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Related Concept Videos

Gastrulation01:56

Gastrulation

Gastrulation establishes the three primary tissues of an embryo: the ectoderm, mesoderm, and endoderm. This developmental process relies on a series of intricate cellular movements, which in humans transforms a flat, “bilaminar disc” composed of two cell sheets into a three-tiered structure. In the resulting embryo, the endoderm serves as the bottom layer, and stacked directly above it is the intermediate mesoderm, and then the uppermost ectoderm. Respectively, these tissue strata will form...

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Related Experiment Video

Updated: May 21, 2026

In Vitro Cultivation Techniques for Modeling Liver Organogenesis, Building Assembloids, and Designing Synthetic Tissues using Human Cell Lines
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In Vitro Cultivation Techniques for Modeling Liver Organogenesis, Building Assembloids, and Designing Synthetic Tissues using Human Cell Lines

Published on: April 18, 2025

Computer simulations of in vitro morphogenesis.

Andreea Robu1, Roxana Aldea, Oana Munteanu

  • 1Department of Automation and Applied Informatics, Politehnica University of Timisoara, Vasile Parvan Ave. No. 2, 300223 Timisoara, Romania. andreea.robu@aut.upt.ro

Bio Systems
|June 27, 2012
PubMed
Summary
This summary is machine-generated.

Computational models aid tissue engineering by simulating cell assembly and morphogenesis. These tools, when validated, can optimize lab-grown tissue development and experimental design for creating tissue replacements.

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Area of Science:

  • Computational biology
  • Developmental biology
  • Tissue engineering

Background:

  • Understanding how cells assemble into tissues (morphogenesis) is a key challenge in biology.
  • Tissue engineering (TE) aims to create tissue replacements in laboratories.

Purpose of the Study:

  • To review individual-based computational models for simulating tissue morphogenesis.
  • To illustrate the potential of these models in addressing TE challenges.
  • To analyze validation strategies for computational tissue models.

Main Methods:

  • Narrative review of existing literature on individual-based computational models.
  • Description of morphogenetic mechanisms.
  • Presentation of cellular and subcellular resolution models.
  • Analysis of validation experiments for cohesive cell tissue constructs.

Main Results:

  • Individual-based computational models are useful for simulating tissue morphogenesis.
  • Current models are underutilized in the literature.
  • Validated computational models can optimize cell culture and experimental design.

Conclusions:

  • Computational models offer significant potential for advancing tissue engineering.
  • Further validation of these models is crucial for their practical application.
  • Optimized models can guide the design of new experiments and improve tissue construct development.