| scholarly article | Q13442814 |
| P2093 | author name string | Mikawa T | |
| Gourdie RG | |||
| P433 | issue | 2 | |
| P407 | language of work or name | English | Q1860 |
| P304 | page(s) | 221-232 | |
| P577 | publication date | 1996-03-01 | |
| P1433 | published in | Developmental Biology | Q3025402 |
| P1476 | title | Pericardial mesoderm generates a population of coronary smooth muscle cells migrating into the heart along with ingrowth of the epicardial organ | |
| P478 | volume | 174 |
| Q40850437 | 1 Homeobox Genes in Cardiovascular Development |
| Q92525212 | A Light Wand to Untangle the Myocardial Cell Network |
| Q35770072 | A comparison of stent-induced stenosis in coronary and peripheral arteries |
| Q41213731 | A myocardial lineage derives from Tbx18 epicardial cells |
| Q24292823 | A role for Tbx5 in proepicardial cell migration during cardiogenesis |
| Q40021958 | A serum response factor-dependent transcriptional regulatory program identifies distinct smooth muscle cell sublineages |
| Q28587312 | Ablation of specific expression domains reveals discrete functions of ectoderm- and endoderm-derived FGF8 during cardiovascular and pharyngeal development |
| Q34876665 | Accelerated coronary angiogenesis by vegfr1-knockout endocardial cells |
| Q42096169 | Altered hypoxia-inducible factor-1 alpha expression levels correlate with coronary vessel anomalies |
| Q42734016 | Analysis of the proepicardium-epicardium transition during the malformation of the RXRalpha-/- epicardium |
| Q93089068 | Application of Bioengineered Materials in the Surgical Management of Heart Failure |
| Q38533062 | Application of Small Organic Molecules Reveals Cooperative TGFβ and BMP Regulation of Mesothelial Cell Behaviors |
| Q42504346 | Arterial pole progenitors interpret opposing FGF/BMP signals to proliferate or differentiate. |
| Q49346823 | Arterial smooth muscle dynamics in development and repair |
| Q34920997 | Autotaxin signaling governs phenotypic heterogeneity in visceral and parietal mesothelia |
| Q48143993 | Avian embryonic coronary arterio-venous pattering involves the contribution of different endothelial and endocardial cell populations. |
| Q52018698 | BMP is an important regulator of proepicardial identity in the chick embryo |
| Q37850773 | BMP signaling in congenital heart disease: New developments and future directions |
| Q30496194 | BMP signals promote proepicardial protrusion necessary for recruitment of coronary vessel and epicardial progenitors to the heart |
| Q35990091 | Basics of cardiac development for the understanding of congenital heart malformations |
| Q37307320 | Brothers and sisters: molecular insights into arterial-venous heterogeneity |
| Q33745199 | CDC42 is required for epicardial and pro-epicardial development by mediating FGF receptor trafficking to the plasma membrane |
| Q38846401 | Can heart function lost to disease be regenerated by therapeutic targeting of cardiac scar tissue? |
| Q28507663 | Capsulin: a novel bHLH transcription factor expressed in epicardial progenitors and mesenchyme of visceral organs |
| Q38863047 | Cardiac Fibroblast Activation Post-Myocardial Infarction: Current Knowledge Gaps |
| Q92752512 | Cardiac Fibroblasts and the Extracellular Matrix in Regenerative and Nonregenerative Hearts |
| Q36708340 | Cardiac Fibrosis: The Fibroblast Awakens |
| Q52187531 | Cardiac and Extracardiac Expression of Csx/Nkx2.5 Homeodomain Protein |
| Q35541868 | Cardiac chamber formation: development, genes, and evolution. |
| Q35035923 | Cardiac endothelial-myocardial signaling: its role in cardiac growth, contractile performance, and rhythmicity |
| Q35883291 | Cardiac fibroblasts: from development to heart failure. |
| Q88022109 | Cardiac fibroblasts: from origin to injury |
| Q34643788 | Cardiac regenerative capacity and mechanisms |
| Q36083465 | Cell biology of cardiac cushion development. |
