Circuit dysfunction

Question 1

What are the basal ganglia?

Answer 1

The striatum (including cuadate nucleus, putamen and ventral striatum (Nacc)), globus pallidus in the cerebrum, the substantia nigra in the midbrain, and the subthalamic nucleus in the diencephalon.

Question 2

What are the functions of the basal ganglia?

Answer 2

• Coordination of execution (info integration for smooth movements)
• initiation and termination of voluntary movements. Inhibition of unwanted movements. (motor circuits)
• Initiation and termination of cognitive and emotional processes (non motor loops (prefrontal and limbic circuits))

Question 3

How does the basal ganglia fit within the motor pathway?

Answer 3

Filters information from cortical areas. This filtered information projects to different nuclei in brain stem via the thalamus, reaching spinal cord where motor circuits are activated.

Question 4

What role does the cerebellum have?

Answer 4

Both the BG and cerebellum influence movement by regulating activity of upper motor neurones. Do not project directly to local circuits or lower motor neurones.

Question 5

What are the 2 descending systems?

Answer 5

Motor cortex - planning, initiating and directing voluntary movements.
Brainstem centres - Basic movements and postural control.

Question 6

Describe the anatomical organisation of inputs to the BG

Answer 6

1. Sensory inputs from cortical areas project via glutamatergic neurones to input areas (putamen and caudate of striatum).
2. Dopamine inputs from substantia nigra reach striatum too.

Question 7

Where are excitatory neurones in the BG found?

Answer 7

The Subthalamic nucleus

Question 8

Describe the anatomical organisation of outputs to the BG

Answer 8

1. In the striatum there are 2 populations of medium spiny neurones.
2. Population 1 of MSN project to the internal segment of the globus pallidum (DIRECT CIRCUIT) where they then project to thalamus by GABAergic neurones maintaining inhibition in the thalamus. When activated, they temporarily release inhibition in the thalamus, and projections to the cortex are allowed and projection to motor areas initiated.
3. Population 2 of medium spiny neurones (inhibitory) project to the external area of globus pallidum. (INDIRECT CIRCUIT - projects to subthalamic nucleus, where there are excitatory neurones that project to the internal globus pallidus.)

Question 9

What are the MSNs?

Answer 9

MSNs projecting to internal segment of pallidum have D1 receptors. When MSNs are excited by dopamine, D1 receptors are activated and project to internal pallidum.
MSNs project

Question 10

What happens with dopamine application to the dopamine neurones?

Answer 10

D1 - Excites MSNs involved in direct pathway. Up regulation of adenylase cyclate and excitation. (Higher inhibition of globus pallidus internal via GABA- neurones.)
D2 - Excites MSNs involved in indirect pathway. Down regulation of adenylate cyclase. Suppression of activity.

Question 11

How are MSNs activated?

Answer 11

AP generated in axon hilock
Dopaminergic neurones synapse very far from axon hilock on synaptic spines so they are very hard to activate.
Large amounts of convergence on single GPi/GPe neurones.

Question 12

What is the direct pathway

Answer 12

EXCITATORY OF THALAMUS

1. Stimulation of cerebral cortex
2. Excitatory glutamatergic input to striatum (caudate and putamen)
3. In striatum, GABAergic inhibitory neurones activated by MSNs project to the internal segment of globus pallidum.
4. This inhibits tonic inhibitory GABAergic firing to the thalamus, disinhibiting it.
5. Thalamus fires glutamatergic / cholinergic (excitatory) inputs to frontal cortex where movement can be generated.

Question 13

What is the indirect pathway

Answer 13

INHIBITORY OF THALAMUS

1. Stimulation of cerebral cortex.
2. Activates excitatory glutamatergic neurones, exciting striatum.
3. Striatum activated, sending inhibitory GABAergic signals to GPexternal.
4. Supresses inhibitory neurones firing to the subthalamic nucleus, allowing excitatory glutamatergic firing to globus pallidus internal segment.
5. GPinternal fires tonic GABAergic impulses to thalamus.
6. Movement supressed.

Question 14

what role does the substantia nigra have in the indirect and direct pathways?

