Fluid Dynamics of Ventricular Filling in the Embryonic Heart

Cell Biochemistry and Biophysics

Volumn 61, Issue 1, 2011, Pages 33-45

  Miller, Laura A ^a  

^a University of North Carolina at Chapel Hill   (United States)

Author keywords

Biofluids; Heart development; Shear stress

Indexed keywords

ANIMAL; ANIMAL EMBRYO; ARTICLE; BIOLOGICAL MODEL; COMPUTER SIMULATION; EMBRYO DEVELOPMENT; HEART ATRIUM FUNCTION; HEART CONTRACTION; HEART VENTRICLE; HEART VENTRICLE FUNCTION; HYDRODYNAMICS; PRENATAL DEVELOPMENT; SHEAR STRENGTH; ZEBRA FISH;

ANIMALS; ATRIAL FUNCTION; COMPUTER SIMULATION; EMBRYO, NONMAMMALIAN; EMBRYONIC DEVELOPMENT; HEART VENTRICLES; HYDRODYNAMICS; MODELS, CARDIOVASCULAR; MYOCARDIAL CONTRACTION; SHEAR STRENGTH; VENTRICULAR FUNCTION; ZEBRAFISH;

VERTEBRATA;

EID: 80051468918     PISSN: 10859195     EISSN: None     Source Type: Journal    
DOI: 10.1007/s12013-011-9157-9     Document Type: Article

References (37)