| Q36141876 | Cellular and molecular mechanisms of coronary vessel development |
| Q39093253 | Cellular plasticity in cardiovascular development and disease |
| Q35026817 | Cellular precursors of the coronary arteries |
| Q41649812 | Chapter 10 The Use of Replication--Defective Retroviruses for Cell Lineage Studies of Myogenic Cells |
| Q54506625 | Chapter 9. Development of coronary vessels. |
| Q30489784 | Characterization of vascular mural cells during zebrafish development |
| Q47807069 | Cloning and expression analysis of the mouse T-box gene Tbx18. |
| Q28505293 | Cloning of capsulin, a basic helix-loop-helix factor expressed in progenitor cells of the pericardium and the coronary arteries |
| Q37836311 | Communication Signals Between Cardiac Fibroblasts and Cardiac Myocytes |
| Q36331213 | Comprehensive timeline of mesodermal development in the quail small intestine |
| Q30568774 | Concurrent generation of functional smooth muscle and endothelial cells via a vascular progenitor |
| Q38711945 | Congenital coronary artery anomalies: a bridge from embryology to anatomy and pathophysiology--a position statement of the development, anatomy, and pathology ESC Working Group. |
| Q39512464 | Connection of Pericyte–Angiopoietin-Tie-2 System In Diabetic Retinopathy: Friend Or Foe? |
| Q30489677 | Connexin 43 regulates epicardial cell polarity and migration in coronary vascular development |
| Q52043546 | Connexin43 deficiency causes dysregulation of coronary vasculogenesis |
| Q26822995 | Coordinating Tissue Interactions: Notch Signaling in Cardiac Development and Disease |
| Q33909846 | Coronary Artery Development: Progenitor Cells and Differentiation Pathways |
| Q60951774 | Coronary Vasculature in Cardiac Development and Regeneration |
| Q42530831 | Coronary arteries form by developmental reprogramming of venous cells |
| Q35026824 | Coronary arteriogenesis and differentiation of periarterial Purkinje fibers in the chick heart: is there a link? |
| Q35048311 | Coronary artery endothelial transcriptome in vivo: identification of endoplasmic reticulum stress and enhanced reactive oxygen species by gene connectivity network analysis |
| Q45901128 | Coronary development is regulated by ATP-dependent SWI/SNF chromatin remodeling component BAF180. |
| Q38825014 | Coronary endothelial proliferation and morphogenesis are regulated by a VEGF-mediated pathway. |
| Q37534988 | Coronary vessel development and insight towards neovascular therapy. |
| Q28507412 | Coronary vessel development requires activation of the TrkB neurotrophin receptor by the Wilms' tumor transcription factor Wt1. |
| Q64905070 | Covering and Re-Covering the Heart: Development and Regeneration of the Epicardium. |
| Q36517012 | Crim1 has cell-autonomous and paracrine roles during embryonic heart development |
| Q28506549 | Defective smooth muscle development in qkI-deficient mice |
| Q38982080 | Defining the Cardiac Fibroblast |
| Q34353382 | Development and evolution of the pharyngeal apparatus |
| Q35937605 | Development of coronary vessels |
| Q82072440 | Development of lymphatic vessels in mouse embryonic and early postnatal hearts |
| Q34810697 | Development of the coronary blood supply: changing concepts and current ideas |
| Q46799857 | Development of the proepicardial organ in the zebrafish |
| Q48743572 | Development of the proepicardium in Xenopus laevis |
| Q36470490 | Developmental Progression of the Coronary Vasculature in Human Embryos and Fetuses |
| Q44030128 | Developmental remodeling and shortening of the cardiac outflow tract involves myocyte programmed cell death |
| Q37359133 | Differential expression of embryonic epicardial progenitor markers and localization of cardiac fibrosis in adult ischemic injury and hypertensive heart disease |
| Q80145787 | Differential growth and multicellular villi direct proepicardial translocation to the developing mouse heart |
