| scholarly article | Q13442814 |
| P2093 | author name string | Deborah Yelon | |
| Huai-Jen Tsai | |||
| Heather E Riley | |||
| Felix Olale | |||
| Hope Coleman | |||
| Heidi J Auman | |||
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| Cell-autonomous action of zebrafish spt-1 mutation in specific mesodermal precursors | Q41214829 | ||
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| Rapidly maturing variants of the Discosoma red fluorescent protein (DsRed). | Q43830777 | ||
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| 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 |
| Q27330243 | 4-Dimensional light-sheet microscopy to elucidate shear stress modulation of cardiac trabeculation |
| Q37873094 | A guide to analysis of cardiac phenotypes in the zebrafish embryo |
| Q45387331 | A method to quantify mechanobiologic forces during zebrafish cardiac development using 4-D light sheet imaging and computational modeling |
| Q30433963 | Absence of heartbeat in the Xenopus tropicalis mutation muzak is caused by a nonsense mutation in cardiac myosin myh6 |
| Q27310193 | Advanced echocardiography in adult zebrafish reveals delayed recovery of heart function after myocardial cryoinjury |
| Q47779836 | Analysis of heart valve development in larval zebrafish |
| Q30651967 | Analysis of postembryonic heart development and maturation in the zebrafish, Danio rerio |
| Q26865437 | Animal and in silico models for the study of sarcomeric cardiomyopathies |
| Q39139181 | Bending and twisting the embryonic heart: a computational model for c-looping based on realistic geometry |
| Q90068855 | Biomechanical signaling within the developing zebrafish heart attunes endocardial growth to myocardial chamber dimensions |
| Q30538292 | Calcium influx through L-type CaV1.2 Ca2+ channels regulates mandibular development |
| Q27302362 | Calcium signaling regulates ventricular hypertrophy during development independent of contraction or blood flow |
| Q30496345 | Cardiac conduction is required to preserve cardiac chamber morphology |
| Q36462525 | Cardiac contraction activates endocardial Notch signaling to modulate chamber maturation in zebrafish |
| Q47134002 | Cell-accurate optical mapping across the entire developing heart. |
| Q36465145 | Cerebellum morphogenesis: the foliation pattern is orchestrated by multi-cellular anchoring centers |
| Q30571404 | Cessation of contraction induces cardiomyocyte remodeling during zebrafish cardiogenesis |
| Q30500285 | Chromatin remodelling complex dosage modulates transcription factor function in heart development |
| Q35921775 | Clonally dominant cardiomyocytes direct heart morphogenesis |
| Q30606532 | Complex cardiac defects after ethanol exposure during discrete cardiogenic events in zebrafish: prevention with folic acid |
| Q27014904 | Concise review: growing hearts in the right place: on the design of biomimetic materials for cardiac stem cell differentiation |
| Q52311540 | Confocal micrographs: automated segmentation and quantitative shape analysis of neuronal cells treated with ostreolysin A/pleurotolysin B pore-forming complex. |
| Q27015114 | Connecting teratogen-induced congenital heart defects to neural crest cells and their effect on cardiac function |
| Q48172012 | Current Perspectives in Cardiac Laterality. |
| Q90239340 | Deep learning enables automated volumetric assessments of cardiac function in zebrafish |
| Q47073947 | Dependence of cardiac trabeculation on neuregulin signaling and blood flow in zebrafish |
| Q37300161 | Depletion of zebrafish essential and regulatory myosin light chains reduces cardiac function through distinct mechanisms |
| Q54957142 | Developmental temperature has persistent, sexually dimorphic effects on zebrafish cardiac anatomy. |
| Q34637646 | DiGeorge syndrome gene tbx1 functions through wnt11r to regulate heart looping and differentiation |
| Q37258930 | Differential requirement for BMP signaling in atrial and ventricular lineages establishes cardiac chamber proportionality |
| Q30497167 | Distinct troponin C isoform requirements in cardiac and skeletal muscle |
| Q42933089 | Efficient site-specific transgenesis and enhancer activity tests in medaka using PhiC31 integrase |
| Q36421781 | Electrical and mechanical stimulation of cardiac cells and tissue constructs. |
| Q44930254 | Epigenetic control of cardiomyocyte production in response to a stress during the medaka heart development |