1. Burggren, W. W. (2004). What is the purpose of the embryonic heart beat? Or how facts can ultimately prevail over physiological dogma. Physiological and Biochemical Zoology, 77, 333-345.
2. Hove, J. R. (2004). In vivo biofluid dynamic imaging in the developing zebrafish. Birth Defects Research, 72, 277-289.
3. Manasek, F. J. (1981). Determinants of heart shape in early embryos. Federation Proceedings, 40, 2011-2016.
4. Manner, J. (2000). Cardiac looping in the chick embryo: a morphological review with special reference to terminological and biomechanical aspects of the looping process. Anatomical Record, 259, 248-262.
5. Taber, L. A., Lin, I.-E., & Clark, L. A. (2005). Mechanics of cardiac looping. Developmental Dynamics, 1, 42-50.
6. Moorman, A. F. M., & Christoffels, V. M. (2003). Cardiac chamber formation: development, genes, and evolution. Physiological Reviews, 83, 1223-1267.
7. Satou, Y., & Satoh, N. (2006). Gene regulatory networks for the development, evolution of the chordate heart. Genes and Development, 20, 2634-2638.
8. Patterson, C. (2005). Even flow: shear cues vascular development. Arteriosclerosis, Thrombosis, and Vascular Biology, 25, 1761-1762.
9. Forouhar, A. S., Liebling, M., Hickerson, A., Nasiraei-Moghaddam, A., Tsai, H.-J., Hove, J. R., et al. (2006). The embryonic vertebrate heart tube is a dynamic suction pump. Science, 312, 751-753.
10. Hove, J. R., Koster, R. W., Forouhar, A. S., Acevedo-Bolton, G., Fraser, S. E., & Gharib, M. (2003). Intracardiac fluid forces are an essential epigenetic factor for embryonic cardiogenesis. Nature, 421, 172-177.
11. Misra, S., Fu, A. A., Puggioni, A., Karimi, K. M., Mandrekar, J. N., Glockner, J. F., et al. (2008). Increased shear stress with upregulation of VEGF-A and its receptors and MMP-2, MMP-9, and TIMP-1 in venous stenosis of hemodialysis grafts. American Journal of Physiology: Heart and Circulatory Physiology, 294, 2219-2230.
12. Thi, M. M., Iacobas, D. A., Iacobas, S., & Spray, D. C. (2007). Fluid shear stress upregulates vascular endothelial growth factor gene expression in osteoblasts. Annals of the New York Academy of Sciences, 1117, 73-81.
13. Ohno, M., Cooke, J. P., Dzau, V. J., & Gibbons, G. H. (1995). Fluid shear stress induces endothelial transforming growth factor beta-1 transcription and production. Modulation by potassium channel blockade. Journal of Clinical Investigation, 95, 1363-1369.
14. Reckova, M., Rosengarten, C., de Almeida, A., Stanley, C. P., Wessels, A., Gourdie, R. G., et al. (2003). Hemodynamics is a key epigenetic factor in development of the cardiac conduction system. Circulation Research, 93, 77-85.
15. Folkow, B. (1982). Physiological aspects of primary hypertension. Physiological Reviews, 62, 347-504.
16. Mulvany, M. J. (1991). Are vascular abnormalities a primary cause or secondary consequence of hypertension? Hypertension, 18, 52-57.
17. Westerhof, N., Stergiopulos, N., & Noble, M. I. M. (2006). Snapshots of hemodynamics: an aid for clinical research and graduate education. New York: Springer-Verlag.
18. Bartman, T., Walsh, E. C., Wen, K. K., McKane, M., Ren, J., Alexander, J., et al. (2004). Early myocardial function affects endocardial cushion development in zebrafish. PLoS Biology, 2, 673-681.
19. Herrmann, C., Wray, J., Travers, F., & Barman, T. (1992). Effect of 2 3-butanedione monoxime on myosin and myofibrillar ATPases. An example of an uncompetitive inhibitor. Biochemistry, 31, 12227-12232.
20. Mironov, V., Visconti, R. P., & Markwald, R. R. (2005). On the role of shear stress in cardiogenesis. Endothelium, 12, 259-261.
21. Thurston, G. B. (1972). Viscoelasticity of human blood. Biophysical Journal, 12, 1205-1217.
22. Thurston, G. B. (1979). Rheological parameters for the viscosity viscoelasticity and thixotropy of blood. Biorheology, 16, 149-162.
23. Chien, S., Usami, S., Taylor, H. M., Lundberg, J. L., & Gregersen, M. I. (1966). Effects of hematocrit and plasma proteins on human blood rheology at low shear rates. Journal of Applied Physiology, 21, 81-87.
24. Chmiel, H., & Walitza, E. (1980). On the rheology of blood and synovial. New York: Research Studies Press.
25. Chhabra, R. P., & Richardson, J. F. (2008). Non-Newtonian flow and applied rheology (2nd ed.). Oxford: Butterworth-Heinemann.
26. Moorman, A. F. M., Soufan, A. T., Hagoort, J., De Boer, P. A. J., & Christoffels, V. M. (2004). Development of the building plan of the heart. Annals of the New York Academy of Sciences, 1015, 171-181.
27. Peskin, C. S. (2002). The immersed boundary method. Acta Numerica, 11, 479-517.
28. Peskin, C. S. (1977). Flow patterns around heart valves: a numerical method. Journal of Computational Physics, 25, 220-252.
29. Peskin, C. S., & McQueen, D. M. (1996). Fluid dynamics of the heart and its valves. In F. R. Adler, M. A. Lewis, J. C. Dalton, & H. G. Othmer (Eds.), Case studies in mathematical modeling-ecology, physiology, and cell biology (pp. 309-337). New Jersey: Prentice Hall.
30. Jung, E. N., & Peskin, C. S. (2001). Two-dimensional simulations of valveless pumping using the immersed boundary method. SIAM Journal on Scientific Computing, 23, 19-45.
31. Fogelson, A. L. (1984). A mathematical model and numerical method for studying platelet adhesion and aggregation during blood clotting. Journal of Computational Physics, 56, 111-134.
32. Miller, L. A., & Peskin, C. S. (2005). A computational fluid dynamics of 'clap and fling' in the smallest insects. Journal of Experimental Biology, 208, 195-212.
33. Miller, L. A., & Peskin, C. S. (2004). When vortices stick: an aerodynamic transition in tiny insect flight. Journal of Experimental Biology, 207, 3073-3088.
34. Santhanakrishnan, A., Nguyen, N., Cox, J. G., & Miller, L. A. (2009). Flow within models of the vertebrate embryonic heart. Journal of Theoretical Biology, 259, 449-461.
35. Peskin, C. S., & Printz, B. F. (1993). Improved volume conservation in the computation of flows with immersed elastic boundaries. Journal of Computational Physics, 105, 33-46.
36. Griffith, B. E., Hornung, R. D., McQueen, D. M., & Peskin, C. S. (2009). Parallel and adaptive simulation of cardiac fluid dynamics. In M. Chandra, S. Li, & X. Parashar (Eds.), Advanced computational infrastructures for parallel and distributed adaptive applications (chapter 7, pp. 105-130). New York: John Wiley and Sons.
37. Press, W. H., Teukolsky, S. A., Vetterling, W. T., & Flannery, B. P. (1992). Numerical recipes in FORTRAN: the art of scientific computing. Cambridge, UK: Cambridge University Press.