcomes. There may be transient effects that reflect the acceleration or the slowing of a maturational process with a fully normal final outcome. This is of special relevance during the first few months of life when visual maturation is progressing rapidly. Brain Injury (Ischemia and Hemorrhage) Hypoxic and hemorrhagic insults to the neonatal brain are not infrequent, especially in preterm infants. Most ischemic injury occurs prior to or at birth; intraventricular hemorrhage is detected mostly in the first hours of life. Thus, it is difficult to propose a nutritional prevention of these conditions, unless the intervention is given to the mother. Whether maternal dietary LCP supply could play a role in defining the occurrence and severity of brain hemorrhagic injury is not known. Crawford has speculated, based on limited data from animal 16 HDL OX-LDL Macrophage Arterial wall Inflammation atherogenesis PPAR / LDL lipase FA VLDL VLDL FA synthesis and oxidation Lipoprotein synthesis PPAR () Adipocyte differentiation Lipogenesis and storage PPAR FA oxidation PPAR / () Fig. 2. Molecular effects (PPARs) of LCP supply on energy and lipid metabolism. observations, that poor maternal dietary LCP supply could be responsible for the high prevalence of hemorrhagic injury observed in small preterm neonates. In addition the possibility of dietary modulation of cytokine release should be considered, since cytokines mediate much of the vascular and tissue damage observed during and after reperfusion. Evidence of a specific role of inflammation and cytokine release in periventricular leukomalacia has been proposed. Selected docosanoids derived from DHA, such as 10,17S-docosatriene, exert a potent anti-inflammatory role. These DHA derivatives inhibit leukocyte infiltration, inflammatory gene expression and cytokine production in hypoxia-reperfussion injury, decreasing by half the damage induced by arterial occlusion if 10,17S-docosatriene is infused during the recovery from hypoxia. The effect of early lipid supply on brain injury deserves further research. Nutrition-Related Chronic Disease (Obesity, Diabetes, Hypertension and Dyslipidemias) LCPs affect the expression of genes subject to transcriptional activation by PPARs, and thus may contribute to the regulation of fuel oxidation, lipid and glucose metabolism, fuel partitioning, adipocyte growth and maturation. The long-term effects of LCP supply on nutrition-related chronic diseases, in addition to their effects on gene expression with direct bearings on glucose and lipid metabolism, and on adipose tissue growth and maturation are depicted in figure 2. The increased risk for nutrition-related chronic diseases in infants born with intrauterine growth restriction is presently being recognized, and 17 this is likely due to the increased risk of metabolic syndrome (insulin resistance, hypertension, visceral obesity and cardiovascular disease) in later life. Conclusions The data from animal studies and the preliminary data from human studies presented in this review suggest that the supply of essential lipids in early life may condition not only the short-term effects related to growth, neurosensory maturation and mental development, but could also contribute in determining the susceptibility to allergic disease and immune responses, condition the severity of inflammatory responses, and possibly modify the risk for diet-related chronic disease linked to the metabolic syndrome (hypertension, insulin resistance, obesity, and cardiovascular disease). The long-term clinical significance of the experimental findings discussed is hard to determine from the existing data, additional information from longterm follow-up of controlled feeding studies is needed before this issue can be resolved. 18 Nutrient-Induced Maternal Hyperinsulinemia and Metabolic Programming in the Progeny Mulchand S. Patel, Malathi Srinivasan and Suzanne G. Laychock Altered early life nutritional experiences, both during fetal development and in the immediate postnatal period, are now recognized to play an important role in the onset of adult-onset degenerative diseases via the process of metabolic programming. Metabolic programming is the phenomenon whereby an altered nutritional experience (overlapping with the critical window of organogenesis during early periods in life) by permanently modifying metabolic processes in the organism predisposes it for the onset of diseases later in life. Data from several