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Related Concept Videos

Motor Units00:46

Motor Units

A motor unit consists of two main components: a single efferent motor neuron (i.e., a neuron that carries impulses away from the central nervous system) and all of the muscle fibers it innervates. The motor neuron may innervate multiple muscle fibers, which are single cells, but only one motor neuron innervates a single muscle fiber.
Gross Anatomy of Skeletal Muscles01:12

Gross Anatomy of Skeletal Muscles

The connective tissues play a significant role in arranging the muscle fibers into a hierarchical structure that forms a complete muscle. Consider a muscle like the bicep brachii, commonly called the bicep. This muscle comprises thousands of muscle fibers enclosed by a protective layer of connective tissue called the endomysium. The endomysium is primarily composed of reticular fibers, a type of thin collagen fiber. It allows the exchange of nutrients and waste products at the fiber level,...
Motor Units01:13

Motor Units

The motor unit is a fundamental component of the neuromuscular system and plays a crucial role in coordinating muscle contractions. It consists of a somatic motor neuron, which connects and controls multiple skeletal muscle fibers, forming a single functional segment. The axon of the motor neuron branches out and establishes synaptic connections known as neuromuscular junctions with individual muscle fibers within the motor unit.
Motor units come in different sizes, with smaller units...
Structure and Organization of Smooth Muscles01:13

Structure and Organization of Smooth Muscles

Smooth muscle tissue is a type of muscle tissue that can be found lining various vital organs in the human body, including the lungs, blood vessels, digestive tract, and respiratory tract. This type of tissue is responsible for regulating the movements of these organs, playing crucial roles in the functioning of various systems, including the vascular, digestive, respiratory, and urinary systems.
Structure of smooth muscle cell
Smooth muscle cells are spindle-shaped with tapering ends and a...
Functions of Smooth Muscles01:23

Functions of Smooth Muscles

Smooth muscles are an important type of muscle tissue that plays a vital role in the involuntary movements of internal organs. For example, they help regulate the movement of food through the gut and the flow of blood through the circulatory system.
Function of visceral smooth muscles
Visceral smooth muscle is found in the walls of all hollow organs, except the heart, and is a key player in the involuntary movements that drive the functioning of these internal organs. This tissue is arranged in...
Sympathetic Pathways: Sympathetic Chain Ganglia01:20

Sympathetic Pathways: Sympathetic Chain Ganglia

The sympathetic chain ganglia, also known as the sympathetic trunk ganglia or paravertebral ganglia, are a series of ganglia located bilaterally on either side of the spinal column. These ganglia serve as relay stations for the sympathetic nervous system. Preganglionic neurons originating in the spinal cord project their axons to the sympathetic chain ganglia. Within the ganglia, these preganglionic fibers synapse with postganglionic neurons.The postganglionic neurons of the sympathetic trunk...

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Updated: May 10, 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

Published on: March 19, 2013

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Tissue-engineered neuromuscular organoids.

Beatrice Auletta1,2,3, Pietro Chiolerio1,2, Giada Cecconi1,2

  • 1Department of Molecular Medicine, University of Padova, Padova, Italy.

Communications Biology
|July 19, 2025
PubMed
Summary
This summary is machine-generated.

Researchers developed novel tissue-engineered neuromuscular organoids using human stem cells and decellularized muscle scaffolds. These organoids mimic human neuromuscular function and disease, offering a new tool for skeletal muscle research.

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Area of Science:

  • Biomedical Engineering
  • Stem Cell Biology
  • Neuroscience

Background:

  • Skeletal muscle function depends on intricate cell and extracellular matrix (ECM) interactions.
  • In vitro models are needed to study innervated skeletal muscle's cellular and ECM components.

Purpose of the Study:

  • To engineer functional human neuromuscular organoids using decellularized muscle scaffolds and human induced pluripotent stem cells (hiPSCs).
  • To create a model for studying neuromuscular system development, homeostasis, and disease.

Main Methods:

  • Utilized decellularized muscle tissue as a scaffold for hiPSC differentiation.
  • Developed tissue-engineered neuromuscular organoids (t-NMOs) over 30 days.
  • Created patient-specific t-NMOs from individuals with Duchenne Muscular Dystrophy.

Main Results:

  • t-NMOs exhibited compartmentalized neural and muscular tissues with functional interactions and muscle contraction.
  • Patient-specific t-NMOs recapitulated reduced muscle contraction and altered calcium dynamics characteristic of Duchenne Muscular Dystrophy.
  • Demonstrated the potential of ECM in organoid engineering for modeling neuromuscular function and dysfunction.

Conclusions:

  • The study presents a novel tissue-engineered organoid model of the human neuromuscular system.
  • This model successfully recapitulates neuromuscular system (dys)function, including disease-specific phenotypes.
  • Highlights the utility of ECM-based scaffolds in creating advanced organoid models for biomedical research.