Blood flow dynamics of one cardiac cycle and relationship to mechanotransduction and trabeculation during heart looping.

Analyses of form-function relationships during heart looping are directly related to technological advances. Recent advances in four-dimensional optical coherence tomography (OCT) permit observations of cardiac dynamics at high-speed acquisition rates and high resolution. Real-time observation of the avian stage 13 looping heart reveals that interactions between the endocardial and myocardial compartments are more complex than previously depicted. Here we applied four-dimensional OCT to elucidate the relationships of the endocardium, myocardium, and cardiac jelly compartments in a single cardiac cycle during looping. Six cardiac levels along the longitudinal heart tube were each analyzed at 15 time points from diastole to systole. Using image analyses, the organization of mechanotransducing molecules, fibronectin, tenascin C, α-tubulin, and nonmuscle myosin II was correlated with specific cardiac regions defined by OCT data. Optical coherence microscopy helped to visualize details of cardiac architectural development in the embryonic mouse heart. Throughout the cardiac cycle, the endocardium was consistently oriented between the midline of the ventral floor of the foregut and the outer curvature of the myocardial wall, with multiple endocardial folds allowing high-volume capacities during filling. The cardiac area fractional shortening is much higher than previously published. The in vivo profile captured by OCT revealed an interaction of the looping heart with the extra-embryonic splanchnopleural membrane providing outside-in information. In summary, the combined dynamic and imaging data show the developing structural capacity to accommodate increasing flow and the mechanotransducing networks that organize to effectively facilitate formation of the trabeculated four-chambered heart.

[1]  Krishnaswamy Chandrasekaran,et al.  Twist mechanics of the left ventricle: principles and application. , 2008, JACC. Cardiovascular imaging.

[2]  M. Palomino,et al.  The primitive cardiac regions in the straight tube heart (Stage 9) and their anatomical expression in the mature heart: An experimental study in the chick embryo. , 1989, Journal of anatomy.

[3]  David L Wilson,et al.  High temporal resolution OCT using image-based retrospective gating. , 2009, Optics express.

[4]  W H Lamers,et al.  Persisting zones of slow impulse conduction in developing chicken hearts. , 1992, Circulation research.

[5]  Y. Oka,et al.  PKC mediates cyclic stretch‐induced cardiac hypertrophy through Rho family GTPases and mitogen‐activated protein kinases in cardiomyocytes , 2005, Journal of cellular physiology.

[6]  E. Clark,et al.  Effect of changes in circulating blood volume on cardiac output and arterial and ventricular blood pressure in the stage 18, 24, and 29 chick embryo. , 1990, Circulation research.

[7]  F. Manasek,et al.  Experimental studies of the shape and structure of isolated cardiac jelly. , 1978, Journal of embryology and experimental morphology.

[8]  T. Spray,et al.  Altered hemodynamics controls matrix metalloproteinase activity and tenascin-C expression in neonatal pig lung. , 2002, American Journal of Physiology - Lung cellular and Molecular Physiology.

[9]  V. Ferrans,et al.  The stretch-activation response may be critical to the proper functioning of the mammalian heart. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[10]  Kim Van der Heiden,et al.  Monocilia on chicken embryonic endocardium in low shear stress areas , 2006, Developmental dynamics : an official publication of the American Association of Anatomists.

[11]  V. Ferrans,et al.  Nonmuscle myosin II-B is required for normal development of the mouse heart. , 1997, Proceedings of the National Academy of Sciences of the United States of America.

[12]  K. Linask Regulation of heart morphology: current molecular and cellular perspectives on the coordinated emergence of cardiac form and function. , 2003, Birth defects research. Part C, Embryo today : reviews.

[13]  J. Hurlé,et al.  Compositional and structural heterogenicity of the cardiac jelly of the chick embryo tubular heart: a TEM, SEM and histochemical study. , 1980, Journal of embryology and experimental morphology.

[14]  B. M. Patten,et al.  Valvular action in the embryonic chick heart by localized apposition of endocardial masses , 1948, The Anatomical record.

