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Direct Motor Pathways01:11

Direct Motor Pathways

2.8K
The direct motor pathways, also known as the pyramidal tracts, are a group of neural pathways that originate in the brain and descend through the spinal cord. They control the voluntary movement of the body. There are two major direct motor pathways: the corticospinal and the corticobulbar tracts.
The corticospinal tract is responsible for the voluntary movement of the limbs and trunk. It originates in the cerebral cortex of the brain and descends through the cerebrum's internal capsule and...
2.8K
Motor Unit Stimulation01:20

Motor Unit Stimulation

2.5K
When the neuron of a motor unit fires an action potential, it triggers a series of events, leading to a twitch contraction in the muscle fibers. The process of excitation-contraction coupling is crucial in relaying the action potential to the muscle fibers.
The latent period of contraction marks the onset of excitation-contraction coupling, when the action potential propagates across the sarcolemma, preparing the muscle fibers for contraction. As the fibers enter the contraction phase, the...
2.5K
Hierarchy of Motor Control01:18

Hierarchy of Motor Control

4.1K
The hierarchy of motor control refers to the different levels of organization and processing involved in controlling movement in the body. These levels range from higher cortical areas involved in planning and decision-making to lower spinal cord reflexes that respond automatically to external stimuli.
4.1K
Indirect Motor Pathways01:22

Indirect Motor Pathways

1.9K
The indirect motor or extrapyramidal pathways originate in the brainstem, the lower portion of the brain that connects it to the spinal cord. They consist of several distinct tracts, each with specialized functions. The four main tracts of the indirect motor pathways are the vestibulospinal tract, the reticulospinal tract, the tectospinal tract, and the rubrospinal tract.
The vestibulospinal tract originates in the vestibular nuclei of the brainstem. The vestibular system detects changes in...
1.9K
Muscle Stimulation Frequency01:22

Muscle Stimulation Frequency

3.3K
The contraction strength of muscles is regulated by motor neurons, which modulate the frequency of action potentials dispatched to the motor units based on the body's requirements. This process of varying the muscle stimulation frequency allows muscles to contract with a force that is precisely tailored to the needs of the moment, whether lifting a feather or a heavy box.
Wave summation
At low firing rates, motor neurons induce individual twitch contractions in muscle fibers. These twitches...
3.3K
Motor Units01:13

Motor Units

5.8K
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...
5.8K

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Related Experiment Video

Updated: Oct 16, 2025

Measuring and Manipulating Functionally Specific Neural Pathways in the Human Motor System with Transcranial Magnetic Stimulation
09:52

Measuring and Manipulating Functionally Specific Neural Pathways in the Human Motor System with Transcranial Magnetic Stimulation

Published on: February 23, 2020

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Motor Learning Promotes the Coupling between Fast Spindles and Slow Oscillations Locally over the Contralateral Motor

Agustín Solano1, Luis A Riquelme1, Daniel Perez-Chada2

  • 1IFIBIO Houssay, Department of Physiology, School of Medicine, University of Buenos Aires, C1121ABG, Argentina.

Cerebral Cortex (New York, N.Y. : 1991)
|October 14, 2021
PubMed
Summary
This summary is machine-generated.

This study reveals that the brain’s slow oscillations (SO) and fast spindles during sleep are crucial for motor memory consolidation. This sleep mechanism, previously linked to declarative memory, also stabilizes motor skills.

Keywords:
humanmotor learningsleepslow oscillationspindle

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Area of Science:

  • Neuroscience
  • Sleep Research
  • Motor Learning

Background:

  • Declarative memory consolidation involves specific sleep oscillations, namely slow oscillations (SOs) and sleep spindles.
  • Emerging evidence suggests overlapping physiological pathways between declarative and procedural memory systems.
  • The role of these sleep oscillations in motor memory stabilization remains largely unexplored.

Purpose of the Study:

  • To investigate whether the coupling between slow oscillations (SOs) and sleep spindles, known for declarative memory consolidation, is also relevant for human motor memory stabilization.
  • To examine the impact of visuomotor adaptation (VMA) learning on SOs and spindles during non-rapid eye movement sleep (NREM3).

Main Methods:

  • Electroencephalography (EEG) was used to record brain activity during sleep.
  • Participants underwent a visuomotor adaptation (VMA) task before a night of sleep.
  • Quantification of slow oscillations (SOs) and fast (≥12 Hz) and slow (<12 Hz) sleep spindles during NREM3 sleep.

Main Results:

  • Visuomotor adaptation learning increased the density of fast spindles, particularly over the hemisphere contralateral to the trained hand, during NREM3 sleep.
  • Learning did not alter SO density but significantly increased the number of fast spindles phase-locked to the active phase of SOs.
  • The number of SO-spindle coupled events, but not individual spindle density, predicted overnight retention of the motor memory.

Conclusions:

  • The coupling between slow oscillations and fast spindles during sleep plays a critical role in the consolidation of human motor memories.
  • This finding supports a common underlying neurophysiological mechanism for the stabilization of both declarative and motor memories.
  • Sleep-based oscillatory coupling represents a potential target for enhancing motor skill learning and retention.