| Q35855618 | Differentiation and diversification of vascular cells from embryonic stem cells |
| Q35895038 | Differentiation of Human Induced-Pluripotent Stem Cells into Smooth-Muscle Cells: Two Novel Protocols |
| Q42429806 | Dissecting the Role of Human Embryonic Stem Cell–Derived Mesenchymal Cells in Human Umbilical Vein Endothelial Cell Network Stabilization in Three-Dimensional Environments |
| Q34261674 | Distinct compartments of the proepicardial organ give rise to coronary vascular endothelial cells |
| Q55280396 | Dynamic Cellular Integration Drives Functional Assembly of the Heart's Pacemaker Complex. |
| Q30669534 | EGF-induced adipose tissue mesothelial cells undergo functional vascular smooth muscle differentiation |
| Q44558883 | Effects of insulin-like growth factor-I on cultured human coronary artery smooth muscle cells |
| Q92639261 | Embryonic Chicken (Gallus gallus domesticus) as a Model of Cardiac Biology and Development |
| Q33651561 | Embryonic origins of human vascular smooth muscle cells: implications for in vitro modeling and clinical application |
| Q26830155 | Endocardial and Epicardial Epithelial to Mesenchymal Transitions in Heart Development and Disease |
| Q84167464 | Endocardial cells are a distinct endothelial lineage derived from Flk1+ multipotent cardiovascular progenitors |
| Q42361373 | Endocardial cells form the coronary arteries by angiogenesis through myocardial-endocardial VEGF signaling |
| Q37235964 | Endothelial cell lineages of the heart |
| Q33345585 | Endothelial-specific ablation of serum response factor causes hemorrhaging, yolk sac vascular failure, and embryonic lethality |
| Q36490548 | Endothelin-induced conversion of embryonic heart muscle cells into impulse-conducting Purkinje fibers |
| Q37656165 | Epicardial GATA factors regulate early coronary vascular plexus formation |
| Q53785255 | Epicardial Outgrowth Culture Assay and Ex Vivo Assessment of Epicardial-derived Cell Migration |
| Q38015278 | Epicardial Progenitor Cells in Cardiac Development and Regeneration |
| Q30355193 | Epicardial YAP/TAZ orchestrate an immunosuppressive response following myocardial infarction |
| Q52006616 | Epicardial development in the rat: a new perspective |
| Q43593323 | Epicardial progenitor cells in cardiac regeneration and neovascularisation |
| Q36952843 | Epicardial progenitors contribute to the cardiomyocyte lineage in the developing heart. |
| Q42137346 | Epicardial-derived cell epithelial-to-mesenchymal transition and fate specification require PDGF receptor signaling. |
| Q52106623 | Epicardial-like cells on the distal arterial end of the cardiac outflow tract do not derive from the proepicardium but are derivatives of the cephalic pericardium |
| Q24303956 | Epicardial-myocardial signaling directing coronary vasculogenesis |
| Q52099714 | Epicardium is required for the full rate of myocyte proliferation and levels of expression of myocyte mitogenic factors FGF2 and its receptor, FGFR-1, but not for transmural myocardial patterning in the embryonic chick heart |
| Q41035429 | Epicardium-Derived Cells Contribute a Novel Population to the Myocardial Wall and the Atrioventricular Cushions |
| Q36767594 | Epicardium-derived cells in cardiogenesis and cardiac regeneration |
| Q38603614 | Epicardium-derived fibroblasts in heart development and disease. |
| Q26853290 | Epigenetic mechanisms in cardiac development and disease |
| Q28388587 | Epithelial-mesenchymal transition in tissue repair and fibrosis |
| Q35906030 | Epithelial-to-mesenchymal and endothelial-to-mesenchymal transition: from cardiovascular development to disease. |
| Q50493507 | Evidence for an extracellular matrix bridge guiding proepicardial cell migration to the myocardium of chick embryos |
| Q27312471 | Evolution and development of ventricular septation in the amniote heart |
| Q48745106 | Experimental analyses of the function of the proepicardium using a new microsurgical procedure to induce loss-of-proepicardial-function in chick embryos |
