Your search keyword '"Pulmonary Valve embryology"' showing total 6 results

1. Spatiotemporally separated cardiac neural crest subpopulations that target the outflow tract septum and pharyngeal arch arteries.

Author

Boot MJ, Gittenberger-De Groot AC, Van Iperen L, Hierck BP, and Poelmann RE

Subjects

Animals, Aorta, Thoracic embryology, Cardiovascular System cytology, Cardiovascular System embryology, Cell Movement, Chick Embryo, Chimera, Coturnix, Heart Septum embryology, Immunohistochemistry, In Vitro Techniques, Lac Operon, Morphogenesis, Multipotent Stem Cells classification, Multipotent Stem Cells cytology, Multipotent Stem Cells physiology, Neural Crest cytology, Neural Crest physiology, Pharynx blood supply, Pulmonary Valve embryology, Specific Pathogen-Free Organisms, Time Factors, Aorta embryology, Heart embryology, Neural Crest embryology, Pharynx embryology, Pulmonary Artery embryology

Abstract

We used lacZ-retrovirus labeling combined with neural crest ablation in chick embryos to determine whether the cardiac neural crest cells constitute one group of multipotent cells, or they emigrate from the neural tube in time-dependent groups with different fates in the developing cardiovascular system. We demonstrated that early-migrating cardiac neural crest cells (HH9-10) massively target the aorticopulmonary septum and pharyngeal arch arteries, while the late-migrating cardiac neural crest cells (HH12) are restricted to the proximal part of the pharyngeal arch arteries. These results suggest a prominent role for early-migrating cells in outflow tract septation, and a function for late-migrating cells in pharyngeal arch artery remodeling. We demonstrated in cultures of neural tube explants an intrinsic difference between the early and late populations. However, by performing heterochronic transplantations we showed that the late-migrating cardiac neural crest cells were not developmentally restricted, and could contribute to the condensed mesenchyme of the aorticopulmonary septum when transplanted to a younger environment. Our findings on the exact timing and migratory behavior of cardiac neural crest cells will help narrow the range of factors and genes that are involved in neural crest-related congenital heart diseases., (Copyright 2003 Wiley-Liss, Inc.)

Published

2003

2. Sculpting the cardiac outflow tract.

Author

Rothenberg F, Fisher SA, and Watanabe M

Subjects

Animals, Aorta, Thoracic abnormalities, Aorta, Thoracic embryology, Aortic Valve abnormalities, Aortic Valve embryology, Apoptosis, Chick Embryo, Fetal Heart abnormalities, Fetal Heart growth & development, Heart Septal Defects embryology, Heart Septum embryology, Heart Ventricles embryology, Humans, Morphogenesis, Myocardium cytology, Pulmonary Artery abnormalities, Pulmonary Artery embryology, Pulmonary Valve abnormalities, Pulmonary Valve embryology, Zebrafish embryology, Heart embryology, Heart Defects, Congenital embryology, Ventricular Outflow Obstruction embryology

Abstract

The cardiac outflow tract is the site of anomalies that affect a substantial proportion of individuals with congenital heart defects. The morphogenesis of this site is complex, and requires coordinated development of many cell types and tissues. It is therefore not surprising that developmental mistakes arise here, and that the steps and mechanisms of morphogenesis are still controversial and poorly understood, despite advances in molecular techniques. Recent findings have provided new insight into mechanisms of outflow tract morphogenesis, including clarification of its origins and the fate of cardiomyocytes, as well as invading cell populations. Application of new and old techniques and a wide range of approaches to tackle the unanswered questions about the outflow tract calls for collaboration among investigators from different disciplines including anatomists, physiologists, and molecular biologists.

Published

2003

3. Histochemical and ultrastructural changes in the extracellular matrix of the developing chick semilunar heart valves.

Author

Garcia-Martinez V, Sanchez-Quintana D, and Hurle JM

Subjects

Animals, Aortic Valve chemistry, Aortic Valve ultrastructure, Azo Compounds, Chick Embryo, Lectins, Neuraminidase, Peanut Agglutinin, Picrates, Pulmonary Valve chemistry, Pulmonary Valve ultrastructure, Silver Staining, Wheat Germ Agglutinins, Aortic Valve embryology, Extracellular Matrix chemistry, Heart embryology, Plant Lectins, Pulmonary Valve embryology, Soybean Proteins

Abstract

The present study analyzes the composition and organization of the extracellular matrix (ECM) and its changes in the course of development of the chick embryo semilunar heart valves. In the present work we have employed chick embryos from stage 29 until hatching, using silver and picrosirius red staining, lectin probes and light and transmission electron microscopy. Our results show that during semilunar valve development a series of elements arise and are organized in the ECM which seem to be more closely related to the maintenance of the structural and biomechanical properties of the valvular leaflets than with morphogenetic processes per se.

