scholarly article | Q13442814 |
P2093 | author name string | Deborah Yelon | |
Huai-Jen Tsai | |||
Heather E Riley | |||
Felix Olale | |||
Hope Coleman | |||
Heidi J Auman | |||
P2860 | cites work | Sarcomere protein gene mutations in hypertrophic cardiomyopathy of the elderly | Q24292234 |
T-box transcription factor Tbx2 represses differentiation and formation of the cardiac chambers | Q24320013 | ||
Early myocardial function affects endocardial cushion development in zebrafish | Q24796758 | ||
Embryonic atrial function is essential for mouse embryogenesis, cardiac morphogenesis and angiogenesis | Q28211875 | ||
Calcium not strain regulates localization of alpha-myosin heavy chain mRNA in oriented cardiac myocytes | Q28213656 | ||
Size control in animal development | Q28297142 | ||
Tbx2 is essential for patterning the atrioventricular canal and for morphogenesis of the outflow tract during heart development | Q28508308 | ||
Chamber formation and morphogenesis in the developing mammalian heart | Q28566310 | ||
A mouse model of familial hypertrophic cardiomyopathy | Q28588233 | ||
Endothelial signaling in kidney morphogenesis: a role for hemodynamic forces | Q31044427 | ||
Patterning during organogenesis: genetic analysis of cardiac chamber formation. | Q33650766 | ||
Seeking a regulatory roadmap for heart morphogenesis | Q33650772 | ||
Cardiac looping in the chick embryo: a morphological review with special reference to terminological and biomechanical aspects of the looping process | Q33947066 | ||
Measuring dimensions: the regulation of size and shape | Q33947762 | ||
Control of growth and organ size in Drosophila | Q34488131 | ||
Cardiac development in zebrafish: coordination of form and function | Q35018089 | ||
Fluid shear stress and the vascular endothelium: for better and for worse | Q35121798 | ||
Minireview: natriuretic peptides during development of the fetal heart and circulation | Q35127242 | ||
Cardiac chamber formation: development, genes, and evolution. | Q35541868 | ||
Mechanical asymmetry in the embryonic chick heart during looping. | Q51716524 | ||
Developmental pattern of ANF gene expression reveals a strict localization of cardiac chamber formation in chicken. | Q52125233 | ||
Regionalized sequence of myocardial cell growth and proliferation characterizes early chamber formation. | Q53607310 | ||
Myocardial cell shape change as a mechanism of embryonic heart looping. | Q54117044 | ||
Changes in Shear Stress–Related Gene Expression After Experimentally Altered Venous Return in the Chicken Embryo | Q58323282 | ||
Determinants of heart shape in early embryos | Q70760656 | ||
Development and ultrastructure of the embryonic heart. II. Mechanism of dextral looping of the embryonic heart | Q71471264 | ||
Regional mitotic activity in the precardiac mesoderm and differentiating heart tube in the chick embryo | Q72414506 | ||
An experimental study of the relation of cardiac jelly to the shape of the early chick embryonic heart | Q72923573 | ||
Patterning the vertebrate heart | Q74399546 | ||
Orientation change of cardiocytes induced by cyclic stretch stimulation: time dependency and involvement of protein kinases | Q74596189 | ||
Mechanobiology and diseases of mechanotransduction | Q35622033 | ||
Shear-induced reorganization of endothelial cell cytoskeleton and adhesion complexes | Q35792109 | ||
Architectural plan for the heart: early patterning and delineation of the chambers and the nodes. | Q35982225 | ||
Mechanics and function in heart morphogenesis | Q36097892 | ||
Determinants of natriuretic peptide gene expression | Q36135889 | ||
The genetic basis for cardiac remodeling | Q36241650 | ||
Titin and its associated proteins: the third myofilament system of the sarcomere | Q36288542 | ||
Oriented clonal cell growth in the developing mouse myocardium underlies cardiac morphogenesis | Q36321793 | ||
Biophysical mechanisms of cardiac looping | Q36396939 | ||
Germ-line transmission of a myocardium-specific GFP transgene reveals critical regulatory elements in the cardiac myosin light chain 2 promoter of zebrafish | Q38350936 | ||
Intrinsic and extrinsic control of growth in developing organs | Q40197878 | ||
Computational model for early cardiac looping | Q40321288 | ||
Restricted expression of cardiac myosin genes reveals regulated aspects of heart tube assembly in zebrafish. | Q40797201 | ||
Screening mosaic F1 females for mutations affecting zebrafish heart induction and patterning | Q40855804 | ||
Cell-autonomous action of zebrafish spt-1 mutation in specific mesodermal precursors | Q41214829 | ||
Cellular control lies in the balance of forces | Q41750971 | ||
Rapidly maturing variants of the Discosoma red fluorescent protein (DsRed). | Q43830777 | ||
Intracardiac fluid forces are an essential epigenetic factor for embryonic cardiogenesis | Q43998282 | ||
A cellular framework for gut-looping morphogenesis in zebrafish. | Q44630502 | ||
Initial formation of zebrafish brain ventricles occurs independently of circulation and requires the nagie oko and snakehead/atp1a1a.1 gene products. | Q46402305 | ||
Cardiomyopathy in zebrafish due to mutation in an alternatively spliced exon of titin | Q47073224 | ||
Mutation of weak atrium/atrial myosin heavy chain disrupts atrial function and influences ventricular morphogenesis in zebrafish | Q47073414 | ||
P275 | copyright license | Creative Commons Attribution 4.0 International | Q20007257 |
P6216 | copyright status | copyrighted | Q50423863 |
P4510 | describes a project that uses | ImageJ | Q1659584 |
P433 | issue | 3 | |
P407 | language of work or name | English | Q1860 |
P921 | main subject | Myosin heavy chain 7 | Q29832699 |
P304 | page(s) | e53 | |
P577 | publication date | 2007-03-01 | |
P1433 | published in | PLOS Biology | Q1771695 |
P1476 | title | Functional modulation of cardiac form through regionally confined cell shape changes | |
P478 | volume | 5 |
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Q36135276 | In vivo natriuretic peptide reporter assay identifies chemical modifiers of hypertrophic cardiomyopathy signalling |
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Q93073881 | Inhibition of Notch signaling rescues cardiovascular development in Kabuki Syndrome |
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