| Q52114634 | Expression of Peg1 (Mest) in the developing mouse heart: involvement in trabeculation |
| Q42256650 | Expression of active Notch1 in avian coronary development |
| Q36713695 | Expression of lymphatic markers during avian and mouse cardiogenesis |
| Q42136235 | Ezh2 restricts the smooth muscle lineage during mouse lung mesothelial development. |
| Q35530095 | FGF10 Signaling Enhances Epicardial Cell Expansion during Neonatal Mouse Heart Repair |
| Q30502384 | FGF10/FGFR2b signaling is essential for cardiac fibroblast development and growth of the myocardium |
| Q42008716 | FGFR-1 is required by epicardium-derived cells for myocardial invasion and correct coronary vascular lineage differentiation |
| Q73205746 | Fate diversity of primitive streak cells during heart field formation in ovo |
| Q28511544 | Fibroblast growth factor signals regulate a wave of Hedgehog activation that is essential for coronary vascular development |
| Q37255246 | Fibroblast-myocyte coupling in the heart: Potential relevance for therapeutic interventions |
| Q37725769 | Fibroblast-myocyte electrotonic coupling: does it occur in native cardiac tissue? |
| Q74381823 | Fibulin-2 expression marks transformed mesenchymal cells in developing cardiac valves, aortic arch vessels, and coronary vessels |
| Q59081200 | Flk1-positive cells derived from embryonic stem cells serve as vascular progenitors |
| Q46506953 | Formation and remodeling of the coronary vascular bed in the embryonic avian heart. |
| Q34935524 | From fish to amphibians to mammals: in search of novel strategies to optimize cardiac regeneration |
| Q89831508 | Functional Heterogeneity within the Developing Zebrafish Epicardium |
| Q64052028 | Functional cardiac fibroblasts derived from human pluripotent stem cells via second heart field progenitors |
| Q27317274 | Functional vascular smooth muscle-like cells derived from adult mouse uterine mesothelial cells |
| Q26746940 | Functions of miRNAs during Mammalian Heart Development |
| Q33346498 | GATA4/FOG2 transcriptional complex regulates Lhx9 gene expression in murine heart development |
| Q90241286 | GFAP (Glial Fibrillary Acidic Protein)-Positive Progenitor Cells Contribute to the Development of Vascular Smooth Muscle Cells and Endothelial Cells |
| Q35737818 | Generation of human vascular smooth muscle subtypes provides insight into embryological origin-dependent disease susceptibility |
| Q28392538 | Genetic tools for identifying and manipulating fibroblasts in the mouse |
| Q50066251 | Harnessing Epicardial Progenitor Cells and Their Derivatives for Rescue and Repair of Cardiac Tissue After Myocardial Infarction |
| Q27001686 | Heart repair and regeneration: Recent insights from zebrafish studies |
| Q43119202 | Hedgehog signaling to distinct cell types differentially regulates coronary artery and vein development |
| Q36021595 | Hematopoietic progenitors are required for proper development of coronary vasculature |
| Q93120633 | Heterogeneity of Adult Cardiac Stem Cells |
| Q41523862 | Hilum of the heart |
| Q36913611 | Hippo Signaling Mediators Yap and Taz Are Required in the Epicardium for Coronary Vasculature Development |
| Q37911584 | Human embryonic stem cell-derived vascular smooth muscle cells in therapeutic neovascularisation |
| Q35841951 | Human epicardium: ultrastructural ancestry of mesothelium and mesenchymal cells |
| Q52771103 | Human pluripotent stem cell-derived epicardial progenitors can differentiate to endocardial-like endothelial cells |
| Q44859259 | Hypoglycemia induced changes in cell death and cell proliferation in the organogenesis stage embryonic mouse heart |
| Q52589939 | Hypoxia Supports Epicardial Cell Differentiation in Vascular Smooth Muscle Cells through the Activation of the TGFβ Pathway |
