Your search keyword '"Hierck, Beerend P"' showing total 4 results

1. The development of the heart and microcirculation: role of shear stress.

Author

Poelmann, Robert E., Gittenberger-de Groot, Adriana C., and Hierck, Beerend P.

Subjects

CARDIOVASCULAR system, SHEAR (Mechanics), GROWTH factors, HEMODYNAMICS, BLOOD flow

Abstract

The article examines the influence of the blood flow and the ensuing shear stress in the changing geometry of the developing cardiovascular system. It discusses the transcription and growth factors that are important for the determination and specification of various components and segments of the cardiovascular system during embryogenesis. It also describes the geometrical changes during heart development as well as the changing hemodynamic results in cardiovascular malformations.

Published

2008

2. Endothelial primary cilia in areas of disturbed flow are at the base of atherosclerosis

Author

Van der Heiden, Kim, Hierck, Beerend P., Krams, Rob, de Crom, Rini, Cheng, Caroline, Baiker, Martin, Pourquie, Mathieu J.B.M., Alkemade, Fanneke E., DeRuiter, Marco C., Gittenberger-de Groot, Adriana C., and Poelmann, Robert E.

Subjects

*ARTERIES, *BLOOD circulation, *BLOOD flow, *HEMODYNAMICS

Abstract

Abstract: Atherosclerosis develops in the arterial system at sites of low as well as low and oscillating shear stress. Previously, we demonstrated a shear-related distribution of ciliated endothelial cells in the embryonic cardiovascular system and postulated that the primary cilium is a component of the shear stress sensor, functioning as a signal amplifier. This shear-related distribution is reminiscent of the atherosclerotic predilection sites. Thus, we determined whether a link exists between location and frequency of endothelial primary cilia and atherogenesis. We analyzed endothelial ciliation of the adult aortic arch and common carotid arteries of wild type C57BL/6 and apolipoprotein-E-deficient mice. Primary cilia are located at the atherosclerotic predilection sites, where flow is disturbed, in wild type mice and they occur on and around atherosclerotic lesions in apolipoprotein-E-deficient mice, which have significantly more primary cilia in the aortic arch than wild type mice. In addition, common carotid arteries were challenged for shear stress by application of a restrictive cast, resulting in the presence of primary cilia only at sites of induced low and disturbed shear. In conclusion, these data relate the presence of endothelial primary cilia to regions of atherogenesis, where they increase in number under hyperlipidemia-induced lesion formation. Experimentally induced flow disturbance leads to induction of primary cilia, and subsequently to atherogenesis, which suggests a role for primary cilia in endothelial activation and dysfunction. [Copyright &y& Elsevier]

Published

2008

3. The Endothelin-1 Pathway and the Development of Cardiovascular Defects in the Haemodynamically Challenged Chicken Embryo.

Author

Groenendijk, Bianca C. W., Stekelenburg-de Vos, Sandra, Vennemann, Peter, Wladimiroff, Juriy W., Nieuwstadt, Frans T. M., Lindken, Ralph, Westerweel, Jerry, Hierck, Beerend P., Ursem, Nicolette T. C., and Poelmann, Robert E.

Subjects

BLOOD circulation, MICROCIRCULATION, ARTERIOVENOUS anastomosis, COMBINATORIAL geometry, CARDIOVASCULAR system, BLOOD flow, GENETIC regulation, GENE expression

Abstract

Background/Aims: Ligating the right lateral vitelline vein of chicken embryos (venous clip) results in cardiovascular malformations. These abnormalities are similar to malformations observed in knockout mice studies of components of the endothelin-1 (ET-1)/endothelin-converting enzyme-1/endothelin-A receptor pathway. In previous studies we demonstrated that cardiac ET-1 expression is decreased 3 h after clipping, and ventricular diastolic filling is disturbed after 2 days. Therefore, we hypothesise that ET-1-related processes are involved in the development of functional and morphological cardiovascular defects after venous clip. Methods: In this study, ET-1 and endothelin receptor antagonists (BQ-123, BQ-788 and PD145065) were infused into the HH18 embryonic circulation. Immediate haemodynamic effects on the embryonic heart and extra-embryonic vitelline veins were examined by Doppler and micro-particle image velocimetry. Ventricular diastolic filling characteristics were studied at HH24, followed by cardiovascular morphologic investigation (HH35). Results: ET-1 and its receptor antagonists induced haemodynamic effects at HH18. At HH24, a reduced diastolic ventricular passive filling component was demonstrated, which was compensated by an increased active filling component. Thinner ventricular myocardium was shown in 42% of experimental embryos. Conclusion: We conclude that cardiovascular malformations after venous clipping arise from a combination of haemodynamic changes and altered gene expression patterns and levels, including those of the endothelin pathway. Copyright © 2007 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2008

4. In vivo micro particle image velocimetry measurements of blood-plasma in the embryonic avian heart

Author

Vennemann, Peter, Kiger, Kenneth T., Lindken, Ralph, Groenendijk, Bianca C.W., Stekelenburg-de Vos, Sandra, ten Hagen, Timo L.M., Ursem, Nicolette T.C., Poelmann, Rob E., Westerweel, Jerry, and Hierck, Beerend P.

Subjects

*BLOOD plasma, *BLOOD flow, *HEART, *GENE expression

Abstract

Abstract: The measurement of blood-plasma velocity distributions with spatial and temporal resolution in vivo is inevitable for the determination of shear stress distributions in complex geometries at unsteady flow conditions like in the beating heart. A non-intrusive, whole-field velocity measurement technique is required that is capable of measuring instantaneous flow fields at sub-millimeter scales in highly unsteady flows. Micro particle image velocimetry meets these demands, but requires special consideration and methodologies in order to be utilized for in vivo studies in medical and biological research. We adapt to measure the blood-plasma velocity in the beating heart of a chicken embryo. In the current work, bio-inert, fluorescent liposomes with a nominal diameter of 400nm are added to the flow as a tracer. Because of their small dimension and neutral buoyancy the liposomes closely follow the movement of the blood-plasma and allow the determination of the velocity gradient close to the wall. The measurements quantitatively resolve the velocity distribution in the developing ventricle and atrium of the embryo at nine different stages within the cardiac cycle. Up to 400 velocity vectors per measurement give detailed insight into the fluid dynamics of the primitive beating heart. A rapid peristaltic contraction accelerates the flow to peak velocities of 26mm/s, with the velocity distribution showing a distinct asymmetrical profile in the highly curved section of the outflow tract. In relation to earlier published gene-expression experiments, the results underline the significance of fluid forces for embryonic cardiogenesis. In general, the measurements demonstrate that has the potential to develop into a general tool for instationary flow conditions in complex flow geometries encountered in cardiovascular research. [Copyright &y& Elsevier]

Published

2006