Motivation

Question 1

What is motivation?

Answer 1

Driving force
Physical need
Wanting, liking

Question 2

How odes the hypothalamus regulate motivation?

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

What happens to the energy taken in by our food?

Answer 3

Energy from food is broken down to be taken up by cells. Any excess is stored as glycogen in the liver and muscles. Triglycerides are stored in adipose tissue

Question 4

Explain how energy is released during periods of starvation

Answer 4

During periods of starvation, glycogen is broken down into glucose
In both, anabolic and metabolic reactions are tightly regulated.

Question 5

How is feeding behaviour regulated long term?

Answer 5

Normal energy balance leads to normal adiposity

Prolonged positive energy balance leads to obesity

Prolonged negative energy balance leads to starvation

Question 6

How does the hypothalamus regulate homeostasis?

Answer 6

Transduction of physiological stimuli in blood in specialized region of hypothalamus

Humoral and visceromotor responses are initiated by activation periventricular and medial hypothalamus

Behavioural action depends on lateral hypothalamus

Question 7

How is body weight regulated around a set value?

Answer 7

Body weight is normally stable
If an animal is force fed, it will gain weight

The weight is lost, however, as soon as the animal can regulate its own food intake

Similarly weight lost during a period of starvation is rapidly gained when food is freely available

Question 8

What is parabiosis?

Answer 8

sharing of blood circulation between animals.

Blood borne signals are shared and can affect the hypothalamus.

Question 9

Which hypothalamic nucleus regulates feeding?

Answer 9

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

Question 10

Describe the role of the arcuate nucleus in regulating feeding

Answer 10

After feeding, fat adipose tissues get replenished and release leptin into the blood circulation.

Leptin binds to its receptors in the arcuate nucleus (hypothalamus) signalling to the brain to stop eating - ‘full sensation’

Question 11

What is the significance of the VMH and Lateral hypothalamus?

Answer 11

Important for the regulation of

• Body weight/food intake
• Blood volume/osmolarity: drinking

Question 12

Where is the hypothalamus located?

Answer 12

Hypothalamus located under the thalamus at the base of the brain

Question 13

Where in the hypothalamus is the arcuate nucleus found?

Answer 13

At the bottom part of the third ventricle is where the arcuate nucleus is found

Question 14

Describe the location of other hypothalamic nuclei

Answer 14

The paraventricular nuclei is adjacent to the third ventricle and below it is the lateral hypothalamus area

Question 15

How was the significance of VMH proved?

Answer 15

VMH lesion caused excessive eating to the point where the mouse became obese - showing the ventral medial hypothalamus is crucial in regulating body weight

Question 16

What is the consequence of VMH lesion?

Answer 16

VMH plays a role in controlling the cessation of eating

Damage to the VMH results in prolonged and dramatic weight gain

Question 17

What are the effects of lesions to the VMH and LH?

Answer 17

Lateral hypothalamic syndrome: diminished appetite for food; anorexia

Ventromedial hypothalamic syndrome: overeating and obesity
Both related to leptin signaling

Question 18

What is the effect of elevated leptin levels?

Answer 18

Anorexic response

Rise in leptin levels in blood is detected by arcuate nucleus neurons that contain the peptides 𝜶MSH and CART
These neurons project axons to the lower brainstem and spinal cord, paraventricular nucleus of the hypothalamus, and inhibit the lateral hypothalamus

Question 19

What is the role of the projections to the LH?

Answer 19

Each of these connections contributes to the coordinated humeral, visceromotor and somatic motor responses to increased leptin levels

Question 20

What is the result of decreased leptin levels?

Answer 20

Orixegenic response

Reduction on blood levels of leptin detected by arcuate nucleus neurons containing peptides NPY and AgRP
These arcuate nucleus neurons inhibit paraventricular nuclei controlling release of TSH and ACTH from pituitary (via 𝜶MSH and CART)

They activate neurons in lateral hypothalamus that stimulate feeding behaviour
Some of the activated lateral hypothalamic neurons contain the peptide MCH (melanin-concentrating hormone)

Question 21

Describe the competition for the MC4R

Answer 21

One way 𝜶MSH (anorectic peptide) and AgRP (orexigenic peptide) exert opposite effects on metabolism and feeding behaviour is via interaction with the MC4 receptor on some hypothalamic neurons

Question 22

Describe how leptin levels effect MC4R competition

Answer 22

When you’ve eaten well there is increased leptin in blood circulation causing an increase in 𝜶MSH and decrease AgRP stimulation. 𝜶MSH then binds to MC4R to inhibit feeding

Question 23

How is the MC4R activated?

