Abstract
The role of hemodynamic forces within the embryo as biomechanical regulators for cardiovascular morphogenesis, growth, and remodeling is well supported through the experimental studies. Furthermore, clinical experience suggests that perturbed flow disrupts the normal vascular growth process as one etiology for congenital heart diseases (CHD) and for fetal adaptation to CHD. However, the relationships between hemodynamics, gene expression and embryonic vascular growth are poorly defined due to the lack of concurrent, sequential in vivo data. In this study, a long-term, time-lapse optical coherence tomography (OCT) imaging campaign was conducted to acquire simultaneous blood velocity, pulsatile micro-pressure and morphometric data for 3 consecutive early embryonic stages in the chick embryo. In conjunction with the in vivo growth and hemodynamics data, in vitro reverse transcription polymerase chain reaction (RT-PCR) analysis was performed to track changes in transcript expression relevant to histogenesis and remodeling of the embryonic arterial wall. Our non-invasive extended OCT imaging technique for the microstructural data showed continuous vessel growth. OCT data coupled with the PIV technique revealed significant but intermitted increases in wall shear stress (WSS) between first and second assigned stages and a noticeable decrease afterwards. Growth rate, however, did not vary significantly throughout the embryonic period. Among all the genes studied, only the MMP-2 and CASP-3 expression levels remained unchanged during the time course. Concurrent relationships were obtained among the transcriptional modulation of the genes, vascular growth and hemodynamics-related changes. Further studies are indicated to determine cause and effect relationships and reversibility between mechanical and molecular regulation of vasculogenesis.
Highlights
Embryonic blood vessel development is regulated through continuous synthesis and remodeling processes
Vessel growth and genetic mechanisms may not progress in perfect harmony with hemodynamic changes, leading to delays in response to flow-induced stress that are typically found within the embryonic vasculature [8]
Some of the hemodynamic parameters have been well assessed for the early chick embryonic cardiovascular system [9, 10], a correlative study relating the microvascular growth, genetic pathways and hemodynamics is still lacking in the literature
Summary
Embryonic blood vessel development (vasculogenesis and angiogenesis) is regulated through continuous synthesis and remodeling processes. Inter- and intra-cellular signaling, under the influence of blood flow, regulates vascular microstructure and regenerative cascade of events, and the morphogenetic fate for the embryonic vessel network through genetic pathways [1]. In the early embryonic vasculature system, newly-formed endothelial cells are under the influence of blood shear stress and circumferential stress as physiological mechano-regulatory stimuli [6]. Vessel growth and genetic mechanisms may not progress in perfect harmony with hemodynamic changes, leading to delays in response to flow-induced stress that are typically found within the embryonic vasculature [8]. Some of the hemodynamic parameters have been well assessed for the early chick embryonic cardiovascular system [9, 10], a correlative study relating the microvascular growth, genetic pathways and hemodynamics is still lacking in the literature
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