epidemiological studies and results from various animal models provide convincing evidence for this concept. In animal studies, the consequences of maternal protein restriction, total caloric restriction and diabetes during pregnancy have been extensively investigated in the progeny. Fetal development under such conditions programs the progeny for adult-onset diseases via metabolic adaptations in islets and hypothalamus with subsequent modulations at the level of peripheral tissues, favoring the progression of metabolic diseases. Studies from our laboratory have demonstrated that, in addition to the effect of over- or undernutrition during early periods in life, the immediate postnatal period is also vulnerable to changes in the quality of nutrition via caloric redistribution without a change in the total caloric availability. In our high-carbohydrate (HC) rat model, neonates are artificially reared on a HC milk formula for a period of 3 weeks from day 4 to 24 and then weaned onto laboratory chow. The HC milk formula is isocaloric and isonitrogenous to rat milk, with the only difference being a switch in the major source of calories to carbohydrate in the HC milk formula compared to fat in rat milk. This caloric redistribution in the HC formula in the neonatal life of rats results in the immediate onset of hyperinsulinemia, its persistence into adulthood 19 Hyperinsulinemia Biochemical, molecular and cellular adaptations in islets Lab chow Birth High CHO Prenatal a 0 Suckling 22 4 12 Increase in weight gain Obesity Post-weaning 24 55 Postnatal age (days) 75 100 Hyperinsulinemia Biochemical and molecular adaptations in islets Birth Increase in weight gain Lab chow Obesity Maternal HI Prenatal 0 b Suckling 22 12 Post-weaning 24 28 55 75 100 Postnatal age (days) Fig. 1. a Summary of the metabolic responses (inclusive of both immediate and long-term adaptations) in rats artificially reared on a high-carbohydrate (HC) milk formula from postnatal day 4 to 24. High CHO High-carbohydrate milk formula. b Summary of the metabolic responses observed in the immediate post-weaning as well as in adulthood of the HC progeny, acquired and expressed due to fetal development in the HC female (female rats raised on the HC formula up to postnatal day 24). Maternal HI Maternal hyperinsulinemia. and the onset of obesity later in life (fig. 1a). An interesting observation from studies on this model is that metabolic processes programmed in females during the period of dietary modulation are not only expressed in the adulthood of the same generation but are transmitted to the next generation without the progeny having to undergo an altered dietary experience in their immediate postnatal period. We thus have a unique model for maternal programming of the progeny, wherein the HC dietary experience in the female in its neonatal life provides an altered intrauterine environment for fetal development (characterized by chronic hyperinsulinemia and obesity without changes in plasma glucose levels) to set up a vicious cycle of transmission of the HC phenotype to the progeny. Although the HC progeny do not develop hyperinsulinemia during the suckling period, immediately upon weaning to laboratory chow there is an increase in their plasma insulin levels and subsequently chronic hyperinsulinemia ensues (fig. 1b). There is no difference in the body weight gain in the 20 HC progeny up to postnatal day 55, but thereafter there is an increase in their body weights and they are distinctly obese by postnatal day 100. In several aspects the metabolic processes programmed and the mechanisms supporting this phenomenon are similar between the HC mothers and their progeny. The results from our studies demonstrate that a change in the quality of nutrition via caloric redistribution in neonatal life can prime the organism not only for the onset of metabolic diseases in its own adulthood, but via the female can set up a cycle of transmission of this potential to the progeny. Based on these observations one wonders if altered dietary practices in infants may, in part, contribute to the epidemic of metabolic diseases encountered in the Western world in recent times. 