| Q93079972 | Epigenetics and Mechanobiology in Heart Development and Congenital Heart Disease |
| Q37736438 | Epithelial tension in the second heart field promotes mouse heart tube elongation. |
| Q27313670 | Excessive nitrite affects zebrafish valvulogenesis through yielding too much NO signaling |
| Q35897454 | Exome analysis of a family with pleiotropic congenital heart disease. |
| Q91854113 | Fluid forces shape the embryonic heart: Insights from zebrafish |
| Q90679951 | Genetic and epigenetic regulation of cardiomyocytes in development, regeneration and disease |
| Q27333494 | Genetic and physiologic dissection of the vertebrate cardiac conduction system |
| Q37376719 | Geometric control of tissue morphogenesis |
| Q24635831 | Hadp1, a newly identified pleckstrin homology domain protein, is required for cardiac contractility in zebrafish |
| Q30541377 | Haemodynamically dependent valvulogenesis of zebrafish heart is mediated by flow-dependent expression of miR-21 |
| Q34107608 | Hand2 ensures an appropriate environment for cardiac fusion by limiting Fibronectin function |
| Q36287189 | Heart chamber size in zebrafish is regulated redundantly by duplicated tbx2 genes |
| Q38041426 | Heavy and light roles: myosin in the morphogenesis of the heart |
| Q34421441 | Hedgehog signaling plays a cell-autonomous role in maximizing cardiac developmental potential |
| Q30567136 | High-resolution imaging of cardiomyocyte behavior reveals two distinct steps in ventricular trabeculation |
| Q46058311 | High-resolution reconstruction of the beating zebrafish heart |
| Q36227102 | Identifying the evolutionary building blocks of the cardiac conduction system. |
| Q34132681 | Immunostaining of dissected zebrafish embryonic heart |
| Q37139540 | Impaired cardiovascular function caused by different stressors elicits a common pathological and transcriptional response in zebrafish embryos |
| Q36135276 | In vivo natriuretic peptide reporter assay identifies chemical modifiers of hypertrophic cardiomyopathy signalling |
| Q88716757 | Influence of blood flow on cardiac development |
| Q93073881 | Inhibition of Notch signaling rescues cardiovascular development in Kabuki Syndrome |
| Q26767303 | Interplay between cardiac function and heart development |
| Q34736495 | Intracardiac flow dynamics regulate atrioventricular valve morphogenesis |
| Q30494734 | Joint dynamic imaging of morphogenesis and function in the developing heart |
| Q26862578 | Mechanical regulation of cardiac development |
| Q37866169 | Mechanotransduction: the role of mechanical stress, myocyte shape, and cytoskeletal architecture on cardiac function |
| Q103017627 | Mef2c factors are required for early but not late addition of cardiomyocytes to the ventricle |
| Q38320233 | Molecular regulation of cardiomyocyte differentiation |
| Q38208920 | Morphomechanics: transforming tubes into organs |
| Q35758199 | Multiple influences of blood flow on cardiomyocyte hypertrophy in the embryonic zebrafish heart |
| Q37819523 | Myocardial lineage development |
| Q63681854 | Myosin Vb is required for correct trafficking of N‐cadherin and cardiac chamber ballooning |
| Q33639096 | Naturally Engineered Maturation of Cardiomyocytes |
| Q30559749 | Novel cardiovascular gene functions revealed via systematic phenotype prediction in zebrafish |
| Q45936448 | Nr2f1a balances atrial chamber and atrioventricular canal size via BMP signaling-independent and -dependent mechanisms. |
| Q34249070 | Overlapping and opposing functions of G protein-coupled receptor kinase 2 (GRK2) and GRK5 during heart development |
| Q36927034 | PCB126 exposure disrupts zebrafish ventricular and branchial but not early neural crest development. |
| Q41921217 | Pbx acts with Hand2 in early myocardial differentiation. |
| Q30492917 | Pdlim7 (LMP4) regulation of Tbx5 specifies zebrafish heart atrio-ventricular boundary and valve formation |
| Q55007691 | Planar cell polarity signalling coordinates heart tube remodelling through tissue-scale polarisation of actomyosin activity. |
| Q39015205 | Platelet-derived growth factor (PDGF) signaling directs cardiomyocyte movement toward the midline during heart tube assembly. |
| Q55259963 | Post-transcriptional Modulation of Sphingosine-1-Phosphate Receptor 1 by miR-19a Affects Cardiovascular Development in Zebrafish. |
| Q30839692 | Proteolysis regulates cardiomyocyte maturation and tissue integration |
| Q37036231 | Real-time 3D visualization of cellular rearrangements during cardiac valve formation |
