Meeting Abstract

24.2  Monday, Jan. 5  Flow within Physical Models of the Vertebrate Embryonic Heart NGUYEN, NHI / P.*; MILLER, LAURA; SANTHANAKRISHNAN, ARVIND; GUNDERSON, JENNIFER; Univ. of North Carolina, Chapel Hill en08nicki@gmail.com

Vertebrate cardiogenesis is believed to be partially regulated by fluid forces imposed by blood flow in addition to myocardial activity and other epigenetic factors. Recent in vitro studies in embryonic cardiogenesis (see Hove et al., Nature , 2003) show that blood flowing through the embryonic heart tube creates shear forces necessary for the formation and development of the heart valves. It is suggested that these flow driven forces interact with the core proteins (e.g. proteoglycans, heparin sulfate glycosaminoglycans (GAGs), glycoproteins, and plasma proteins) making up the glycocalyx and endothelial surface layer (ESL). The shear and pressure forces from these flows provide a mechanical stimulus that is transmitted through the various proteins and the cytoskeleton, resulting in a biomechanical cascade within the ESL that might initiate intracellular processes leading to heart looping, chamber ballooning and valve formation. To understand the flow field within the embryonic heart, flow visualization experiments were performed on a series of physical models that represent the different morphological stages of early heart development. The chamber and valve depths of the models as well as the Reynolds numbers were varied in this study. Different compositions of solutions consisting of corn syrup and water were used as the fluid media to examine Reynolds numbers from 0.01 to 1000, corresponding to a scale of the early heart tube to the adult heart. The observed results showed that vortex formation within the chambers occurred for Reynolds numbers in the range of 1-10. This transition to vortical flow appears to be highly sensitive to the chamber and valve depths within the model. The sensitivity of this transition in flow ultimately affects the mechanotransduction ability of the ESL.