| Q30540730 | Identification and prospective isolation of a mesothelial precursor lineage giving rise to smooth muscle cells and fibroblasts for mammalian internal organs, and their vasculature |
| Q34145728 | Identification of Thymosin β4 as an effector of Hand1-mediated vascular development. |
| Q47855025 | Identification of a CArG-independent region of the cysteine-rich protein 2 promoter that directs expression in the developing vasculature |
| Q36111002 | Identification of a novel developmental mechanism in the generation of mesothelia |
| Q77741974 | Immunolocalization of the vascular endothelial growth factor receptor-2 in the subepicardial mesenchyme of hamster embryos: identification of the coronary vessel precursors |
| Q37998444 | Importance of Myocyte-Nonmyocyte Interactions in Cardiac Development and Disease |
| Q55401713 | In Vitro Culture of Epicardial Cells From Mouse Embryonic Heart. |
| Q82462288 | In vivo and in vitro analysis of the vasculogenic potential of avian proepicardial and epicardial cells |
| Q26853054 | Induced pluripotent stem cell-derived vascular smooth muscle cells: methods and application |
| Q36668306 | Induction of Purkinje fiber differentiation by coronary arterialization |
| Q38129884 | Induction of the Proepicardium |
| Q45258552 | Inhibition of α4-integrin stimulates epicardial–mesenchymal transformation and alters migration and cell fate of epicardially derived mesenchyme |
| Q77841325 | Initiation of apoptosis in the developing avian outflow tract myocardium |
| Q39709619 | Insights into coronary artery development in model of maternal protein restriction in mice. |
| Q47969185 | Interleukin-10 Inhibits Bone Marrow Fibroblast Progenitor Cell-Mediated Cardiac Fibrosis in Pressure-Overloaded Myocardium |
| Q43243916 | Islet 1 is expressed in distinct cardiovascular lineages, including pacemaker and coronary vascular cells |
| Q54679955 | Isolation and characterization of multipotent progenitor cells from the human fetal aorta wall. |
| Q33668497 | Isolation and culture of mouse proepicardium using serum-free conditions |
| Q50529157 | Kicking the Epicardium Up a Notch |
| Q30480448 | LMP4 regulates Tbx5 protein subcellular localization and activity |
| Q36038172 | Lack of Genetic Interaction between Tbx18 and Tbx2/Tbx20 in Mouse Epicardial Development |
| Q37971729 | Life is a pattern: vascular assembly within the embryo |
| Q91586255 | Limited Regeneration Potential with Minimal Epicardial Progenitor Conversions in the Neonatal Mouse Heart after Injury |
| Q51906492 | Lineage tracing of epicardial cells during development and regeneration |
| Q34193595 | Mab21l2 Is Essential for Embryonic Heart and Liver Development |
| Q37865969 | Mechanisms of T-box gene function in the developing heart |
| Q37522618 | Mechanisms simultaneously regulate smooth muscle proliferation and differentiation |
| Q34207057 | Membrane topology of Bves/Pop1A, a cell adhesion molecule that displays dynamic changes in cellular distribution during development |
| Q36938543 | Mesothelium contributes to vascular smooth muscle and mesenchyme during lung development. |
| Q35562519 | MicroRNA-processing enzyme Dicer is required in epicardium for coronary vasculature development |
| Q39308903 | More than Just a Simple Cardiac Envelope; Cellular Contributions of the Epicardium |
| Q37383073 | Mouse models of congenital cardiovascular disease |
| Q92922799 | Multi-cellularity in cardiac tissue engineering, how close are we to native heart tissue? |
| Q33723035 | Multiple modes of proepicardial cell migration require heartbeat |
| Q37819523 | Myocardial Lineage Development |
| Q33853829 | Myocardial regeneration: expanding the repertoire of thymosin β4 in the ischemic heart |
| Q34985191 | Myocardin-related transcription factors control the motility of epicardium-derived cells and the maturation of coronary vessels |
| Q82940227 | Myocyte-fibroblast electrical coupling: the basis of a stable relationship? |
