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Indirect Motor Pathways01:22

Indirect Motor Pathways

2.8K
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...
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Major Somatic Sensory Pathways01:28

Major Somatic Sensory Pathways

2.1K
Sensory impulses related to touch, pressure, vibration, and proprioception from various body parts, such as the limbs, trunk, neck, and posterior head, travel to the cerebral cortex through the posterior column-medial lemniscus pathway. The pathway’s name derives from the two white-matter tracts that convey the impulses: the spinal cord's posterior column and the brainstem's medial lemniscus. First-order sensory neurons extend their axons into the spinal cord, forming the...
2.1K
Functional Brain Systems: Reticular Formation01:13

Functional Brain Systems: Reticular Formation

3.7K
The reticular formation is a complex network of gray and white matter located within the brainstem extending from the medulla to the midbrain.
Within the reticular formation, there are several distinct nuclei that can be classified into three broad categories. The Raphe nuclei are located along the midline of the brainstem. They are primarily known for their role in synthesizing and releasing serotonin, a neurotransmitter involved in regulating mood, appetite, sleep, and circadian rhythms. The...
3.7K
Brainstem01:19

Brainstem

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The brainstem, located inferior to the brain and superior to the spinal cord, serves as a bridge between the cerebrum and the spinal cord. It plays a vital role in relaying information and controlling critical life functions. It comprises three primary regions: the midbrain, pons, and medulla oblongata.
The Midbrain
The midbrain is located beneath the diencephalon and connects the cerebrum with the lower parts of the brain. The cerebral peduncles are prominent midbrain structures that house the...
4.9K
Cerebellum: Anatomical Regions01:17

Cerebellum: Anatomical Regions

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The cerebellum, also known as the "little brain," is located in the posterior cranial fossa, inferior to the tentorium cerebelli and dorsal to the brainstem. It plays a significant role in motor control, coordination, and proprioception.
Cerebellar Structure
Externally, the cerebellum features a highly convoluted surface with numerous folia (narrow ridges) separated by shallow sulci (grooves). The cerebellum is divided into two hemispheres by a thin median structure known as the vermis. The...
3.6K
Diencephalon: Thalamus and Information Relay01:27

Diencephalon: Thalamus and Information Relay

3.3K
The thalamus, often called “the gateway to the cerebral cortex,” is vital in processing and directing sensory and motor signals throughout the brain. Almost all inputs destined for the cerebral cortex, except for olfactory signals, are relayed through the thalamus. The thalamus is  a sophisticated relay station, channeling information from various brain regions to the cerebral cortex, as well as a filter, prioritizing certain signals over others based on current physiological...
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Related Experiment Video

Updated: Dec 12, 2025

In Vivo Wireless Optogenetic Control of Skilled Motor Behavior
07:52

In Vivo Wireless Optogenetic Control of Skilled Motor Behavior

Published on: November 22, 2021

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Cerebral Substrates for Controlling Rhythmic Movements.

Naho Konoike1, Katsuki Nakamura1

  • 1Section of Neuroscience, Primate Research Institute, Kyoto University, Kyoto 484-8501, Japan.

Brain Sciences
|August 7, 2020
PubMed
Summary

The brain controls rhythmic movements through interconnected sensory and motor functions. New research explores rhythm processing independent of senses and body parts to understand neural control mechanisms.

Keywords:
brain imagingfinger-tappingneurosciencepatient studyrhythm

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Area of Science:

  • Neuroscience
  • Cognitive Science
  • Motor Control

Background:

  • Rhythmic movements like walking and dancing are integral to daily life.
  • The brain mechanisms underlying rhythmic movement control remain largely unclear.
  • Previous studies suggest intertwined sensory and motor processing of rhythm.

Purpose of the Study:

  • To investigate rhythm representations independent of sensory and motor functions.
  • To identify brain areas involved in modality-independent rhythm processing.
  • To examine body part-independent neural activation during rhythm reproduction.

Main Methods:

  • Review of neuropsychological studies on focal brain lesions.
  • Analysis of functional brain imaging studies, primarily using finger-tapping tasks.
  • Conducting two novel functional brain imaging studies.

Main Results:

  • Evidence suggests a strong link between sensory and motor rhythm processing.
  • Identified brain activations for rhythm processing irrespective of sensory input.
  • Observed body part-independent brain activation during rhythm reproduction.

Conclusions:

  • The brain utilizes integrated sensory-motor networks for rhythmic control.
  • Further research is needed to fully elucidate the neural basis of rhythmic movement.
  • Understanding these mechanisms can inform treatments for motor control disorders.