21 Maternal Malnutrition and the Risk of Infection in Later Life Sophie E. Moore, Andrew C. Collinson, P a Ta m b a N ’ G o m a n d A n d r e w M . P r e n t i c e In rural Gambia, individuals born during the nutritionally debilitating annual ‘hungry’ (wet) season have an odds ratio of premature adult mortality up to 10 times greater than those born during the ‘harvest’ (dry) season (fig 1) [1]. Since the majority of these premature adult deaths are from infections or infection-related diseases, it has been hypothesized that an insult occurring in early life and linked to the season of birth is disrupting immune development and resulting in impaired immune function, increased susceptibility to infections, and premature mortality later in life. This hypothesis is supported by several pieces of evidence from the literature. The principle components of the human immune system develop in fetal life [2], and it is plausible that fetal nutrient deprivation could lead to a more permanent immunological insult than a similar degree of undernutrition experienced in postnatal life. Furthermore, maternal malnutrition has been observed to have greater effects on thymic and lymphoid tissue development than on other organs [3, 4], and such deficits in organ growth and development occurring in utero appear more serious and long-lasting than those caused by later malnutrition [5]. Some evidence exists to suggest that low birth weight babies may have sustained impairment of immune competence as infants and children [6–8], and increased susceptibility, following intrauterine growth retardation, to infections in childhood is also well known [9]. However, despite this evidence, mechanisms to explain any of these observations are not described. We are therefore attempting to define the biological mechanisms underlying the early-life programming of immune function through a series of ongoing studies, and some preliminary findings from these studies are detailed below. 22 100 OR 10.3 (P 0.00002) Survivors (%) 90 OR 3.7 (P 0.000013) 80 70 Harvest 60 Hungry 50 40 0 10 20 30 40 50 Age (years) Fig. 1. Kaplan-Meier survival plots by season of birth. n 3,162 (2,059 alive and 1,103 dead). OR Odds ratio. Adapted from Ferguson et al. [7]. In The Gambia, a prospective birth-cohort study of neonatal immune function and development has demonstrated seasonal effects on thymic size (measured by ultrasonography), with the smallest thymuses found in infants both born and measured in the hungry season, regardless of infant weight (fig. 2) [10]. This difference in thymic size is greatest at 8 weeks of age, an age at which infants in this community are exclusively breast-fed, have good weight, and have minimal incidence of active infections. This finding could suggest that breast milk has a specific trophic effect on the thymus. Indeed, further work in this cohort has demonstrated that levels of the cytokine IL-7 were significantly lower in samples of breast milk collected in the hungry season compared to samples from the harvest season (79 vs. 100 pg/ml, p 0.02) [11]. This finding suggests that improved maternal nutrition during the harvest season could influence certain factors in breast milk, with the consequent improvement in thymic size and function. We have also investigated the association between size at birth and response to vaccination (purified Vi surface polysaccharide extracted from Salmonella typhi and rabies vaccines) in a cohort of 257 adults (mean age 29.4 years; 146 males) born in an urban slum in Lahore, Pakistan during 1964–1978 [12]. Vaccine responses were not consistently associated with contemporary variables (month of study, gender, current age, indicators of wealth). The response to typhoid vaccination was positively related to birth weight (anti-Vi IgG 23 Wet minus dry (% difference) 15 10 5 0 5 10 15 1 a 8 24 52 Postnatal age (weeks) Wet minus dry (% difference) 5 0 5 10 15 b 1 8 24 52 Postnatal age (weeks) Fig. 2. Percentage (standard error) difference in mean thymic index between hungry and harvest season births (a), and hungry and harvest season measurements (b), adjusted for gender, gestation and current weight. Adapted from Collinson et al. [Acta Paediatr 2003;92:1014–1020]. p 0.031; anti-Vi IgM p 0.034). The response to the rabies vaccine, however, was not associated with birth weight. The contrasting effects on typhoid and rabies responses observed in this study seem to suggest that the antibody generation to polysaccharide antigens, which has greater B-cell involvement, has been compromised by fetal growth retardation. Ongoing research in this and other cohorts aims to elucidate the mechanisms involved. All the key studies within this area of research have so far focused on a limited