| Q24304096 | Reduced ACTC1 Expression Might Play a Role in the Onset of Congenital Heart Disease by Inducing Cardiomyocyte Apoptosis |
| Q41089472 | Regulation of cardiomyocyte behavior in zebrafish trabeculation by Neuregulin 2a signaling |
| Q37362971 | Reiterative roles for FGF signaling in the establishment of size and proportion of the zebrafish heart |
| Q27325403 | Reversing blood flows act through klf2a to ensure normal valvulogenesis in the developing heart |
| Q39676931 | Strategies for analyzing cardiac phenotypes in the zebrafish embryo |
| Q34200680 | TCDD Induced Pericardial Edema and Relative COX-2 Expression in Medaka (Oryzias Latipes) Embryos |
| Q27306780 | Targeted laser ablation of the zebrafish larval heart induces models of heart block, valvular regurgitation, and outflow tract obstruction |
| Q42801306 | Tbx5-mediated expression of Ca(2+)/calmodulin-dependent protein kinase II is necessary for zebrafish cardiac and pectoral fin morphogenesis |
| Q102152450 | Tension heterogeneity directs form and fate to pattern the myocardial wall |
| Q41563000 | The Calcineurin-FoxO-MuRF1 signaling pathway regulates myofibril integrity in cardiomyocytes. |
| Q29618810 | The Tol2kit: a multisite gateway-based construction kit for Tol2 transposon transgenesis constructs |
| Q90163109 | The Transitional Heart: From Early Embryonic and Fetal Development to Neonatal Life |
| Q30583884 | The atypical Rho GTPase, RhoU, regulates cell-adhesion molecules during cardiac morphogenesis |
| Q37205924 | The contribution of cellular mechanotransduction to cardiomyocyte form and function |
| Q37089736 | The developmental genetics of congenital heart disease. |
| Q27302915 | The endoderm and myocardium join forces to drive early heart tube assembly |
| Q26770162 | The force within: endocardial development, mechanotransduction and signalling during cardiac morphogenesis |
| Q35342432 | The genomic and genetic toolbox of the teleost medaka (Oryzias latipes) |
| Q37791098 | The mechanics of development: Models and methods for tissue morphogenesis |
| Q37659191 | The zebrafish model system in cardiovascular research: A tiny fish with mighty prospects |
| Q99708106 | Tie1 regulates zebrafish cardiac morphogenesis through tolloid-like 1 expression |
| Q50458099 | Time-lapse imaging of cell cycle dynamics during development in living cardiomyocyte |
| Q33651020 | Tropomyosin is required for cardiac morphogenesis, myofibril assembly, and formation of adherens junctions in the developing mouse embryo |
| Q42390125 | Two developmentally distinct populations of neural crest cells contribute to the zebrafish heart |
| Q36452387 | Uncovering the Number and Clonal Dynamics of Mesp1 Progenitors during Heart Morphogenesis. |
| Q38043058 | Uncovering the molecular and cellular mechanisms of heart development using the zebrafish. |
| Q27024639 | Understanding cardiac sarcomere assembly with zebrafish genetics |
| Q47073802 | Voltage-gated calcium channel CACNB2 (β2.1) protein is required in the heart for control of cell proliferation and heart tube integrity |
| Q51867539 | Wnt signaling regulates atrioventricular canal formation upstream of BMP and Tbx2. |
| Q59134756 | Wnt/β-catenin signaling regulates VE-cadherin-mediated anastomosis of brain capillaries by counteracting S1pr1 signaling |
| Q24632619 | Wnt11 patterns a myocardial electrical gradient through regulation of the L-type Ca(2+) channel |
| Q37190836 | Wtip is required for proepicardial organ specification and cardiac left/right asymmetry in zebrafish |
| Q91675882 | Zebrafish Vestigial Like Family Member 4b Is Required for Valvulogenesis Through Sequestration of Transcription Factor Myocyte Enhancer Factor 2c |
| Q37878169 | Zebrafish as a model to study cardiac development and human cardiac disease |
| Q47073820 | Zebrafish cul4a, but not cul4b, modulates cardiac and forelimb development by upregulating tbx5a expression. |
| Q38019209 | Zebrafish models in cardiac development and congenital heart birth defects |
| Q30484543 | microRNA-138 modulates cardiac patterning during embryonic development. |
| Q36252345 | α-Actinin2 is required for the lateral alignment of Z discs and ventricular chamber enlargement during zebrafish cardiogenesis |
| Q34026936 | β-Lapachone induces heart morphogenetic and functional defects by promoting the death of erythrocytes and the endocardium in zebrafish embryos |
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