Download Document

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts

Cognitive neuroscience of music wikipedia , lookup

Long-term depression wikipedia , lookup

Premovement neuronal activity wikipedia , lookup

Development of the nervous system wikipedia , lookup

Stimulus (physiology) wikipedia , lookup

Axon wikipedia , lookup

Neuropsychopharmacology wikipedia , lookup

Neuroanatomy wikipedia , lookup

Embodied language processing wikipedia , lookup

Muscle memory wikipedia , lookup

Feature detection (nervous system) wikipedia , lookup

Subventricular zone wikipedia , lookup

Channelrhodopsin wikipedia , lookup

Synaptogenesis wikipedia , lookup

Cerebellum wikipedia , lookup

Eyeblink conditioning wikipedia , lookup

Transcript
Cerebellum
• Overview and structure of cerebellum
• Microcircuitry of cerebellum
• Motor learning
Overview
• “small brain”
• Weight: 10% of entire brain
• Number of neurons: 50% (due
to large number of small
granule cells)
• Cerebellar cortex: highly
regular structure
• Function: coordination,
balance, motor learning, etc.
The cerebellum consists of the cerebellar
cortex and a set of deep nuclei
fastigial nuclei
interposed nuclei
dentate nuclei
Dorsal view
Sagital view
Different regions of cerebellar cortex are connected to
different deep nuclei
• Vermis  fastigial nuclei, control
proximal muscles
• Intermediate zone  interposed nuclei,
control distal muscles
• Lateral zone  dentate
• Flocculonodular
Descending system to brain
stem, motor execution
Connect to motor & premotor cortices,
planning and initiation of movement
Connect to vestibular nuclei, control balance
and eye movement
Microcircuitry of cerebellum
5 cell types
Stellate
Basket
(molecular layer)
Purkinje
(Purkinje layer)
Golgi
Granular
(Granular layer)
Inputs:
• Climbing fiber (“+”, excitatory)
• Mossy fiber (+)
Output:
• Purkinje cell axon (“-”, inhibitory)
Purkinje cell
2-D dendritic tree perpendicular to the long
convolutions of the cortex
First direct pathway:
• climbing fiber (+)  Purkinje cells (-)  deep nuclei
• each climbing fiber projects to a single Purkinje cell
• each Purkinje cell receives input from a single climbing fiber
• Powerful excitatory connection, each climbing fiber spike cause a burst of spikes
in Purkinje cell (called a “complex spike”)
Second direct pathway:
• Mossy fiber (+)  granule cells (axon: parallel fibers, +)  Purkinje cells (-)  deep nuclei
• each parallel fiber projects to thousands of Purkinje cells (high divergence)
• each Purkinje cell receives input from ~200,000 parallel fibers (high convergence)
• Weak excitatory connection, spatiotemporal summation of inputs from many parallel fibers
causes a single spike in Purkinje cell (called a “simple spike”)
glomeruli
Lateral inhibition:
• granule cells (axon: parallel fibers, +)  stellate and basket cells (-)  Purkinje cells in a
different row
Negative feedback:
•
granule cells (axon: parallel fibers, +)  Golgi cells (-)  granule cells
Everything together
Cerebellum and motor learning
• During learning of a new motor task, subject makes mistakes, but
the error reduces with practice
• The standard notion is that the “error signal” causes changes in brain
circuits involved in motor control (e.g., cerebellum), thus improving
motor performance
Patient H.M., who had bilateral removal of medial temporal lobe and lack of ability to
form episodic memory, but motor learning is intact, indicating it is mediated by
different brain structure
Cerebellum and motor learning
• In a well-known model of cerebellum motor learning, climbing fiber
activity represents error signals (difference between expected and
actual sensory inputs, e.g., the template and the actual drawing).
• Experimentally, simultaneous activation of climbing fibers and
parallel fibers converging onto the same Purkinje cell can cause longterm depression of parallel fiber  Purkinje synapse, which may
underlie motor learning.