Book contents
- Frontmatter
- Contents
- List of contributors
- Preface
- 1 The developmental origins of health and disease: an overview
- 2 The ‘developmental origins’ hypothesis: epidemiology
- 3 The conceptual basis for the developmental origins of health and disease
- 4 The periconceptional and embryonic period
- 5 Epigenetic mechanisms
- 6 A mitochondrial component of developmental programming
- 7 Role of exposure to environmental chemicals in developmental origins of health and disease
- 8 Maternal nutrition and fetal growth and development
- 9 Placental mechanisms and developmental origins of health and disease
- 10 Control of fetal metabolism: relevance to developmental origins of health and disease
- 11 Lipid metabolism: relevance to developmental origins of health and disease
- 12 Prenatal hypoxia: relevance to developmental origins of health and disease
- 13 The fetal hypothalamic–pituitary–adrenal axis: relevance to developmental origins of health and disease
- 14 Perinatal influences on the endocrine and metabolic axes during childhood
- 15 Patterns of growth: relevance to developmental origins of health and disease
- 16 The developmental environment and the endocrine pancreas
- 17 The developmental environment and insulin resistance
- 18 The developmental environment and the development of obesity
- 19 The developmental environment and its role in the metabolic syndrome
- 20 Programming the cardiovascular system
- 21 The role of vascular dysfunction in developmental origins of health and disease: evidence from human and animal studies
- 22 The developmental environment and atherogenesis
- 23 The developmental environment, renal function and disease
- 24 The developmental environment: effect on fluid and electrolyte homeostasis
- 25 The developmental environment: effects on lung structure and function
- 26 Developmental origins of asthma and related allergic disorders
- 27 The developmental environment: influences on subsequent cognitive function and behaviour
- 28 The developmental environment and the origins of neurological disorders
- 29 The developmental environment: clinical perspectives on effects on the musculoskeletal system
- 30 The developmental environment: experimental perspectives on skeletal development
- 31 The developmental environment and the early origins of cancer
- 32 The developmental environment: implications for ageing and life span
- 33 Developmental origins of health and disease: implications for primary intervention for cardiovascular and metabolic disease
- 34 Developmental origins of health and disease: public-health perspectives
- 35 Developmental origins of health and disease: implications for developing countries
- 36 Developmental origins of health and disease: ethical and social considerations
- 37 Past obstacles and future promise
- Index
- References
12 - Prenatal hypoxia: relevance to developmental origins of health and disease
Published online by Cambridge University Press: 08 August 2009
- Frontmatter
- Contents
- List of contributors
- Preface
- 1 The developmental origins of health and disease: an overview
- 2 The ‘developmental origins’ hypothesis: epidemiology
- 3 The conceptual basis for the developmental origins of health and disease
- 4 The periconceptional and embryonic period
- 5 Epigenetic mechanisms
- 6 A mitochondrial component of developmental programming
- 7 Role of exposure to environmental chemicals in developmental origins of health and disease
- 8 Maternal nutrition and fetal growth and development
- 9 Placental mechanisms and developmental origins of health and disease
- 10 Control of fetal metabolism: relevance to developmental origins of health and disease
- 11 Lipid metabolism: relevance to developmental origins of health and disease
- 12 Prenatal hypoxia: relevance to developmental origins of health and disease
- 13 The fetal hypothalamic–pituitary–adrenal axis: relevance to developmental origins of health and disease
- 14 Perinatal influences on the endocrine and metabolic axes during childhood
- 15 Patterns of growth: relevance to developmental origins of health and disease
- 16 The developmental environment and the endocrine pancreas
- 17 The developmental environment and insulin resistance
- 18 The developmental environment and the development of obesity
- 19 The developmental environment and its role in the metabolic syndrome
- 20 Programming the cardiovascular system
- 21 The role of vascular dysfunction in developmental origins of health and disease: evidence from human and animal studies
- 22 The developmental environment and atherogenesis
- 23 The developmental environment, renal function and disease
- 24 The developmental environment: effect on fluid and electrolyte homeostasis
- 25 The developmental environment: effects on lung structure and function
- 26 Developmental origins of asthma and related allergic disorders
- 27 The developmental environment: influences on subsequent cognitive function and behaviour
- 28 The developmental environment and the origins of neurological disorders
- 29 The developmental environment: clinical perspectives on effects on the musculoskeletal system
- 30 The developmental environment: experimental perspectives on skeletal development
- 31 The developmental environment and the early origins of cancer
- 32 The developmental environment: implications for ageing and life span
- 33 Developmental origins of health and disease: implications for primary intervention for cardiovascular and metabolic disease
- 34 Developmental origins of health and disease: public-health perspectives
- 35 Developmental origins of health and disease: implications for developing countries
- 36 Developmental origins of health and disease: ethical and social considerations
- 37 Past obstacles and future promise
- Index
- References
Summary
Introduction
The compelling evidence linking small size at birth with later cardiovascular disease, obtained from epidemiological studies of human populations from more than a dozen countries (Barker 1998), has clearly renewed and amplified a clinical and scientific interest in the determinants of fetal growth, birthweight and the development of cardiovascular function before and after birth. As early as the 1950s Penrose highlighted that an important determinant of birthweight was the quality of the intrauterine environment, being twice as great a determinant of the rate of fetal growth as the maternal or fetal genotype. Studies of birthweights of relatives (Penrose 1954), together with strong evidence from animal crossbreeding experiments (Walton and Hammond 1938, Giussani et al. 2003), have clearly supported this contention. One of the important modifiers of the fetal environment is maternal nutritional status during pregnancy. The reciprocal association between low birthweight and increased risk of high blood pressure in adulthood, as described by Barker (1998), has exploded into a new field of research investigating the effects of maternofetal nutrition on fetal growth, birthweight and subsequent cardiovascular disease. However, the fetus nourishes itself also with oxygen, and in contrast to the international effort which is assessing the effects of maternofetal undernutrition on early development, the effects of maternofetal under-oxygenation on fetal growth, birthweight and subsequent increased risk of disease have been little addressed.
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- Information
- Developmental Origins of Health and Disease , pp. 178 - 190Publisher: Cambridge University PressPrint publication year: 2006
References
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