W10 - Neuro: Motivation

Question 1

What is motivation?

Answer 1

*Driving force
*Physical need
*Wanting, liking

Question 2

What roles do the hypothalamus play?

Answer 2

*Maintain homeostasis by regulating three
interrelated functions
–endocrine secretion
–autonomic nervous system
–emotions and drive/behaviour
*Motivated behaviour, e.g. drinking, eating

Question 3

How does the body’s energy system work?

Answer 3

a) Anabolism during the prandial state
This is where we eat food and is absorbed into the system and gets stored as glycogen and triglycerides turn into adipose tissue etc.

b) Catabolism during the post-absorptive state is
This occurs after about 8 hours of fasting. The system still requires food, so the previously stored energy sources are broken down.

Together this is called metabolism.

Question 4

What are The long-term regulations of feeding
behaviour and body fat?

Answer 4

a) Intake = expenditure = normal adiposity
b) Intake > expenditure = obesity
c) Intake < expenditure = Starvation

Question 5

What are the effects of Parabiosis on body weight in ob/ob mice

Answer 5

*Parabiosis: sharing of blood circulation between animals.
*Blood borne signals are shared and can affect the hypothalamus.
*Example 1:–A genetically obese mouse ob/ob: its fat cells do not produce leptin. (Leptin inhibits food intake)–Connected to a normal mouse (which produces leptin) will lead to a reduction of obesity in the ob/ob mouse.

They did an experiment with normal mice and ob ob mice, where the ob ob mice were obese. They found a way to create 2 mice with a shared circulatory system (like conjoint twins) with one normal mouse and one ob ob mouse. They found that the ob ob mouse started losing weight since the chemical regulating factor was crossing over to its brain.

Question 6

What is Jeffrey Friedman: Discovery of Leptin?

Answer 6

Leptin means thin in Greek.
He isolated the leptin protein by separating ob ob mice into 2 groups, one with saline and the other with leptin.

Question 7

How does feedback work?

Answer 7

Fatty tissues produce leptin when satisfied.
Leptin then travels to the brain to tell you to stop eating.
They relay this information to the Arcuate nucleus in the hypothalamus.

Question 8

What role does the frontal section of the hypothalamus play?

Answer 8

Structures in descending order:
-The third ventricle sends messages to and receives messages from the lateral ventricles.
- Paraventricular nucleus - This is where the magocellular neurones and cell bodies project from to the posterior pituitary to release oxytocin and vasopressin.
- Lateral hypothalamic area
- Ventromedial Hypothalamic nuclei
- Arcuate nucleus

Question 9

How did they investigate homeostasis, body weight and food intake from the hypothalamus?

Answer 9

Similar to the practical, they looked at VMH lesioned rat brain and brain of sister of lesioned rat.

They found that VMH-legioned rat showed a dramatic increase in food intake and body weight. In conclusion, the VMH plays a role in controlling the cessation of eating. Damage to the VMH results in prolonged and dramatic weight gain.
The ventromedial hypothalamus of the rat was damaged and her body weight was monitored for a year. Her sister was normal.

Question 10

What is VMG and LH effects on food intake?

Answer 10

Lateral hypothalamic syndrome: diminished
appetite for food; anorexia
Venteromedial hypothalamic syndrome: overeating and obesity
Both related to leptin signaling

Question 11

What is the Arcuate Nucleus?

Answer 11

Arcuate Nucleus: important for control of feeding (effect of leptin on arcuate nucleus)

Question 12

What is the anorexic response?

Answer 12

Elevated leptin levels will get sensed by specialised neurones, whose cell bodies are found in the Arcuate nucleus. These neurohormones, release 2 peptide hormones (CART/a-MSH). These neurones project to axons to the lower part of the brain stem and spinal cord, the paraventricular nuclei of the hypothalamus, and the lateral hypothalamic area. Each of these are connections contribute to the coordinated humoral, visceromotor and somatic motor responses to increased leptin levels.

The neurones would induce the release of corticotrophic releasing factor and thyrotrophin releasing factor. CRH released in the portal system gets transported to the anterior pituitary, where they will induce the release of ACTH and TSH into the circulation, which will eventually release cortisol and thyroxine. This increases the basal metabolic rate, increasing metabolism.

Injection of CART/aMSH mimics high concentration of leptin

Question 13

What is a response to elevated leptin levels?

