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Related Concept Videos

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.
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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.
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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...
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Spinal Cord: Cross-sectional Anatomy01:16

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The cross-sectional anatomy of the spinal cord offers a detailed view of its complex structure and function within the central nervous system. At the core of the spinal cord lies the gray matter, characterized by its butterfly or "H"-shaped appearance in cross-section. This central region is enveloped by white matter, with the overall structure divided into symmetrical halves by the dorsal median sulcus and the ventral median fissure.
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Central to the gray...
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Cerebellum: Anatomical Regions01:17

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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.
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Diencephalon: Thalamus and Information Relay01:27

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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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Separate brainstem circuits for fast steering and slow exploratory turns.

Lulu Xu1,2, Bing Zhu1,2, Zhiqiang Zhu1,2

  • 1Shanghai Key Laboratory of Anesthesiology and Brain Functional Modulation, Clinical Research Center for Anesthesiology and Perioperative Medicine, Translational Research Institute of Brain and Brain-Like Intelligence, Shanghai Fourth People's Hospital, School of Medicine, Tongji University, Shanghai, China.

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Summary

The brainstem uses distinct circuits for rapid steering and slow exploratory turns during locomotion. These circuits, involving specific neuron types, enable precise control over turning movements for different behaviors.

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Area of Science:

  • Neuroscience
  • Motor Control
  • Computational Neuroscience

Background:

  • Locomotion involves complex motor commands for turning.
  • Different turning behaviors, like prey pursuit and exploration, require distinct motor control strategies.

Purpose of the Study:

  • To investigate the neural circuits underlying rapid steering versus slow exploratory turns.
  • To elucidate the modular organization of brainstem circuits controlling different turning behaviors.

Main Methods:

  • Electrophysiological recordings in vivo
  • Genetic manipulation of neuronal populations
  • Behavioral analysis of turning maneuvers

Main Results:

  • Identified distinct brainstem circuits for rapid steering (V2a and V0d neurons) and slow turns (separate V2a neurons).
  • Rapid steering circuits are activated by the degree of direction change, not locomotor frequency.
  • Pretectal V2a neurons, responding to visual input, control steering neurons.

Conclusions:

  • Brainstem circuits are modularly organized to control distinct turning behaviors.
  • Separate neural pathways enable precise scaling of turning movements for specific locomotor contexts.