Book contents
- Fetal and Neonatal Lung Development
- Lung Growth, Development, and Disease
- Fetal and Neonatal Lung Development
- Copyright page
- Contents
- Contributors
- Preface
- Chapter 1 The Genetic Programs Regulating Embryonic Lung Development and Induced Pluripotent Stem Cell Differentiation
- Chapter 2 Early Development of the Mammalian Lung-Branching Morphogenesis
- Chapter 3 Pulmonary Vascular Development
- Chapter 4 Transcriptional Mechanisms Regulating Pulmonary Epithelial Maturation:
- Chapter 5 Environmental Effects on Lung Morphogenesis and Function:
- Chapter 6 Congenital Malformations of the Lung
- Chapter 7 Lung Structure at Preterm and Term Birth
- Chapter 8 Surfactant During Lung Development
- Chapter 9 Initiation of Breathing at Birth
- Chapter 10 Perinatal Modifiers of Lung Structure and Function
- Chapter 11 Chronic Neonatal Lung Injury and Care Strategies to Decrease Injury
- Chapter 12 Apnea and Control of Breathing
- Chapter 13 Alveolarization into Adulthood
- Chapter 14 Physiologic Assessment of Lung Growth and Development Throughout Infancy and Childhood
- Chapter 15 Perinatal Disruptions of Lung Development:
- Chapter 16 Lung Growth Through the “Life Course” and Predictors and Determinants of Chronic Respiratory Disorders
- Chapter 17 The Lung Structure Maintenance Program: Sustaining Lung Structure during Adulthood and Implications for COPD Risk
- Index
- References
Chapter 11 - Chronic Neonatal Lung Injury and Care Strategies to Decrease Injury
Published online by Cambridge University Press: 05 April 2016
Book contents
- Fetal and Neonatal Lung Development
- Lung Growth, Development, and Disease
- Fetal and Neonatal Lung Development
- Copyright page
- Contents
- Contributors
- Preface
- Chapter 1 The Genetic Programs Regulating Embryonic Lung Development and Induced Pluripotent Stem Cell Differentiation
- Chapter 2 Early Development of the Mammalian Lung-Branching Morphogenesis
- Chapter 3 Pulmonary Vascular Development
- Chapter 4 Transcriptional Mechanisms Regulating Pulmonary Epithelial Maturation:
- Chapter 5 Environmental Effects on Lung Morphogenesis and Function:
- Chapter 6 Congenital Malformations of the Lung
- Chapter 7 Lung Structure at Preterm and Term Birth
- Chapter 8 Surfactant During Lung Development
- Chapter 9 Initiation of Breathing at Birth
- Chapter 10 Perinatal Modifiers of Lung Structure and Function
- Chapter 11 Chronic Neonatal Lung Injury and Care Strategies to Decrease Injury
- Chapter 12 Apnea and Control of Breathing
- Chapter 13 Alveolarization into Adulthood
- Chapter 14 Physiologic Assessment of Lung Growth and Development Throughout Infancy and Childhood
- Chapter 15 Perinatal Disruptions of Lung Development:
- Chapter 16 Lung Growth Through the “Life Course” and Predictors and Determinants of Chronic Respiratory Disorders
- Chapter 17 The Lung Structure Maintenance Program: Sustaining Lung Structure during Adulthood and Implications for COPD Risk
- Index
- References
Summary
Abstract
Currently, virtually all cases of bronchopulmonary dysplasia (BPD) occur in infants with birth weights <1250 g. A minority of these infants will develop a severe form of BPD, which evolves into a long-term failure of alveologenesis and vasculogenesis or, in some, a progressive pulmonary hypertension leading to an early death. Effective interventions, based on the mechanisms underlying the lung injury, most need to be developed for this group. We review putative mechanisms of lung and vascular injury, drawn on data from both clinical studies and animal models, then review currently used and potentially promising interventions. Despite numerous initiatives in clinical management, the overall incidence of BPD remains unchanged. Downward or upward manipulation of oxygen saturations is limited by increased risks of neurological impairment or retinopathy. Attempts to minimize ventilator-induced volutrauma have generally been disappointing, though avoidance of early intubation may be beneficial, and a volume-targeted approach to ventilation appears promising. Uncertainties exist about dosing, safety, and efficacy of such therapeutic interventions as high-dose vitamin A and caffeine in the currently most susceptible infant population. Promising approaches based on animal studies, but not yet adequately assessed in human infants, include the use of nonsteroidal antiinflammatory agents, antiprotease therapy and targeting bombesin-like peptides.
- Type
- Chapter
- Information
- Fetal and Neonatal Lung DevelopmentClinical Correlates and Technologies for the Future, pp. 205 - 222Publisher: Cambridge University PressPrint publication year: 2016
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