number of cohorts from specific countries where infectious diseases still prevail as the leading cause of mortality. However, if true, then this hypothesis clearly has relevance for many more sectors of 24 Table 1. Immune function in relation to birth weight, season of birth and maternal supplementation status in 6- to 10-year-old Gambian children Measure Birth weight Season of birth Supplementation status1 CMI2 NS NS Pneumococcal vaccination Rabies vaccination NS NS Increased response in intervention children (p 0.006)2 NS NS NS Intestinal permeability Salivary sIgA2 levels NS NS NS Increased response in hungry season births (p 0.0018) Increased response in control children (1st dose p 0.024, 2nd dose p 0.005)2 NS NS CMI Cell-mediated immune response; SIgA secretory immunoglobulin A. Table adapted from Moore et al. [Am J Clin Nutr 2001;74:840–847]. 1 Maternal dietary supplement during pregnancy (intervention) or during lactation (control). 2 Significantly different after adjustment for age, sex, month of study, and current weight-for-age z-score. society, and demonstrates the necessity for continued research into the key factors that impact on the development of the human immune system during fetal and early postnatal life. References 1 2 3 4 Moore SE, Cole TJ, Poskitt EME, et al: Season of birth predicts mortality in rural Gambia. Nature 1997;388:434. Hayward AR: Development of immune responsiveness; in Falkner F, Tanner JM (eds): Human Growth. 1. Principles and Prenatal Growth. New York, Plenum Press, 1978, pp 593–607. Winick M, Noble A: Cellular response in rats during malnutrition at various ages. J Nutr 1966;89:300–306. Owens JA, Owens PC: Experimental fetal growth retardation: Metabolic and endocrine aspects; in Gluckman PD, Johnston BM, Nathanielsz PW (eds): Advances in Fetal Physiology. Ithaca, Perinatology Press, 1989, pp 263–286. 25 5 6 7 8 9 10 11 12 26 Beach RS, Gershwin ME, Hurley LS: Gestational zinc deprivation in mice: Persistence of immunodeficiency for three generations. Science 1982;218: 469–471. Chandra RK: Fetal malnutrition and postnatal immunocompetence. Am J Dis Child 1975;129:450–454. Ferguson AC, Lawlor GJ, Neuman GG, et al: Decreased rosette forming lymphocytes in malnutrition and intra-uterine growth retardation. J Pediatr 1974; 85:717–723. Victora CG, Smith PG, Vaughan JP: Influence of birth weight on mortality from infectious diseases: A case control study. Pediatrics 1988;81:807–811. Ashworth A: Effects of intrauterine growth retardation on mortality and morbidity in infants and young children. Eur J Clin Nutr 1998;52:S34–S42. Collinson AC, Moore SE, Cole TJ, Prentice AM: Birth season and environmental influences on patterns of thymic growth in rural Gambian infants. Acta Paediatr 2003;92:1014–1020. N’Gom PT, Collinson AC, Pido-Lopez J, et al: Improved thymic function in exclusively breast-fed babies is associated with higher breast milk IL-7. Am J Clin Nutr 2004; in press. Moore SE, Jalil F, Ashraf R, et al: Birth weight predicts response to vaccination in adults born in an urban slum in Lahore, Pakistan. Am J Clin Nutr 2004; in press. Size and Body Composition at Birth and Risk of Type-2 Diabetes: A Critical Evaluation of ‘Fetal Origins’ Hypothesis for Developing Countries C . S . Ya j n i k There is a rapidly increasing epidemic of type-2 diabetes in India and other developing countries. In addition to genetic susceptibility, intrauterine nutrition may have an etiological role in this epidemic. The ‘thrifty phenotype’ hypothesis was based on the demonstration of an inverse relation between birth weight and type-2 diabetes in elderly Europid populations. People in the Indian subcontinent have faced undernutrition for many generations, and Indian babies are among the smallest in the world. However, the epidemic is of recent origin, and more common in urban than in rural people despite higher birth weight. The relationship between birth weight and type-2 diabetes may be U-shaped and dependent on the body composition of the fetus. Adiposity of the neonate may be the most relevant risk factor for risk of type-2 diabetes. For a given size, Indian neonates, children and adults have a higher body fat percent (adiposity) and higher visceral fat compared to other populations. In Mysore, South India, there was no relation between birth weight and later diabetes but a higher ponderal index was predictive. This is contrary to the findings in the Europid populations. Neonatal size and body composition are influenced by parental size, maternal food intake, physical activity and concentrations of circulating nutrients and metabolites. Maternal insulin resistance and hyperglycemia have a substantial influence on the adiposity of the fetus. As yet there are no prospective human studies to demonstrate an association between maternal nutrition in pregnancy and offspring risk of type-2 diabetes. The Pune Maternal Nutrition Study will provide some of this information for the first time. Preliminary findings in 6-year-old children suggest that the relationship may be different than expected from retrospective studies in Europid populations. 