[15]  Bradley B Keller,et al.  Regional passive ventricular stress-strain relations during development of altered loads in chick embryo. , 2002, American journal of physiology. Heart and circulatory physiology.

[16]  Renato Perucchio,et al.  Computational model for the transition from peristaltic to pulsatile flow in the embryonic heart tube. , 2007, Journal of biomechanical engineering.

[17]  E. Clark,et al.  Remodeling of chick embryonic ventricular myoarchitecture under experimentally changed loading conditions , 1999, The Anatomical record.

[18]  Michael W. Jenkins,et al.  Ultrahigh-speed optical coherence tomography imaging and visualization of the embryonic avian heart using a buffered Fourier Domain Mode Locked laser. , 2007, Optics express.

[19]  Chun-Min Lo,et al.  Nonmuscle myosin IIb is involved in the guidance of fibroblast migration. , 2003, Molecular biology of the cell.

[20]  David Sedmera,et al.  Effects of mechanical loading on early conduction system differentiation in the chick. , 2010, American journal of physiology. Heart and circulatory physiology.

[21]  K. Stankunas,et al.  Endocardial Brg1 represses ADAMTS1 to maintain the microenvironment for myocardial morphogenesis. , 2008, Developmental cell.

[22]  Ashok Ramasubramanian,et al.  Morphogenetic adaptation of the looping embryonic heart to altered mechanical loads , 2006, Developmental dynamics : an official publication of the American Association of Anatomists.

[23]  N. Hu,et al.  Hemodynamics of the Stage 12 to Stage 29 Chick Embryo , 1989, Circulation research.

[24]  K. Linask,et al.  Application of plastic embedding for sectioning whole-mount immunostained early vertebrate embryos. , 2000, Methods in molecular biology.

[25]  G. Sacchi,et al.  Mechanotransduction in lymphatic endothelial cells. , 2007, Lymphology.

[26]  C. Figdor,et al.  Myosin II and mechanotransduction: a balancing act. , 2007, Trends in cell biology.

[27]  K. Linask,et al.  Cardiac morphogenesis: Matrix metalloproteinase coordination of cellular mechanisms underlying heart tube formation and directionality of looping , 2005, Developmental dynamics : an official publication of the American Association of Anatomists.

[28]  T. Sasaki,et al.  Extracellular matrix protein fibulin-2 is expressed in the embryonic endocardial cushion tissue and is a prominent component of valves in adult heart. , 1995, Developmental biology.

[29]  F. Manasek,et al.  Cardiac jelly fibrils: their distribution and organization. , 1978, Birth defects original article series.

[30]  Cassandra R. Farthing,et al.  Cellular nonmuscle myosins NMHC‐IIA and NMHC‐IIB and vertebrate heart looping , 2008, Developmental dynamics : an official publication of the American Association of Anatomists.

[31]  J G Fujimoto,et al.  High-resolution optical coherence microscopy for high-speed, in vivo cellular imaging. , 2003, Optics letters.

[32]  M. Brueckner,et al.  Monocilia in the embryonic mouse heart suggest a direct role for cilia in cardiac morphogenesis , 2008, Developmental dynamics : an official publication of the American Association of Anatomists.

[33]  A. Barry,et al.  The functional significance of the cardiac jelly in the tubular heart of the chick embryo , 1948 .

[34]  B. Keller,et al.  Correlation of ventricular area, perimeter, and conotruncal diameter with ventricular mass and function in the chick embryo from stages 12 to 24. , 1990, Circulation research.

[35]  J. Fujimoto,et al.  Optical coherence microscopy in scattering media. , 1994, Optics letters.

[36]  T. Mikawa,et al.  Trabecular myocytes of the embryonic heart require N-cadherin for migratory unit identity. , 1998, Developmental biology.

[37]  Anna I Hickerson,et al.  The Embryonic Vertebrate Heart Tube Is a Dynamic Suction Pump , 2006, Science.

[38]  Igor R Efimov,et al.  Optical Coherence Tomography as a Tool for Measuring Morphogenetic Deformation of the Looping Heart , 2007, Anatomical record.