| Q27692541 | Myofibroblasts: trust your heart and let fate decide. |
| Q38085110 | New Insights into the Developmental Mechanisms of Coronary Vessels and Epicardium |
| Q36497186 | New approaches under development: cardiovascular embryology applied to heart disease. |
| Q82745736 | New morphological aspects of blood islands formation in the embryonic mouse hearts |
| Q35944775 | Nf1 limits epicardial derivative expansion by regulating epithelial to mesenchymal transition and proliferation |
| Q37618967 | Nkx2-5 lineage tracing visualizes the distribution of second heart field-derived aortic smooth muscle |
| Q28590420 | Nkx2-5- and Isl1-expressing cardiac progenitors contribute to proepicardium |
| Q82148954 | No muscle for a damaged heart: Thymosin beta 4 treatment after myocardial infarction does not induce myocardial differentiation of epicardial cells |
| Q33693863 | Non-autonomous modulation of heart rhythm, contractility and morphology in adult fruit flies. |
| Q81446261 | Normal patterning of the coronary capillary plexus is dependent on the correct transmural gradient of FGF expression in the myocardium |
| Q54618721 | Notch Signaling Regulates Smooth Muscle Differentiation of Epicardium-Derived Cells |
| Q38853720 | Notch signalling in ventricular chamber development and cardiomyopathy. |
| Q34531894 | Novel therapeutic strategies targeting fibroblasts and fibrosis in heart disease |
| Q36108192 | Numb family proteins: novel players in cardiac morphogenesis and cardiac progenitor cell differentiation |
| Q53822427 | Optical Electrophysiology in the Developing Heart. |
| Q37628341 | Origin of cardiac fibroblasts and the role of periostin |
| Q37716879 | Origin, development, and differentiation of cardiac fibroblasts |
| Q54223294 | Origins of cardiac fibroblasts. |
| Q34617481 | Oxygen-Dependent Gene Expression in Development and Cancer: Lessons Learned from the Wilms' Tumor Gene, WT1 |
| Q34182901 | PDGF signaling is required for epicardial function and blood vessel formation in regenerating zebrafish hearts |
| Q47128640 | Pathophysiology and therapeutic potential of cardiac fibrosis |
| Q36506011 | Pericytes are progenitors for coronary artery smooth muscle |
| Q49544674 | Pericytes: The Role of Multipotent Stem Cells in Vascular Maintenance and Regenerative Medicine |
| Q42114294 | Platelet-derived growth factor receptor beta signaling is required for efficient epicardial cell migration and development of two distinct coronary vascular smooth muscle cell populations |
| Q42757117 | Platelet-derived growth factor receptors direct vascular development independent of vascular smooth muscle cell function. |
| Q81881777 | Platelet-derived growth factors in the developing avian heart and maturating coronary vasculature |
| Q28396403 | Pleural mesothelial cells in pleural and lung diseases |
| Q37256433 | Pluripotent stem cell models of human heart disease |
| Q36148533 | Pod1/Tcf21 is regulated by retinoic acid signaling and inhibits differentiation of epicardium-derived cells into smooth muscle in the developing heart. |
| Q61207209 | Preotic neural crest cells contribute to coronary artery smooth muscle involving endothelin signalling |
| Q80535500 | Primary and immortalized mouse epicardial cells undergo differentiation in response to TGFbeta |
| Q48040213 | Prolyl-4-hydroxylase 2 and 3 coregulate murine erythropoietin in brain pericytes |
| Q39012408 | Prospects for improving neovascularization of the ischemic heart: Lessons from development |
| Q84781580 | Rare coronary anastomoses between the aorta, pulmonary trunk, left coronary artery, and subclavian artery |
| Q36785331 | Rebuilding the coronary vasculature: hedgehog as a new candidate for pharmacologic revascularization. |
| Q49239010 | Recapitulation of developmental mechanisms to revascularize the ischemic heart |
| Q91843151 | Recent insights on the role and regulation of retinoic acid signaling during epicardial development |