27 Cardiovascular Diseases in Survivors of the Dutch Famine O t t o P. B l e k e r, Te s s a J . R o s e b o o m , A n i t a C . J . Ravelli, Gert A. van Montfrans, Clive Osmond, a n d D a v i d J . P. B a r k e r The Dutch famine was a 5- to 6-month period of extreme shortage of food that affected all people in the west of the Netherlands, a previously well-nourished population. The official daily rations for an adult in Amsterdam – which had gradually decreased from about 1,800 cal in December 1943 to 1,400 cal in October 1944 – fell abruptly to below 1,000 cal in late November 1944. During the peak of the famine from December 1944 to April 1945, the rations varied between 400 and 800 cal. After the liberation in early May, the rations improved rapidly to over 2,000 calories in June 1945. To assess the effect that prenatal exposure to maternal malnutrition has on coronary heart disease (CHD) in people born around the time of the Dutch famine, we studied the prevalence of CHD (defined as the presence of angina pectoris according to the Rose questionnaire, Q waves on the ECG, or a history of coronary revascularization) among singletons born alive between November 1943 and February 1947 for whom we had detailed birth records. We compared the prevalence of CHD in those exposed to famine in late gestation (n 120), in mid gestation (n 108), or in early gestation (n 68) with those born in the year before the famine or those conceived in the year after the famine (non-exposed subjects, n 440). The CHD prevalence was higher in those exposed in early gestation than in non-exposed people (8.8 versus 3.2%, odds ratio adjusted for sex 3.0, 95% confidence interval 1.1–8.1). The CHD prevalence was not increased in those exposed in mid gestation (0.9%) or late gestation (2.5%). The CHD effect of exposure to famine in early gestation was independent of birth weight (adjusted odds ratio 3.2, 95% confidence interval 1.2–8.8). Previously, we have found that people exposed to famine in late gestation had a reduced glucose tolerance at age 50, whereas exposure to famine in early gestation was linked to higher levels of obesity in 28 women and more atherogenic lipid profiles in both men and women. Blood pressure was not affected by exposure to famine although it was strongly negatively associated with size at birth. These distinct relations between prenatal exposure to famine and fetal growth on the one hand and CHD and its risk factors on the other, suggest that an adverse fetal environment contributes to several aspects of cardiovascular risk in adult life, but that the effects very much depend on its timing during gestation. We would like to conclude that maternal conditions before and during pregnancy are of main importance with respect to the adult health of their offspring. If poor maternal conditions proceed throughout pregnancy, lower birth weights are observed and will be found to be related to impaired adult health. If poor maternal conditions only exist around conception and in early pregnancy, especially CHD is found at adult age. If poor conditions are especially present in late pregnancy, effects on blood pressure and glucose tolerance are found. However, if lower birth weights occur in healthy mothers with a normal nutritional status, due to limitations set by the placenta in special cases like twins, adult health is not impaired at all. Obviously, in these twin newborns the early organ development and the tuning of endocrine and other systems essential for adult health are normal and the placental limitations met in the second half of pregnancy do not affect these essential developmental systems. Therefore, the observed difference with respect to adult disease found in the children exposed late to the Dutch famine and not found in twin children is of very special interest and does not oppose the fetal origins hypothesis. Very likely maternal malnutrition at conception and during early gestation contributes to the occurrence of CHD in the offspring. Useful interventions to prevent disease in adulthood should not only aim at the nutritional condition of pregnant women, but also at the nutritional condition before pregnancy and at the very start of pregnancy, which are much more meaningful for the nutritional status in childhood and in young adults. 