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Related Concept Videos

Overview of Muscle Tissues01:25

Overview of Muscle Tissues

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The human body has three types of muscle tissue: skeletal, smooth, and cardiac. Each class has unique properties that enable them to perform specific functions. However, all muscle tissues share certain properties, including elasticity, contractility, and excitability. 
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Plant Cells and Tissues02:01

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Plant tissues are collections of similar cells performing related functions. Different plant tissues will have their own specialized roles and can be combined with other tissues to form organs such as flowers, fruit, stem, and leaves. Two major types of plant tissue include meristematic and permanent tissue.
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Tissues01:18

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Cells with similar structure and function are grouped into tissues. A group of tissues with a specialized function is called an organ. There are four main types of tissue in vertebrates: epithelial, connective, muscle, and nervous.
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Tissues are a group of cells that share a common embryonic origin. Microscopic observation reveals that the cells in a tissue share morphological features and are arranged in an orderly pattern to perform specific functions. From an evolutionary perspective, tissues appear in more complex organisms. Although there are many types of cells in the human body, they are organized into four broad categories of tissues: epithelial, connective, muscle, and nervous. Each of these categories is...
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Bone Cells and Tissue01:30

Bone Cells and Tissue

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Bones contain a relatively small number of cells entrenched in a matrix of organic and inorganic components. Although bone cells compose only a small amount of the bone volume, they are crucial to its function. Four types of cells are found within the bone tissue— osteoblasts, osteocytes, osteogenic cells, and osteoclasts.
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Lymphoid Cells and Tissues01:18

Lymphoid Cells and Tissues

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Lymphoid cells and tissues are integral to the immune system, which is crucial in maintaining our body's defense against harmful pathogens. They form the building blocks of lymphoid organs, which include the spleen, thymus, and lymph nodes.
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Updated: Feb 6, 2026

Engineering Skeletal Muscle Tissues from Murine Myoblast Progenitor Cells and Application of Electrical Stimulation
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Engineering Skeletal Muscle Tissues from Murine Myoblast Progenitor Cells and Application of Electrical Stimulation

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Modelling multi-scale cell-tissue interaction of tissue-engineered muscle constructs.

Ryo Torii1, Rallia-Iliana Velliou1, David Hodgson2,3

  • 1Department of Mechanical Engineering, University College London, London, UK.

Journal of Tissue Engineering
|August 22, 2018
PubMed
Summary
This summary is machine-generated.

Engineered tissue development relies on understanding cellular responses to mechanical forces. Combining experimental and computational methods offers a powerful approach to predict tissue growth and improve engineered tissue quality.

Keywords:
Cellular mechanoresponseagent-based methodengineered tissue growth predictionfinite element analysis

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Area of Science:

  • Biomedical Engineering
  • Tissue Engineering
  • Computational Biology

Background:

  • Cellular mechanoresponse is crucial for functional engineered tissues, but quantitative monitoring remains challenging.
  • Understanding cell-tissue interactions across scales is improving, yet technical limitations persist.
  • Computational (in silico) studies are increasingly used to complement experimental data and predict tissue growth.

Purpose of the Study:

  • To review combined experimental and computational approaches in tissue growth analysis.
  • To highlight the advantages of integrated methods for tissue engineering.
  • To present a case study on predicting musculoskeletal tissue engineering construct development.

Main Methods:

  • Literature review of combined experimental and computational studies in tissue growth.
  • Analysis of technical limitations in quantitative monitoring of tissue development.
  • Case study application to musculoskeletal tissue engineering.

Main Results:

  • Integrated experimental and computational analyses offer significant advantages for tissue engineering.
  • Computational models can successfully predict tissue growth, complementing experimental findings.
  • The reviewed approaches enhance the quality control and development of engineered tissues.

Conclusions:

  • A combined experimental and computational strategy is essential for advancing tissue engineering.
  • This integrated approach overcomes current technical limitations in monitoring tissue development.
  • Predictive modeling of tissue growth is key to the future of functional engineered tissues.