Cardiac/Heart Organoids
-
ISoOR is a leading resource for the latest information on cardiac organoids, providing researchers with essential insights into this vital area of study. The organization frequently hosts conferences focused on cardiac organoids research, encouraging collaboration and knowledge sharing among experts. Additionally, ISoOR features Research Highlights that summarize key findings and breakthroughs, ensuring the scientific community stays updated about advancements in cardiac organoid technology.
Research Highlights
Blood-Generating Heart-Forming Organoids Recapitulate Co-Development of the Human Haematopoietic System and the Embryonic Heart
Heart-Forming Organoids Mimic Human Blood System Development
Cardiac/heart organoids
Modelling Myocardial Ischemia/Reperfusion Injury with Inflammatory Response in Human Ventricular Cardiac Organoids
Cardiac Organoids Simulate Myocardial I/R Injury and Inflammatory Cascades
Cardiac/Heart Organoids
De Novo Design of Miniprotein Antagonists of Cytokine Storm Inducers
Miniprotein Antagonists Mitigate Cytokine Storm in Human Cardiac Organoids
Cardiac Organoids
Efficient and Reproducible Generation of Human iPSC-Derived Cardiomyocytes and Cardiac Organoids in Stirred Suspension Systems
[Nature Communications] Suspension Culture for High-Yield iPSC Cardiac Cells and Organoids.
Cardiac/Heart Organoids
Proposal for Considerations During Human iPSC-Derived Cardiac Organoid Generation for Cardiotoxicity Drug Testing
[Biomedicine & Pharmacotherapy] The Essential Role of Cardiac Organoids in Drug Development and Basic Research.
Cardiac Organoids
MSC-Derived Small Extracellular Vesicles Exert Cardioprotective Effect Through Reducing VLCFAs and Apoptosis in Human Cardiac Organoid IRI Model
[Stem Cells] The Ventricular Organoids Unveil the Mechanistic Role of sEVs in Alleviating IRI.
Cardiac Organoids
A Patterned Human Primitive Heart Organoid Model Generated by Pluripotent Stem Cell Self-Organization
[Nature Communication] Exploring Self-Organization in Pluripotent Stem Cells: Generation and Characterization of a Patterned Human Primitive Heart Organoid Model.
Cardiac/Heart Organoids
Modeling Cardiac Fibroblast Heterogeneity from Human Pluripotent Stem Cell-Derived Epicardial Cells
[Nature Communication] Deciphering the Spectrum of Cardiac Fibroblast Heterogeneity: A Comprehensive Modeling Approach Utilizing Human Pluripotent Stem Cell-Derived Epicardial Cells.
Cardiac/Heart Organoids
HOPX-Associated Molecular Programs Control Cardiomyocyte Cell States Underpinning Cardiac Structure and Function
[Developmental Cell] Deciphering the Regulatory Landscape: HOPX-Associated Molecular Programs Steering Cardiomyocyte Cell States in Support of Cardiac Structure and Function.
For more information about patient derived organoids and organoid conference 2024, please feel free to contact us!