Answer 13

*Activation of arcuate neurons that
release αMSH and CART peptides
–Anorectic peptides—diminish appetite
–Project to regions that orchestrate
coordinated response of humoral,
visceromotor, and somatic responses
*Paraventricular nucleus (humoral response)
*Intermediolateral gray matter of spinal cord
(visceromotor response)
*Lateral hypothalamus (somatic response)

Question 14

What is orexigenic?

Answer 14

This contributes to the response to decreased leptin levels. A reduction in blood levels of leptin is detected by neurons in the arcuate nucleus that contain the peptides NPY and AgRP. These arcuate nucleus neurones inhibit the neurons in the paraventricular nuclei that control the release of TSH and ACTH from the pituitary, In addition, they activate the neurones in the lateral hypothalamus that stimulate feeding behaviour. Some of the activated lateral hypothalamic neurons contain the peptide MCH (melanin-concentrating hormones).

Injection of NPY/AgRP mimics low concentration of leptin, increasing appetite.

Question 15

How does the competition for activation of the MC4 receptor work?

Answer 15

One way that a-MSH, an anorectic peptide and AgRP, an orexigenic peptide exert opposite effects on metabolism and feeding behaviour is via an interaction with the MC4 receptor on some hypothalamic neurons. While a-MSH stimulates the MC4 receptor, AgRP inhibits it.

MC4 receptor:
+ aMSH acts as an agonist, so activates it and inhibits feeding behaviour.
- AgRP acts as an antagonist, blocking the aMSH from binding to the receptor.

Question 16

How is feeding controlled by Lateral Hypothalamic Peptides (2 other players)

Answer 16

*LH neurons stimulating feeding behavior
contain:

–Melanin-concentrating hormone (MCH)
*Widespread connections in the brain
*Prolongs consumption

–Orexin
*Also with widespread cortical connections
*Promotes meal initiation
This peptide is also connected to sleep -eg. Narcolepsy having very low levels of Orexin. It also plays a role in addiction.

Question 17

How is bodyweight and food intake controlled?

Answer 17

Hypothalamus and the control of
bodyweight and food intake:
*Motivated behaviour
*Accurately regulated by leptin produced by
adipose tissue and hypothalamic peptides
*Hypothalamus plays an important role in
regulating feeding behaviour (long term)
* Disruption of this regulation leads to
–Hyperphagia
–Anorexia
–Bulimia nervosa

Question 18

How is feeding regulated in the short term?

Answer 18

*Motivation to eat also depends on:
-How long it has been since last meal
-How much one has already eaten
-What type of food has already been eaten

Question 19

What is satiety?

Answer 19

*Satiety is the feeling of fullness and the
suppression of hunger for a period of time
after a meal
*Feelings of satiety can influence how soon
and how much you next eat
*The feeling of satiety occurs due to a
number of bodily signals that begin when a
food or drink is consumed and continue as
it enters the gut and is digested and
absorbed

Question 20

What is the model for short term regulation of feeding?

Answer 20

Before meal:
- Satiety signals decrease continuously until 0
- This will induce feeding
- Orexigenic signals are high

During meal:
- Satiety signals continually increase.
- Orexigenic signals decrease along with feeding.

After meal:
-Will start to decrease again.
- Orexigenic signals will start to increase again.

Question 21

What is the satiety cascade?

Answer 21

*Three phases: cephalic, gastric, substrate (intestinal)

1) Cephalic stage:
Sight of pancakes (before eating)
PNS and enteric activation
Saliva secretion
Digestive juices secretion

2) Gastric stage:
Much more intense secretions
when chewing/swallowing

3) Substrate (intestinal) stage:
CCK released by intestine in response to fatty food. Acts on vagus nerve to inhibit feeding
Insulin is a satiety signal

Question 22

What happens in the Caphalic phase?

Answer 22

Short-Term Regulation of Feeding
(Cephalic phase)
*Cephalic: hunger
–Ghrelin released when stomach is empty
–Activates NPY/AgRP-containing neurons in
arcuate nucleus
–Removal of ghrelin-secreting cells of stomach
thought to cause loss of appetite. Eg. In bariatric surgery, when a large portion of the stomach is taken out, the Ghrelin-secreting cells are lost with it. This plays a role in the treatment for morbid obesity.

Question 23

What are the short term regulation of feeding satiety signals?

Answer 23

–Gastric distension signals brain via vagus nerve.
–Works synergistically with CCK released in intestines in response to certain foods
–Insulin also released by β cells of the pancreas— induces satiety by acting on arcuate nucleus of the hypothalamus

Question 24

What do we eat?

