Neurophysiology of Reward and Addiction

Question 1

Reward prediction error

Answer 1

• Dopaminergic neurons encode the mismatch b/w reward predicted and the info about the actual reward, then send this to brain regions involved in reward learning
  1. Positive prediction error - unpredicted reward elicits an activation (brain arousal)
  2. No response - fully predicted reward –> assigns value to reward itself rather than only noting when it occurred
  3. Negative prediction error - omission of a predicted reward induces depression

Question 2

Drug vs natural reward

Answer 2

• Repeated drug use causes repeated reward prediction error signals since the exogeneous compound elicits a larger and longer (5-10X) increase in extracellular [dopamine] in limbic regions than natural reinforcers (e.g. food and sex). These signals continue to reinforce drug-related cues and behaviors since we are unable to appropriately correct the reward prediction to this level
• Natural rewards produce an error-correcting dopamine reward prediction error that signals until the predictions match the actual events

Question 3

Reward prediction and salience

Answer 3

• Salience = stimuli or environmental changes that are arousing or elicit an attentional-behavioral switch and it affects the motivation to seek anticipated reward + conditions learning –> drug-induced dopamine will motivate further drug procurement b/c salience and motivation to seek the drug becomes more powerful
• Also leads to an increase in DA via sensory stimuli associated w/ drug or drug taking to elicit desire for drug –> risk of relapse when exposed to familiar environment

Question 4

Dopamine-hypothesis of reward

Answer 4

1. Activation of the ventral tegmental area when engaging in behavior/activity that results in reward
2. Dopaminergic neurons from the ventral tegmental area project to the nucleus accumbens
3. Dopamine inhibits nucleus accumbens –> decreased activity
4. Decreased GABA released on the prefrontal cortex –> sensation of pleasure
5. Nucleus accumbens projects back on to the ventral tegmental area and eventually releases GABA and dynorphin (acts through kappa-opioid receptors) to suppress the additional DA release from the VTA to halt reward process

Question 5

main function of the nucleus accumbens

Answer 5

• Suppress sensations of pleasure/reward via GABA projections to constitutively inhibit the prefrontal cortex –> reward-neutral state
• Nucleus accumbens is constitutively activated by trickle of EAA from hippocampus, amygdala or prefrontal cortex

Question 6

How does the ventral tegmental area become activated in reward pathway?

Answer 6

Upon engaging in behavior or activity that results in reward it can be activated by:

1. EAA from pre-frontal cortex
2. ACh from dorsal tegmental area
3. Orexin from hypothalamus in consuming food

Question 7

Dopamine-independent reward pathway

Answer 7

• Exercise, ethanol, etc increase endogenous opioid at all lvls of the reward network via activation of mu-receptors w/in:
  1. Dopaminergic neurons in the ventral tegmental area –> inhibit local interneurons to ‘disinhibit’ DA neurons and allow for DA release
  2. Local interneurons in the nucleus accumbens to inhibit GABA neurons locally
  3. Prefrontal cortex
• Net = profound sense of pleasure

Question 8

Normal reward stimuli vs reward due to drugs of abuse: normal reward stimuli

Answer 8

• Caused by release of dopamine from ventral tegmental area
• Reinforces behaviors c/w health, longevity and don’t have immediate benefit
• Reward = sense of pleasure

Question 9

Normal reward stimuli vs reward due to drugs of abuse: drugs of abuse

Answer 9

• Drugs enhance dopamine release from ventral tegmental area
• Dopamine signal in nucleus accumbens is not proportional to stimuli (constant negative reward prediction error)
• Reward = enhanced euphoria and exaggerated reward to an otherwise mild stimulus

Question 10

Memory in reward/addiction: hippocampus

Answer 10

-Lasting memory created that associates rewarding feelings w/ circumstance/context and environment in which they occur (“conditioned associations”)

Question 11

Memory in reward/addiction: amygdala

Answer 11

• retrieval of fear memories

- mediates cravings

Question 12

Memory in reward/addiction: ventral tegmental area

Answer 12

-signal prediction error b/w expected outcome and actual reward experienced

Question 13

Memory in reward/addiction: substantia nigra & dorsal striatum

Answer 13

-motor response associated w/ navigating environment toward desirable cue w/ goal of engaging in activity that elicits reward

Question 14

Memory in reward/addiction: orbitofrontal cortex

Answer 14

-when abuser encounters associated persons or things and then driven to make poor decisions or seek out more drugs in spit of obstacles

Question 15

Memory mechanisms in reward/addiction

Answer 15

• Persistent increase in synaptic strength following high-frequency stimulation of a chemical synapse –> requires repeated strong stimulation (Papez circuit)
  a. Short-term - increased phosphorylation of AMPA in post-synpatic membrane
  b. Longer term - activation of Ca2+-Calmodulin-CREB mechanism (LTP)
  c. Life long - signaling cascades involving deltaFosB and AP-1

Question 16

Memory mechanisms in reward/addiction: CREB

Answer 16

1. Stimulates production of dynorphin w/in the nucleus accumbens but acts for days-weeks and returns to normal lvls after cessation of reward stim
2. Mediates physical dependency w/in locus ceruleus due to excessive noradrenergic output and CREB-dependent upregulation of structural proteins involved in learning and memory

Question 17

Memory mechanisms in reward/addiction: deltaFosB and AP-1

Answer 17

• Lifelong implications/learning
• Transcription factors that increase transcription/translation of:
  a. structural proteins
  b. EAA receptor expression
  c. Elements of cell signal transduction pathways
  d. Factors promoting drug seeking, motivation and locomotion

Question 18

Stress, memory and reward: nucleus accumbens

Answer 18

• Assigns salience to certain stimuli and mediates decisions that seek a desirable or avoid an aversive situation
• Acute stress, mediated by corticotrophin releasing factor, usually increases dopamine release in the nucleus accumbens in short term
• Severe, chronic stress results in corticotrophin releasing factor-mediated dopamine release to result in aversive results –> switches emotional response to acute stressors due to divergent action of CRF1 vs CRF2 receptors in the nucleus accumbens