Sleep

Question 1

What is meant by brain rhythms?

Answer 1

The brain has evolved a variety of systems for rhythmic control – most striking example is our sleep/wake cycle.

Question 2

Where do brain rhythms originate form?

Answer 2

The earth has a rhythmic environment – temperature, precipitation and daylight vary with the seasons.

In order to compete effectively and survive, an animal’s behaviour must oscillate with its environment.

Question 3

What is the EEG?

Answer 3

The electroencephalogram (EEG) is a measurement of electrical activity generated by the brain and recorded from the scalp.

Question 4

How does an EEG work?

Answer 4

Involves non-invasive electrodes placed on standard positions on the head – connected to amplifiers and a recording device.

Question 5

What is the use of EEGs?

Answer 5

Today, the EEG is used primarily to help diagnose certain neurological disorders (e.g. seizures in epilepsy).

Question 6

What does the EEG measure?

Answer 6

EEG measures the combined activity of a large number (1000s) of similarly orientated neurons.
EEG reflects summed post-synaptic activity of large cell ensembles.

Question 7

What is required for a successful EEG to occur?

Answer 7

Requires synchronous activity across groups of cells.

The amplitude of an EEG signal depends upon how synchronous the activity of the neurons is.

When a group of cells is excited the tiny signals sum to generate a large surface signal.

Question 8

What factor detrimentally affects an EEG result?

Answer 8

Timing is everything – the same amount of excitation can occur, but at irregular intervals resulting in a small summed signal.

Question 9

How are EEG signals categorised?

Answer 9

EEG rhythms correlate with states of behaviours

EEG rhythms are categorised by their frequency range.

Question 10

What are the common EEG rhythms associated with Sleep?

Answer 10

A high-frequency low-amplitude associated with alertness and waking (or dreaming…).

A low-frequency high-amplitude associated with non-dreaming sleep or coma.

Question 11

What are the 2 ways synchronous brain rhythms are generated?

Answer 11

Via:

• Pacemakers
• Collective Behaviour

Question 12

How do pacemakers generate synchronous brain rhythms?

Answer 12

Synchronous rhythms can be led by a central clock or pacemaker (e.g. thalamus).

Question 13

What generates synchronous rhythms by collective behaviours?

Answer 13

Some rhythms of the cerebral cortex do not depend on a thalamic pacemaker – rely instead on collective interactions of cortical neurons themselves.

Synchronous rhythms can arise from the collective behaviour of cortical neurons themselves`

Question 14

What is the major pacemaker of the body?

Answer 14

The thalamus, with its vast input to the cerebral cortex, can act as a pacemaker.

Question 15

How does the thalamus produce synchronous brain rhythms?

Answer 15

Synaptic connections between excitatory and inhibitory thalamic neurons force each individual neuron to conform to the rhythm of the group.

Coordinated rhythms are then passed to the cortex by thalamocortical axons.

Thus, a relatively small group of centralised thalamic cells can compel a much larger group of cortical cells.

Question 16

How does collective behaviour generate synchronous rhythms?

Answer 16

Excitatory and inhibitory interconnections of neurons result in a co-ordinated, synchronous pattern of activity.

This can remain localised or spread to encompass larger regions of the cortex.

Question 17

What is the significance of brain rhythms?

Answer 17

Cortical rhythms parallel many interesting human behaviours

Question 18

What are the functions of brain rhythms?

Answer 18

One plausible hypothesis is that most brain rhythms have no direct function – instead they are by-products.

However, even if brain rhythms don’t have a function, they provide us with a convenient window on the functional states of the brain.

Question 19

What is sleep?

Answer 19

Sleep is a readily reversible state of reduced responsiveness to, and interaction with, the environment.

Question 20

What is the significance of sleep?

Answer 20

Sleep may be universal among higher invertebrates and perhaps amongst all animals (e.g. fruit fly Drosophila sleeps).
Prolonged sleep deprivation can be devastating to proper functioning.
However, we can stave off sleep… but not forever…

Question 21

What are the functional states of the brain?

Answer 21

• Wakefulness
• Non-REM sleep
  Body capable of involuntary movement, rarely accompanied by vivid, detailed dreams.
• REM sleep
  Body immobilised, accompanied by vivid, detailed dreams.

Question 22

Outline the bodily changes that occur during Non-REM sleep

Answer 22

• Temperature decreases
• Heart rate drops
• Breathing decreases
• Brain energy consumption falls

Question 23

How does the body respond in REM sleep?

Answer 23

• Big temperature decrease
• Irregular decreased heart rate
• Irregular decreased breathing
• Large increase in brain energy consumption

Question 24

How can we identify different stages of sleep?

Answer 24

EEG stages can be subdivided to indicate depth of sleep

Stages 1-4

Question 25

What is the initial stage of the sleep cycle?

Answer 25

Each night begins with a period of non-REM sleep.

Question 26

How often does the sleep cycle repeat in a night?

Answer 26

Sleep stages are then cycled throughout the night, repeating approximately every 90 minutes.

Question 27

How does sleep differ throughout the night?

Answer 27

As night progresses, there is a shift from non-REM to REM sleep.

Question 28

Why do we sleep?

Answer 28

No single theory of the function of sleep is widely accepted, although most reasonable ideas fall into two categories – theories of restoration and adaptation.