29 The Relationship between Maternal Obesity and Adverse Pregnancy Outcomes D . K i m Wa l l e r a n d Tr a c y E . D a w s o n The increase in obesity over the last three decades is of great concern because obesity is associated with an elevated risk of many types of diseases. This chapter reviews epidemiologic studies on the effect of maternal obesity on reproductive function, pregnancy complications, and pregnancy outcomes. Obese women are more likely to have irregular menstrual cycles and to have difficulty becoming pregnant. This may be explained by the large increase in the risk of developing polycystic ovarian syndrome among them. Obesity is associated with an increased risk of several pregnancy complications. Obese women are more likely to develop gestational diabetes compared with women who are not obese. They also have an increased risk of having a macrosomic infant (birth weight 4,000 g). Macrosomia is of concern because there is a risk of shoulder dystocia, dysfunctional labor and cesarean birth among these infants. Obese women also have an increased risk of having hypertension and preeclampsia during their pregnancies, and increased rates of blood loss and postoperative infection following cesarean deliveries. Finally, maternal obesity impacts pregnancy outcome. Studies are consistent in reporting that obese women have a 2- to 3-fold increase in the risk of late fetal death. This may be due to the increased risk of diabetes, hypertension and preeclampsia among obese women. In contrast, obese women and overweight women are about half as likely to have a small-for-gestational age infant, compared with thin or underweight women. This association has been found to be independent of weight gain during pregnancy, suggesting that caloric intake at the time of conception and during the first trimester may play an important role in the determining the overall growth of the fetus. Studies of the association between maternal obesity and preterm birth are inconsistent. More recent studies suggest that obese women 30 have no increase in the risk of preterm birth after adjusting for confounding variables such as maternal age, race and income. Seven case-control studies and two cohort studies have found that obese women have a 2-fold increase in the risk of having an infant with a neural tube defect. In addition, evidence is accumulating to support an association between maternal obesity and other birth defects; however, further research is needed. Obese women are more likely to have high serum insulin levels and altered response to glucose tolerance tests. Alterations in glucose tolerance have been shown to be teratogenic in women who have insulin-dependent diabetes mellitus. Therefore, it has been proposed that the mechanism that causes the excess of birth defects among infants of obese women is similar to the mechanism that causes the well-established excess of major birth defects among infants of diabetic mothers. Studies conducted in Western countries have observed that obesity is associated with a number of adverse reproductive outcomes. As obesity has wide-ranging metabolic effects, it seems likely – although not proven – that obesity will also prove to be associated with adverse reproductive outcomes among Asian populations. Currently, China has much lower rates of obesity than the United States and other Western countries. Thus, China should encourage programs to prevent children and adolescents from becoming obese. Such programs may be particularly effective in China and other Asian countries because the problem of obesity is not yet fully entrenched in these countries. 