Answer 24

*We like food
–Hedonic aspect
*We want food
–Drive reduction
*Liking and wanting mediated in part by separate brain circuits
*Dopaminergic system involved in wanting/
craving (or liking?)

Question 25

What are the natural rewards?

Answer 25

• Food
• Water
• Sex
• Nurturing

Question 26

How does dopamine contribute to motivation? What experiment was formed to test this?

Answer 26

There was a box with levers. A mouse was let into the box with each of the levers attached to a specific part of its brain. If the rat pushes the lever, that part of the brain would be shocked. This means the rat lost interest in the levers not attached to the reward centres such as the nucleus accumbens or the Ventral Tegmental Area.

They also discovered dopamine was the main neurotransmitter involved in rewards. They discovered this through micro-dialysis experiments. Took mice and rats and planted probes into different brain regions, which measured the amount of neurotransmitters released by each region. Eg. when they were given food.

Problems start when these regions are continuously over stimulated - leading to addictions.

Question 27

What are the stages in the addiction cycle?

Answer 27

1) Acute Reinforcement/Social Drug-Taking
- People usually start alcohol, smoking etc due to peer pressure at a young age. They might go out every Sunday for a drink and stop that there.
2) Escalating/Compulsive Use
- They might start to increase the dose bit by bit to increase tolerance.
3) Dependance
- The emergence of physical and emotional symptoms with the substance isn’t taken.
4) Withdrawl
- When these symptoms are apparent. Eg. in Heroin addicts, withdrawl symptoms include: vomiting, diarrhoea, excruciating abdominal pain, joint aches, tremours etc. Psychological conditions too: depression, anxiety, social withdrawl and craving for the drug.

• This may lead to relapse into taking the drug, in an attempt to self medicate. This is a negative reinforcement because the motivation there is to not feel those symptoms.

In people that are dependent, the reward system is actually suppressed.

Question 28

What is reinforcement and reward?

Answer 28

*Positive reinforcement (anything added
that follows a behavior that makes it more
likely that the behavior will occur again in
the future)

*Negative reinforcement (a response or
behavior is strengthened by stopping,
removing or avoiding a negative outcome
or aversive stimulus)

Question 29

What is the role of D2 receptors in obesity?

Answer 29

This is seen in people with binge-eating disorder.
In obese people, there is a down regulation in D2 receptors. This is a decrease in the receptor where dopamine binds to. These people eat more food in an attempt to stimulate the D2 receptors - for the reward system.

The higher the BMI, the lower the D2 receptors.

Question 30

What is the role of D2 receptors in drug abusers?

Answer 30

A reduction in dopamine levels is found in people addicted to cocaine, amphetamine, alcoholics, heroine etc.

The addiction is to activate the suppressed reward system.

Question 31

What are the key neural circuits of reinforcement?

Answer 31

There are other regions involved with addiction.
Eg. Hippocampus associated with memory - memory of the substance of abuse. Stronger in people with dependence.

Eg. Amygdala - associated with emotions - they are likely to have an emotional connection with the substance.

Question 32

What is operant behaviour?

Answer 32

These can be tested by putting mice and rats in containers where they have a drug of abuse. The container is attached to a probe, which is implanted in a region of brain. If the rat pulls the lever, they have a small amount of the drug injected into that part of the rat’s brain. When implanted in eg. nucleus accumbens, they get a rewarding effect. The mouse would not have any interest in pressing the lever if it is the part of the brain stimulated is not associated with reward.

Question 33

What is microdialysis?

Answer 33

*Measuring neurotransmitter release in vivo
*Association with behaviour parameters

Question 34

How does dopamine help with reinforcement?

Answer 34

*Dopamine release in the nucleus
accumbens is correlated with motivation
but not liking (hedonic)
*Its also release in anticipation of reward
*Note that dopamine also involved in
movement

Question 35

How is serotonin, food and mood connected?

Answer 35

*Mood and food are connected–5HT in hypothalamus
*Rises in anticipation of food
*Spike during a meal (carbohydrates in particular)
*Association anorexia nervosa, bulimia with
depression (low serotonin)

When we expect to be eating food, serotonin is secreted, whilst eating food, another wave of serotonin is released.

Question 36

What role does the integration of hypothalamus with the cortex and periphery play in motivation?

Answer 36

The hypothalamus is linked to pretty much all of these regions of the brain mentions eg. brain stem, Gut, nucleus accumbens, amygdala and also the cortex and prefrontal cortex.

In recent years, another factor to effect motivation was discovered to be gut microbiota, which releases metabolites.