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Developing 3D Organized Human Cardiac Tissue within a Microfluidic Platform
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Bioengineered Human Cardiac Ventricular Model with Transmural Helical Remodeling.

Nisa P Williams1, Kevin M Beussman2, John R Foster1

  • 1Department of Bioengineering, University of Washington, Seattle, WA, 98195, USA.

Advanced Healthcare Materials
|June 13, 2025
PubMed
Summary
This summary is machine-generated.

Researchers engineered a 3D heart model with helical architecture, mimicking natural myocardial twisting for efficient blood ejection. This tissue engineering approach reveals how mechanical forces guide cell remodeling and cardiac structure-function relationships.

Keywords:
contractile pressureinduced pluripotent stem cellsstructure‐function relationshiptissue engineeringventricular remodeling

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Area of Science:

  • Biomedical Engineering
  • Cardiovascular Research
  • Tissue Engineering

Background:

  • The heart's helical myocardial architecture is crucial for efficient blood ejection.
  • Existing methods struggle to replicate complex cardiac structure-function relationships at the organ level.

Purpose of the Study:

  • To engineer a human 3D ventricular model with helical transmural architecture.
  • To investigate how mechanical cues influence cardiac tissue remodeling and structure-function relationships.

Main Methods:

  • Assembling multilayered, patterned cardiac sheets on a 3D-printed conical mold.
  • Comparing contractile performance of ventricles with cardiomyocytes aligned parallel, perpendicular, angled, or randomly.
  • Utilizing finite element analysis to study stress distribution and cellular remodeling.

Main Results:

  • Tissue-engineered ventricles with perpendicular cardiomyocyte alignment showed enhanced contractile pressures and capture rates.
  • Spontaneous realignment of inner layers in perpendicular sheets formed a helical structure over 4 days.
  • Finite element analysis indicated cells remodel to reduce local shear stress, influenced by alignment.

Conclusions:

  • Engineered cardiac tissue can dynamically remodel in response to mechanical cues within a 3D geometry.
  • This platform elucidates the mechanobiology underlying myocardial structure-function relationships.
  • The study provides insights into replicating physiologically relevant cardiac architecture and function.