31 Special Problems of Nutrition in the Pregnancy of Teenagers Paul B. Pencharz It is well established that the average birth weight of babies resulting from teenage pregnancy is lower than in those from adult women; and the proportion which have a low birth weight (2,500 g) is greater. These adverse pregnancy outcomes in adolescents may be due in part to the fact that the diet must supply enough to permit maternal growth as well as fetal growth. Clearly this matter is more of a concern in adolescents who are still capable of growth (usually those 16 years). All of this at a time in the life cycle where maternal diet habits are less than optimal. Adolescents may restrict their total food intake in order to limit weight gain and thereby make their pregnant state less obvious. In addition to concerns about macronutrients (protein and energy), attention needs to be focussed on micronutrients and those of major importance are folate and iron. Folate deficiency has been associated with fetal wastage and with neural tube defects. Iron deficiency can result in anemia and weakness. It is now well accepted that suboptimal fetal growth is associated with higher fetal mortality and neonatal morbidity and mortality. Further that suitable nutrition-based interventions can substantially improve the health of mothers and their infants. Most of the studies to date have been conducted in adult mothers. However, there are clear data that adolescent pregnancies especially in mothers 16 years are at increased risk. Recognition of these issues has resulted in programs specifically designed to meet the nutritional needs of the pregnant teenager. These programs have managed to get the adolescent mothers to take more energy and protein as well as taking micronutrient supplements and have shown a clear improvement in infant birth weight and a reduction in low birth weight prevalence. Many questions remain such as what is an optimal nutritional intervention for a teenage mother. Secondly how to motivate the adolescent mother to take the additional food to ‘both feed herself and her unborn baby’. 32 Dietary Intervention during Pregnancy and Allergic Disease in the Offspring S. Salvatore, K. Keymolen, R.K. Chandra, a n d Y. Va n d e n p l a s Because of its high incidence, allergic disease has become a worldwide problem of health care. Because of the impact of allergic disease on health care cost, interest is more focused on prevention than on therapy, although the etiology of allergic disease and atopy is not yet fully understood. The avoidance of contact with allergens postpones the development of allergic disease, but does not result in the development of tolerance, which is the ultimate goal. Many studies have focused on how to intervene in the infant to ensure the development of tolerance and to decrease the development of allergy. It has been clearly demonstrated that some postnatal dietary, environmental and drug interventions beyond doubt result in a decrease in some aspects of allergic disease in at-risk groups of infants and children. However, it is also obvious that the hoped for impact of postnatal intervention studies could have been larger. The bottom line of consensus is limited. Agreement exists on the fact that the etiology of allergic disease is multifactorial, with many variables contributing to the final (absence of) clinical expression of atopic disease. Three breeding grounds are needed to develop allergic disease: the appropriate genetic background; contact with the allergen(s), and environmental factors. Timing and dosing of the contact with the allergen(s) are of major importance. Contact with allergens occurs not only during postnatal life, but also perinatally and prenatally. To date, little attention has been given to sensitization during prenatal life, although it is obvious that the fetus is in contact with multiple allergens, such as respiratory and dietary allergens. Fetal contact with various agents such as metabolites of medications, alcohol, tobacco smoke, and viral infections have made it obvious that fetal development is (at least partially) determined by maternal factors. 