Published

1991

4. Morphogenesis of human cardiac outflow.

Author

Thompson RP, Sumida H, Abercrombie V, Satow Y, Fitzharris TP, and Okamoto N

Subjects

Cell Survival, Embryo, Mammalian anatomy & histology, Humans, Myocardium cytology, Aortic Valve embryology, Heart embryology, Pulmonary Valve embryology

Abstract

The developmental anatomy of human cardiac outflow was studied in a series of 16 normal embryos (gestational days 29-39, crown-rump length 6-20 mm, stages 14-19). Structural features and kinetics during truncal septation (TS) were described from external photographs, serial histological sections, and computer graphic reconstructions of selected tissues. Early in the period studied, the tubular myocardium ensheathed the single cardiac lumen and spiralling conotruncal ridges, which were filled with mesenchymal cells during days 31-33. As TS began (late stage 16), the aorticopulmonary (AP) septum appeared across the dorsal wall of the aortic sac between arches IV and VI. Mesenchymal condensations formed within the AP septum, crossing the lumen bifurcation to extend along the truncal ridges to the myocardium. During days 35-37, the cephalic margin of the myocardium grew or folded in toward these mesenchymal condensations between the developing valves and within the nearby conal ridges, which appeared to fuse to separate the subvalvular outflow channels by day 39. These observations are consistent with studies in chicks and rats which suggest that mesenchymal condensations or cell death foci interact with the distal myocardial rim during TS to form a structural septation complex dividing the two arterial streams.

Published

1985

5. The position of the left and right ventricular outlets during septation. A comparison of chicken and rat development.

Author

Wagenaar JA, Lamers WH, and Los JA

Subjects

Animals, Aortic Valve embryology, Heart Ventricles, Medical Illustration, Pulmonary Valve embryology, Time Factors, Chick Embryo physiology, Heart embryology, Heart Septum embryology, Rats embryology

Abstract

A comparative study was made of the relative position of the outflow tracts of chicken and rat hearts with respect to the ventricles during septation. For this purpose the position of the left and right ventricular outlet including the aortic and pulmonary valve primordia and the left and right ventricle were established with respect to the midsagittal plane of the embryo, using reconstructions of serial sections of chicken (stage 28-30) and rat (stage 28-30) embryos. In the chicken embryo no rotation of the outflow tract occurs, i.e. the position of the aortic and pulmonary valve primordia with respect to the left and right ventricle remains the same. In the rat embryo a clockwise rotation of the aortic and pulmonary valve primordia with respect to the ventricles does occur. This is in fact a detorsion. The left and right ventricle and the left ventricular outlet do not show change in position with regard to the midsagittal plane. The left ventricular outlet always straddles the interventricular septum, both lying in the midsagittal plane. These interspecies differences in the degree of detorsion of the outflow channels before septation may explain the differences in the extent of the region of contact between the endocardial outflow tract ridges.

Published

1986

6. The quantitative anatomy of the normal human heart in fetal and perinatal life.

Author

Alvarez L, Aránega A, Saucedo R, and Contreras JA

Subjects

Aortic Valve anatomy & histology, Aortic Valve embryology, Cardiac Volume, Embryonic and Fetal Development, Female, Heart Valves embryology, Heart Ventricles anatomy & histology, Heart Ventricles embryology, Humans, Infant, Newborn, Male, Mitral Valve anatomy & histology, Mitral Valve embryology, Pulmonary Valve anatomy & histology, Pulmonary Valve embryology, Tricuspid Valve anatomy & histology, Tricuspid Valve embryology, Fetal Heart anatomy & histology, Heart anatomy & histology, Heart Valves anatomy & histology

Abstract

A total of 367 human fetuses and newborn subjects weighing from 60 to 5000 g provided the material for a morphometric study of the heart. A total of 17 interventricular parameters were measured in each specimen, one of the parameters representing an innovation with regard to the classically used set of measurements. A new anatomo-geometric configuration is described for each ventricle along with a new component for the left ventricular outflow tract, designated as the aortic outflow tract. The appropriate stereometric formulas were used to calculate real ventricular volumes rather than the previously studied volumetric indices. Additionally, correlation indices were calculated for ventricular wall thickness as well as the circumferences and diameters of the atrioventricular and arterial valves. The results show that, in fetuses of up to 2700 g in body weight, ventricular wall thickness is greater in the right than in the left ventricle, although the opposite is true in fetuses weighing above 2700 g. Throughout the range of weights studied, ventricular volume was greater in the left than in the right chamber. Tricuspid and pulmonary valve circumference and diameter were consistently greater than in the mitral and aortic valves, respectively. We believe the new morphometric data and their innovative interpretation to have immediate applications in both the morphological and functional areas of cardiology.

Published

1987