Journal
/
Bio-ingénierie
/
Creating a Structurally Realistic Finite Element Geometric Model of a Cardiomyocyte to Study the Role of Cellular Architecture in Cardiomyocyte Systems Biology
Journal JoVE
Bio-ingénierie
Un abonnement à JoVE est nécessaire pour voir ce contenu.  Connectez-vous ou commencez votre essai gratuit.
Journal JoVE Bio-ingénierie
Creating a Structurally Realistic Finite Element Geometric Model of a Cardiomyocyte to Study the Role of Cellular Architecture in Cardiomyocyte Systems Biology

Creating a Structurally Realistic Finite Element Geometric Model of a Cardiomyocyte to Study the Role of Cellular Architecture in Cardiomyocyte Systems Biology

DOI:
10.3791/56817-v

08:54 min

April 18, 2018

, , , , , , ,
1Cell Structure and Mechanobiology Group,University of Melbourne, 2Systems Biology Laboratory, Melbourne School of Engineering,University of Melbourne, 3Department of Biomedical Engineering,University of Melbourne, 4School of Mathematics and Statistics, Faculty of Science,University of Melbourne, 5Department of Engineering Science,University of Auckland, 6Advanced Microscopy Facility, Bio21 Molecular Science and Biotechnology Institute,University of Melbourne, 7ARC Centre of Excellence in Convergent Bio-Nano Science and Technology,University of Melbourne, 8School of Medicine, Faculty of Medicine, Dentistry and Health Sciences,University of Melbourne, 9Living Systems Institute,University of Exeter

Chapitres

  • 00:04Titre
  • 01:19Segment Myofibrils and Mitochondria Regions from the EM 3D Image Dataset
  • 03:05Create a Finite Element Mesh from the Segmented Components
  • 04:36Mathematically Map the Spatially Varying Density of Ion-channels of Interest onto the Finite Element Mesh
  • 06:51Results: A Structurally Realistic Finite Element Geometric Model of a Cardiomyocyte
  • 08:13Conclusion

Summary

Traduction automatique

Traduction automatique

This protocol outlines a novel method to create a spatially detailed finite element model of the intracellular architecture of cardiomyocytes from electron microscopy and confocal microscopy images. The power of this spatially detailed model is demonstrated using case studies in calcium signaling and bioenergetics.

Tags

Finite Element ModelCardiomyocyteCellular ArchitectureCardiac Cell Systems BiologyElectron MicroscopyConfocal MicroscopyIMOD3D ReconstructionMitochondriaContourObject Modeling

Article

Embed

AJOUTER À LA PLAYLIST

Usage Statistics

Vidéos Connexes

check_url/fr/56817?article_type=v

The Three-Dimensional Human Skin Reconstruct Model: a Tool to Study Normal Skin and Melanoma Progression
check_url/fr/56817?article_type=v

Creating Two-Dimensional Patterned Substrates for Protein and Cell Confinement
check_url/fr/56817?article_type=v

Design of a Cyclic Pressure Bioreactor for the Ex Vivo Study of Aortic Heart Valves
check_url/fr/56817?article_type=v

Rotating Cell Culture Systems for Human Cell Culture: Human Trophoblast Cells as a Model
check_url/fr/56817?article_type=v

Establishment of a Surgically-induced Model in Mice to Investigate the Protective Role of Progranulin in Osteoarthritis
check_url/fr/56817?article_type=v

Characterization of Complex Systems Using the Design of Experiments Approach: Transient Protein Expression in Tobacco as a Case Study
check_url/fr/56817?article_type=v

A Coupled Experiment-finite Element Modeling Methodology for Assessing High Strain Rate Mechanical Response of Soft Biomaterials
check_url/fr/56817?article_type=v

Concentric Gel System to Study the Biophysical Role of Matrix Microenvironment on 3D Cell Migration
check_url/fr/56817?article_type=v

An Experimental and Finite Element Protocol to Investigate the Transport of Neutral and Charged Solutes across Articular Cartilage
check_url/fr/56817?article_type=v

Human iPSC-Derived Cardiomyocyte Networks on Multiwell Micro-electrode Arrays for Recurrent Action Potential Recordings

Read Article