| Q39258331 | Redefining the identity of cardiac fibroblasts. |
| Q36178498 | Reference guide to the stages of chick heart embryology |
| Q28767450 | Relations and interactions between cranial mesoderm and neural crest populations |
| Q83389927 | Remodeling of aortic smooth muscle during avian embryonic development |
| Q88219954 | Reprogramming the Endocardium: Trials and Tribulations |
| Q33808347 | Resident fibroblast lineages mediate pressure overload-induced cardiac fibrosis |
| Q52193706 | Retroviral techniques for studying organogenesis with a focus on heart development |
| Q83200048 | Retroviral vectors to study cardiovascular development |
| Q45815042 | Role of fibroblast growth factor signaling during proepicardium formation in the chick embryo |
| Q35026820 | Role of growth factors in coronary morphogenesis. |
| Q35973553 | Roles of JUMONJI in mouse embryonic development |
| Q51978819 | Sclerotomal origin of smooth muscle cells in the wall of the avian dorsal aorta |
| Q80646839 | Sclerotomal origin of vascular smooth muscle cells and pericytes in the embryo |
| Q39999179 | Serosal mesothelium retains vasculogenic potential. |
| Q37707814 | Sfrp5 identifies murine cardiac progenitors for all myocardial structures except for the right ventricle. |
| Q37380465 | Shared circuitry: developmental signaling cascades regulate both embryonic and adult coronary vasculature |
| Q36724285 | Signals from both sides: Control of cardiac development by the endocardium and epicardium |
| Q38946672 | Skeletal and cardiac muscle pericytes: Functions and therapeutic potential |
| Q38596550 | Smooth Muscle Cell Differentiation: Model Systems, Regulatory Mechanisms, and Vascular Diseases |
| Q35678533 | Somatic transgenesis using retroviral vectors in the chicken embryo |
| Q34251249 | Sorting out where fibroblasts come from. |
| Q42548151 | Spatial and temporal regulation of coronary vessel formation by calcineurin-NFAT signaling |
| Q82184183 | Spatial relations between avian craniofacial neural crest and paraxial mesoderm cells |
| Q77846924 | Special communicationthe critical role of mechanical forces in blood vessel development, physiology and pathology |
| Q37665063 | Stem cell-mediated neovascularization in heart repair |
| Q37844965 | Target cell movement in tumor and cardiovascular diseases based on the epithelial–mesenchymal transition concept |
| Q48000607 | Tbx18 and the fate of epicardial progenitors |
| Q33942656 | Tbx5 and Bmp signaling are essential for proepicardium specification in zebrafish |
| Q36503371 | Tbx5 is required for avian and Mammalian epicardial formation and coronary vasculogenesis |
| Q36842821 | Tcf21 regulates the specification and maturation of proepicardial cells |
| Q27027610 | Tenascin-C in development and disease of blood vessels |
| Q26830787 | The Dynamic Role of Cardiac Fibroblasts in Development and Disease |
| Q48621270 | The Early Stages of Heart Development: Insights from Chicken Embryos |
| Q36744048 | The Lhx9-integrin pathway is essential for positioning of the proepicardial organ |
| Q36535178 | The Living Scar--Cardiac Fibroblasts and the Injured Heart |
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| Q87829005 | The TGFβ superfamily in cardiac dysfunction |
| Q34273888 | The bHLH transcription factor Tcf21 is required for lineage-specific EMT of cardiac fibroblast progenitors. |
| Q38166731 | The cardiac hypoxic niche: emerging role of hypoxic microenvironment in cardiac progenitors |
| Q37945458 | The cardiogenic niche as a fundamental building block of engineered myocardium |
| Q35243583 | The cytoplasmic domain of TGFβR3 through its interaction with the scaffolding protein, GIPC, directs epicardial cell behavior |
| Q35618207 | The epicardium and epicardially derived cells (EPDCs) as cardiac stem cells |
| Q37687321 | The epicardium as a candidate for heart regeneration. |