[39]  F. Manasek,et al.  Embryonic development of the heart. I. A light and electron microscopic study of myocardial development in the early chick embryo , 1968, Journal of morphology.

[40]  Viktor Hamburger,et al.  A series of normal stages in the development of the chick embryo , 1992, Journal of morphology.

[41]  Darrell J. R. Evans,et al.  Developmental stages of the Japanese quail , 2010, Journal of anatomy.

[42]  Jörg Männer,et al.  High‐resolution in vivo imaging of the cross‐sectional deformations of contracting embryonic heart loops using optical coherence tomography , 2008, Developmental dynamics : an official publication of the American Association of Anatomists.

[43]  Wei Zheng,et al.  Stretch induces upregulation of key tyrosine kinase receptors in microvascular endothelial cells. , 2004, American journal of physiology. Heart and circulatory physiology.

[44]  Gabriel Acevedo-Bolton,et al.  Intracardiac fluid forces are an essential epigenetic factor for embryonic cardiogenesis , 2003, Nature.

[45]  J. Huhta,et al.  Doppler Echocardiography of Normal and Abnormal Embryonic Mouse Heart , 1996, Pediatric Research.

[46]  A. Aletras,et al.  A gradient of myosin regulatory light-chain phosphorylation across the ventricular wall supports cardiac torsion. , 2002, Cold Spring Harbor symposia on quantitative biology.

[47]  Martin Baiker,et al.  Changes in Shear Stress–Related Gene Expression After Experimentally Altered Venous Return in the Chicken Embryo , 2005, Circulation research.

[48]  Bradley B Keller,et al.  Microtubule Involvement in the Adaptation to Altered Mechanical Load in Developing Chick Myocardium , 2002, Circulation research.

[49]  D. Stainier,et al.  Early Myocardial Function Affects Endocardial Cushion Development in Zebrafish , 2004, PLoS biology.

[50]  R E Poelmann,et al.  Intracardiac blood flow patterns related to the yolk sac circulation of the chick embryo. , 1995, Circulation research.

[51]  David C. Young,et al.  Regulation of myotrophin gene by pressure overload and stretch , 2004, Molecular and Cellular Biochemistry.

[52]  Jörg Männer,et al.  In vivo imaging of the cyclic changes in cross‐sectional shape of the ventricular segment of pulsating embryonic chick hearts at stages 14 to 17: A contribution to the understanding of the ontogenesis of cardiac pumping function , 2009, Developmental dynamics : an official publication of the American Association of Anatomists.

[53]  David Sedmera,et al.  High‐frequency ultrasonographic imaging of avian cardiovascular development , 2007, Developmental dynamics : an official publication of the American Association of Anatomists.

[54]  Aiping Du,et al.  Myofibrillogenesis in the first cardiomyocytes formed from isolated quail precardiac mesoderm. , 2003, Developmental biology.

[55]  N. Epstein,et al.  Sensing Stretch Is Fundamental , 2003, Cell.

[56]  L. Velloso,et al.  RhoA/ROCK signaling is critical to FAK activation by cyclic stretch in cardiac myocytes. , 2005, American journal of physiology. Heart and circulatory physiology.

[57]  R. Markwald,et al.  Formation and Septation of the Tubular Heart: Integrating the Dynamics of Morphology With Emerging Molecular Concepts , 1998 .

[58]  M. Vanauker,et al.  A Role for the Cytoskeleton in Heart Looping , 2007, TheScientificWorldJournal.

[59]  W. Hop,et al.  Acutely altered hemodynamics following venous obstruction in the early chick embryo , 2003, Journal of Experimental Biology.

[60]  Renato Perucchio,et al.  Patterns of muscular strain in the embryonic heart wall , 2009, Developmental dynamics : an official publication of the American Association of Anatomists.

[61]  M. Hori,et al.  Guidance of myocardial patterning in cardiac development by Sema6D reverse signalling , 2004, Nature Cell Biology.

[62]  J. Fujimoto,et al.  Swept source optical coherence microscopy using a Fourier domain mode-locked laser. , 2007, Optics express.