Answer 14

Releases dopamine (via D1 or D2)

Question 15

What is parkinson’s disease characterised by?

Answer 15

Diminished Substantia nigra.
Reduced dopaminergic firing to the striatum. Works in the motor loop.
- Without D1 (involved in direct pathway) - less excitation of GPi, so an increased inhibition of thalamus and diminished
activation of motor areas.
- Without D2 (indirect) - less inhibition of inhibitory neurones projecting to subthalamic nucleus. More excitation of GPi, higher inhibition of thalamus and motor areas.

Question 16

How can Parkinson’s disease be treated?

Answer 16

• Replace dopamine - Cannot be administered orally as can not cross blood brain barrier.
• L -Dopa administeration (it is a dopamine precursor and can go through BBB.) (Can lead to hallucinations).
• Inhibition of MOA and COMT enzymes as degrade dopamine.
• deep brain stimulation (implant electrodes into parts of BG and batteries under skin keep electrodes activated causing excitation of BG).

Question 17

What happens in a non - schizophrenic brain?

Answer 17

1. D1 neurones in the VTA activate glutamatergic (excitatory) in the prefrontal cortex which feed back to the VTA (positive feedback loop) .
2. These glutamatergic neurones descend onto GABAergic neurones in VTA, which keep D2 neurones projecting to the Nacc under tonic inhibition.

Question 18

What happens in a schizophrenic brain?

Answer 18

1. weakened D1 input from VTA to prefrontal cortex
2. Less activation of GABAergic neurones.
3. More D2 activity firing to Nacc and more dopamine in Nacc.

Question 19

What are some schizophrenia treatments?

Answer 19

DA antagonists

Question 20

What are the cell bodies in the midbrain?

Answer 20

VTA and SN

Question 21

What forebrain areas do the VTA and SN project to?

Answer 21

Prefrontal cortex
Nacc
Dorsal striatum (including Nacc)

Question 22

What is the mesocortical limbic system

Answer 22

System involved in perceiving reward and reinforcement.

Includes dopamine neurones projecting from VTA to NAcc and PFC.

Question 23

How do natural reinforcers affect the NAcc

Answer 23

Increase activity of dopaminergic neurones in VTA which project to the NAcc and PFC releasing dopamine. After exposure of the natural reward, there is a decline in dopamine release.

Question 24

How do addictive drugs differ to natural reinforcers.

Answer 24

Release far more dopamine in NAcc (250% more than basal levels for cocaine v 50% more for food).
Work pharmacologically, by consistently causing a heightened release of dopamine.

Question 25

How does cocaine work specifically?

Answer 25

Causes its subjective experienced effects by increasing monoaminergic neurotransmission in mesocortical limbic pathway from VTA to NAcc and PFC,
through the inhibition of dopamine, adrenaline and serotonin reuptake inhibitors, causing a
prolonged extracellular deposit of these neurotransmitters

Question 26

How does addiction work?

Answer 26

A shift from activation in the NAcc (where rewards are first learnt about) to the dorsal striatum which is responsible for habitual behaviour.
Addictive drugs can also reduce excitability in PFC neurones, responsible for executive function, causing higher likelihood of taking drugs even with adverse consequences.
Can increase LTP of reward circuits involved in impulsivity. In rats, a single administration of cocaine can enhance transmission at synapses connecting glutamatergic nerve endings and dopaminergic neurones in the VTA.
Neutral stimuli can be given incentive salience when paired with drug related stimuli.

Question 27

How does amphetamine differ to cocaine?

Answer 27

Not only does it inhibit reuptake transporters, it reverses the activity of dopamine transporters to pump dopamine into the synapse.

Question 28

What is the action of opiates?

Answer 28

Inhibits opioid receptors, decreasing Adenylyl clycase activity, opening K channels and closing Na channels, inhibiting it. This disinhibits dopamine neurones in the NAcc.
Opioid receptors are interneurones that project onto dopamine neurones.

Question 29

What is the action of alcohol?

Answer 29

Agonist to GABA and antagonist to NMDA.

Increases dopamine release in NAcc.