| Q89295292 | The epicardium as a hub for heart regeneration |
| Q50551462 | The epicardium as modulator of the cardiac autonomic response during early development. |
| Q37799410 | The epicardium in cardiac repair: From the stem cell view |
| Q38220618 | The epicardium signals the way towards heart regeneration |
| Q84080482 | The hypoxic epicardial and subepicardial microenvironment |
| Q35745263 | The identification of different endothelial cell populations within the mouse proepicardium |
| Q36884662 | The origin and arrhythmogenic potential of fibroblasts in cardiac disease |
| Q28391520 | The pleural mesothelium in development and disease |
| Q42510105 | The proepicardium delivers hemangioblasts but not lymphangioblasts to the developing heart |
| Q27687858 | The role of serum response factor in early coronary vasculogenesis |
| Q34999427 | The small molecule Wnt signaling modulator ICG-001 improves contractile function in chronically infarcted rat myocardium |
| Q38013063 | Thymosin β4 and Cardiac Regeneration: Are We Missing a Beat? |
| Q39540256 | Thymosin β4 mobilizes mesothelial cells for blood vessel repair. |
| Q33569963 | Tissue Myeloid Progenitors Differentiate into Pericytes through TGF-β Signaling in Developing Skin Vasculature |
| Q89582170 | Tissue Specific Origin, Development, and Pathological Perspectives of Pericytes |
| Q39007418 | Transcriptional Control of Cell Lineage Development in Epicardium-Derived Cells. |
| Q28212211 | Transcriptional activation of BMP-4 and regulation of mammalian organogenesis by GATA-4 and -6 |
| Q36609712 | Transcriptional control of cardiac fibroblast plasticity |
| Q34173691 | Transcriptional programs regulating vascular smooth muscle cell development and differentiation. |
| Q46782583 | Transforming growth factor-beta induces loss of epithelial character and smooth muscle cell differentiation in epicardial cells |
| Q35177514 | Transforming growth factor-beta stimulates epithelial-mesenchymal transformation in the proepicardium |
| Q33715016 | Transitions in cell organization and in expression of contractile and extracellular matrix proteins during development of chicken aortic smooth muscle: evidence for a complex spatial and temporal differentiationprogram |
| Q44770910 | Transplantation-induced functional/morphological changes in rat aorta allografts differ from those in arteries of rat kidney allografts |
| Q21999269 | Type-1 pericytes accumulate after tissue injury and produce collagen in an organ-dependent manner |
| Q38116924 | Understanding vascular development |
| Q34497421 | Upk3b is dispensable for development and integrity of urothelium and mesothelium |
| Q38672297 | Vascular smooth muscle cell differentiation from human stem/progenitor cells. |
| Q93053742 | Vascular smooth muscle cells in atherosclerosis |
| Q35095423 | Vascular smooth muscle diversity: insights from developmental biology |
| Q37833832 | Vascularizing the heart |
| Q38000154 | Why are the intramyocardial portions of the coronary arteries spared from arteriosclerosis? Clinical implications |
| Q38659755 | Wnt signaling in the heart fields: Variations on a common theme |
| Q50801972 | Wt1 and Epicardial Fate Mapping |
| Q37190836 | Wtip is required for proepicardial organ specification and cardiac left/right asymmetry in zebrafish |
| Q50569796 | Zebrafish cardiac enhancer trap lines: new tools for in vivo studies of cardiovascular development and disease |
| Q48024565 | epicardin: A novel basic helix-loop-helix transcription factor gene expressed in epicardium, branchial arch myoblasts, and mesenchyme of developing lung, gut, kidney, and gonads |
| Q42766102 | tcf21+ epicardial cells adopt non-myocardial fates during zebrafish heart development and regeneration |
| Q53620505 | α5 and αv integrins cooperate to regulate vascular smooth muscle and neural crest functions in vivo |
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