33 Dietary antigens are possibly another interfering factor. A critical review of published evidence regarding the impact of dietary antigens ingested by the mother during pregnancy on later development of allergic disease in the offspring can only result in the conclusion that more research is urgently needed. It can be speculated that contact with multiple dietary allergens should in general be of benefit to the fetus since tolerance is likely to develop. However, it may well be that in a subset of fetuses with a (yet unknown) specific genetic background, the development of allergic disease is enhanced via contact with dietary antigens during pregnancy. As a consequence, avoidance of dietary antigens during pregnancy may become recommended in the future in pregnant woman or fetuses with a specific genetic background. If parental history is insufficient to determine the fetal risk, then determination of the genetic background may in practice not be feasible. In the latter, preventive measurements would be advisable for all fetuses. Today’s knowledge suggests that pregnant women should have a normal diversified diet, avoiding toxic agents such as tobacco and alcohol. Since peanuts are strong allergens and they are rather consumed as a dietary habit rather than being an important nutrient, their consumption during pregnancy should be avoided, although it has not been demonstrated that regular ingestion of peanuts during pregnancy results in the development of tolerance in the offspring. The role of polyunsaturated fatty acids ingested by pregnant women on the development of atopy in the infants needs to be further evaluated. It is likely that both an immunological and a genetic profile adequately predict the risk for atopy, and that contact with allergens may result in tolerance or allergic sensitization depending on the genetic profile in combination with the immunological balance. The interaction between genetic predisposition and environmental factors, such as the first gastrointestinal colonization, exists during a restricted window of time. It can be speculated that the impact of dietary intervention during pregnancy will only have a borderline effect if not followed by adequate perinatal and postnatal intervention. 34 List of Speakers Prof. Otto Pieter Bleker Department of Obstetrics and Gynecology, Academic Medical Center, University of Amsterdam Room H4-210, Postbox 22700 NL–1100 DE Amsterdam The Netherlands Tel. 31 20 5663658 Fax 31 20 6971651 E-Mail [email protected] Dr. Nancy Butte Department of Pediatrics Children’s Nutrition Research Center, Baylor College of Medicine, 1100 Bates Street Houston, TX 77030 USA Tel. 1 713 798 7179 Fax 1 713 798 7187 E-Mail [email protected] Prof. Gian Carlo Di Renzo Centre of Perinatal and Reproductive Medicine Department of Gynecologic Obstetric and Pediatric Sciences University Hospital Monteluce Via Brunamonti 51 I–06121 Perugia Italy Tel. 39 7 55720563/74 Fax 39 7 55729271 E-Mail [email protected] Prof. Gerard Hornstra Healthy Lipids Research and Consultancy Maastricht University Brikkenoven 14 NL–6247 BG Gronsveld The Netherlands Tel. 31 43 3560537 Fax 31 43 3560535 E-Mail g.hornstra@ nutrim.unimaas.nl Prof. Michael S. Kramer Department of Pediatrics Montreal Children’s Hospital 2300 Tupper Street Room F-265 Montreal, Que. H3H 1P3 Canada Tel. 1 514 412 4400/22687 Fax 1 514 412 4253 E-Mail michael.kramer@ mcgill.ca Dr. Sophie Moore MRC International Nutrition Unit Public Health Nutrition Unit London School of Hygiene and Tropical Medicine, 49–51 Bedford Square, London WC1B 3DP UK Tel. 44 207 299 4667 Fax 44 207 299 4666 E-Mail [email protected] 35 Prof. Mulchand Patel Department of Biochemistry School of Medicine and Biomedical Sciences, State University of New York at Buffalo, 140 Farber Hall 3435 Main Street Buffalo NY 14214 USA Tel. 1 716 829 3074 Fax 1 716 829 2725 E-Mail [email protected] Dr. Paul Pencharz Hospital for Sick Children Division of Gastroenterology and Nutrition, 555 University Avenue Toronto, Ont. M5G 1X8 Canada Tel. 1 416 813 7733 Fax 1 416 813 4972 E-Mail paul.pencharz@ sickkids.ca Dr. Thomas H. Rosenquist University of Nebraska Medical Center, 987878 Medical Center, Omaha, NE 68198-7878 USA Tel. 1 402 559 4032 Fax 1 402 559 3990 E-Mail [email protected] Prof. Ricardo Uauy INTA University of Chile, Macul 5540, Casilla 138-11, Santiago 11 Chile Tel. 562 2 2214105 Fax 562 2 2214030 E-Mail [email protected] 36 Prof. Yvan Vandenplas AZ-VUB, Laarbeeklaan 101 BE–1090 Brussels Belgium Tel. 32 2 477 5780/1 Fax 32 2 4775783 E-Mail yvan.vandenplas@ az.vub.ac.be Prof. Kim Waller School of Public Health University of Texas, 1200 Herman Pressler Drive, Suite W-210 Houston, TX 77030 USA Tel. 1 713 500 9155 Fax 1 713 500 9149 E-Mail [email protected] Dr. Chittaranjan Yajnik King Edward Memorial Hospital Diabetes Unit, Sardar Moodliar Road, Rasta Peth, Pune 411 011 India Tel. 91 22 6111958 Fax 91 22 6125603 E-Mail [email protected] Prof. Xiaoguang Yang Chinese Center for Disease Control and Prevention, 27 Nan Wei Road, Beijing 100050 China Tel. 86 10 63012327 E-Mail [email protected]