Answer 23

While 𝜶MSH (agonist) stimulates the MC4 receptor, AgRP (antagonist) inhibits it

Question 24

What are the 2 other factors contained in LH neurons that stimulate feeding?

Answer 24

• Melanin-concentrating hormone (MCH)

- Orexin

Question 25

Describe the effects of MCH

Answer 25

Widespread connections in the brain

Prolongs consumption

Question 26

Describe the effects of orexin

Answer 26

Also with widespread cortical connections

Promotes meal initiation

Question 27

What are the consequences of disruption to the hypothalamic control of body weight and food intake?

Answer 27

Disruption of this regulation leads to

• Hyperphagia
• Anorexia
• Bulimia nervosa

Question 28

What are the 3 phases of feeding?

Answer 28

Three phases: cephalic, gastric, substrate

Question 29

How do satiety signals control feeding behaviour?

Answer 29

Satiety signals rise in response to feeding
When satiety signals are high, food consumption is inhibited (full feeling).

When the satiety signals falls to zero the inhibition is eliminated and food consumption ensues

Question 30

Outline what occurs during satiation

Answer 30

Sight of food (before eating)
PNS and enteric activation
Saliva & Digestive juices secretion

Much more intense secretions when chewing / swallowing

Question 31

Describe the events of the cephalic phase

Answer 31

Cephalic: hunger
- Ghrelin released when stomach is empty
- Activates NPY/AgRP-containing neurons in the arcuate
nucleus
- Removal of ghrelin-secreting cells of stomach thought to
cause loss of appetite

Question 32

What occurs during the gastric phase of feeding?

Answer 32

Gastric: feeling full
- Gastric distension signals brain via the vagus nerve.
- Works synergistically with CCK released in intestines in
response to certain foods
- Insulin also released by β cells of the pancreas—
important in anabolism

Question 33

Describe the effects of satiety

Answer 33

CCK released by intestine in response to fatty food
Acts on vagus nerve to inhibit feeding
Insulin is a satiety signal

Question 34

What is the effect of serotonin on food intake?

Answer 34

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)

Question 35

Why do we eat?

Answer 35

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 36

What are natural rewards?

Answer 36

Food 
Water
Sex 
Nurturing 
Social interactions

Question 37

Describe the reward system of the brain

Answer 37

These natural rewards activate the mesolimbic system - reward pathway of the brain

This consists of dopaminergic neurons that project from the VTA to the nucleus accumbens where dopamine is released

Question 38

How does addiction occur?

Answer 38

Addictive drugs act on the dopaminergic pathways from the ventral tegmental area to the nucleus accumbens

Question 39

Describe how someone gets addicted

Answer 39

After the initial stages of addiction you start getting rewards making you want to do it again = positive reinforcement behaviour
Increased activation of the mesolimbic pathway

Question 40

How does someone become dependent on an addiction?

Answer 40

Continuation causes some people to become dependent on drugs - withdrawal symptoms and behaviours prevail both physical and psychological

At this stage the addict is no longer taking the drugs to get high but to self medicate and put off the withdrawal symptoms

Question 41

What is positive reinforcement?

Answer 41

anything added that follows a behaviour that makes it more likely that the behaviour will occur again in the future

Question 42

What is negative reinforcement?

Answer 42

a response or behaviour is strengthened by stopping, removing or avoiding a negative outcome or aversive stimulus

Question 43

How is D2 receptor presence different in addiction patients?

Answer 43

D2 receptor decrease in addicted individuals causing lower levels of rewards - the drug they’re addicted to is used in an attempt to stimulate those reward centres

Question 44

What is the significance of the amygdala?

Answer 44

Amygdala is the emotional centre of the brain also involved in the motivational regulation along with the mesolimbic pathway

Question 45

What is microdialysis?

Answer 45

Measuring neurotransmitter release in vivo

Association with behaviour parameters

Question 46

Describe the role of dopamine in motivating behaviours

Answer 46

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 47

What other regions work alongside the hypothalamus in motivation regulation?

Answer 47

There is a strong connectivity between the hypothalamus and the periphery (e.g. leptin and ghrelin release)
There are also projections from the hypothalamus to other brain regions such as reward centres of the brain, emotional centre (amygdala) as well as cognitive centres