Question 29

What role does sleep have in restoration?

Answer 29

We sleep to rest and recover and to prepare to be awake again.

Question 30

How does sleep aid adaptation?

Answer 30

We sleep to protect ourselves (e.g. hide from predators) and to conserve energy.

Question 31

What is the neural mechanism of wakefulness?

Answer 31

During wakefulness, there is an increase in brain stem activity.

Question 32

Why is there increased brain activity during wakefulness?

Answer 32

Several sets of neurons increase rate of firing in anticipation of wakening and enhance the wake state (e.g. ACh, 5-HT, NE and histamine).

Question 33

How does brain activity differ in wakefulness and sleep?

Answer 33

Collectively, these neurons synapse directly brain regions including the thalamus and cerebral cortex.

Increase in excitatory activity suppresses rhythmic forms of firing in the thalamus and cortex present during sleep.

Question 34

How do neural mechanisms alter in sleep?

Answer 34

During sleep, there is a decrease in brain stem activity.

Question 35

Why is there decreased brain activity during sleep?

Answer 35

Several sets of neurons decrease rate of firing during sleep (e.g. ACh, 5-HT and NE).

Question 36

When does neural firing increase in sleep?

Answer 36

Cholinergic neurons in pons shown to increase the rate of firing to induce REM sleep.

Question 37

How do brain rhythms aid sleep?

Answer 37

Rhythmic forms of firing in the thalamus shown to block the flow of sensory information to the cortex.
However, other sleep-promoting factors also involved in promoting sleep…

Question 38

What are the 4 main sleep promoting factors?

Answer 38

• Adenosine
• Melatonin
• Nitric Oxide
• Inflammatory Factors

Question 39

How does adenosine promote sleep?

Answer 39

Adenosine receptor activation decreases heart rate, respiratory rate and smooth muscle tone (decreasing blood pressure).

Question 40

What is adenosine?

Answer 40

Adenosine is a building block for DNA, RNA and ATP.

Question 41

How are adenosine receptors manipulated to inhibit sleep?

Answer 41

Adenosine receptor antagonists (e.g. caffeine) promote wakefulness.

Question 42

What is melatonin?

Answer 42

Melatonin is a hormone secreted by the pineal body at night.

Question 43

How does melatonin promote sleep?

Answer 43

Over-the-counter medication for symptoms of jet-lag.

Shown to initiate and maintain sleep – role in natural sleep-wake cycle remains unclear.

Question 44

What is the role of Nitric oxide?

Answer 44

Nitric oxide (NO) is a potent vasodilator.
Decreases smooth muscle tone (decreasing blood pressure).
NO also stimulates adenosine release.

Question 45

How do inflammatory mediators aid sleep?

Answer 45

Sleepiness is a familiar consequence of infection (e.g. cold, flu).
Cytokines (e.g. interleukin-1) stimulates the immune system to fight infections.
Interleukin-1 levels shown to promote non-REM sleep –evidence for adaptation theory?

Question 46

What are circadian rhythms?

Answer 46

Almost all land animals coordinate behaviour according to circadian rhythms – the daily cycles of daylight and darkness that result from the spin of the Earth

Question 47

Why are rhythms so important for physiological function?

Answer 47

Most physiological processes also rise and fall with daily rhythms (e.g. temperature, hormone levels).

Question 48

Why are circadian rhythms so significant?

Answer 48

If cycles of daylight and darkness are removed from an animal’s environment, circadian rhythms continue.

Question 49

What determines the circadian rhythms?

Answer 49

Primary clocks for circadian rhythms are biological (“brain clocks”).

Question 50

What are ‘brain clocks’?

Answer 50

Environmental time cues (e.g. light-dark, temperature, humidity) are collectively termed zeitgebers.

Question 51

What is the consequence of having no ‘brain clock’?

Answer 51

It is quite difficult to separate a human from all possible zeitgebers – even inside a laboratory (e.g. people coming/going provide time cues).
Isolation studies are therefore best conducted in deep caves.

If humans are separated from all possible zeitgebers, they are said to be in a “free-running” state – internal biological clock of approximately 24.5-25.5 hours.

Question 52

What is the SCN?

Answer 52

The suprachiasmatic nucleus (SCN) is a small nucleus of the hypothalamus, located just above the optic chiasm.

Question 53

What is the role of the SCN?

Answer 53

It receives retinal innervation and synchronises circadian rhythms with the daily light-dark cycle.

Question 54

What happens when the SCN is removed from animals?

Answer 54

With no SCN, animals had fluctuating sleep and temperature - no pattern
SCN inhibition does not abolish sleep – animals will continue to coordinate sleep with light-dark cycles if they are present.

Question 55

What cells are responsible for sycnhronising the SCN to the circadian rhythms?

Answer 55

Retinal cells synchronising the SCN are not rods or cones – they are specialised photoreceptor cells expressing the photopigment melanopsin.

Question 56

How are melanopsin photoreceptors activated?

Answer 56

Photoreceptors expressing melanopsin are slowly excited by light and can detect changes in luminosity.

Question 57

How does melanopsin photoreceptor activation, synchronise the SCN?

Answer 57

Project directly to the SCN, inhibiting the production of melatonin by the pineal gland – melatonin involved in inducing the onset of sleep.