6B - Nervous Coordination

Question 1

Describe the polarisation of a neurone at rest.

Answer 1

The membrane is polarised.

Question 2

For a neurone at rest, which part of the membrane is more positive: inside or outside?

Answer 2

Outside

Question 3

At rest, are the charge across a neurone membrane the same?

Answer 3

No, there are more positive charges outside compare to inside the neurone.

Question 4

Define resting potential.

Answer 4

The potential difference across a neurone membrane when it is at rest.

Question 5

What is the value of the resting potential for a neurone?

Answer 5

About -70mV.

Question 6

What causes the resting potential across a neurone membrane?

Answer 6

• Na⁺-K⁺ pumps move 3 sodium ions out of the cell for every 2 potassium into the cell
• Na⁺ ions can’t move back in, but K⁺ ions can move back out of the neurone using potassium ion channels
• There is more positive charge outside of the neurone compared to inside it, which causes there to be a resting potential

Question 7

How does a sodium-potassium pump work?

Answer 7

Pumps 3 Na⁺ ions out of the cell for every 2 K⁺ ions that go into the neurone.

Question 8

Do sodium-potassium pumps require energy?

Answer 8

Yes

Question 9

What sort of transport is involved in potassium ion channels?

Answer 9

Facilitated diffusion

Question 10

Which way do Na⁺-K⁺ pumps move sodium and potassium?

Answer 10

• Sodium -> Out of the cell

* Potassium -> Into the cell

Question 11

What role do potassium ion channels have in a neurone membrane?

Answer 11

They allow potassium to move out of the cell.

Question 12

What are the 3 types of transport protein involved in neurone membranes?

Answer 12

• Na⁺-K⁺ pump
• K⁺ channel
• Na⁺ channel

Question 13

Describe the polarisation of a neurone when stimulated.

Answer 13

Depolarised

Question 14

What is an action potential?

Answer 14

When a stimulus triggers sodium ion channels to open, causing a rapid change in potential difference.

Question 15

What are the stages of an action potential?

Answer 15

1) At rest
2) Stimulus
3) Depolarisation
4) Repolarisation
5) Hyperpolarisation
6) Resting potential

Question 16

Describe an action potential (including membrane potentials).

Answer 16

1) At rest:
• The membrane is polarised at a constant -70mV
• Na⁺ and K⁺ channels are closed
2) Stimulus:
• The neurone cell membrane is excited, causing Na⁺ channels to open
• Sodium ions diffuse into the neurone
• This causes the potential difference to become less negative
3) Depolarisation:
• If the potential difference reaches the threshold (-55mV), more Na⁺ channels open
• More sodium ions diffuse into the neurone
• The potential difference becomes rapidly more positive
4) Repolarisation:
• At about +30mV, Na⁺ channels close, while K⁺ channels open
• Potassium ions can diffuse out of the neurone
• The potential difference becomes more negative
5) Hyperpolarisation:
• K⁺ channels are slow to close, so there’s some “overshoot” when too many potassium ions diffuse out of the neurone
• Potential difference becomes slightly more negative than resting potential (-90mV)
6) Resting potential
• Ion channels are reset and the Na⁺-K⁺ pump returns the potential difference to the resting potential, then maintains it

Question 17

What is the order of the events and channel openings in an action potential?

Answer 17

• Stimulus
• Na⁺ channels open
• Depolarisation
• Na⁺ channels close and K⁺ channels open
• Repolarisation
• Hyperpolarisation and K⁺ channels close
• Resting potential

Question 18

What is the usual threshold voltage in an action potential?

Answer 18

-55mV

Question 19

What is the usual peak voltage in an action potential?

Answer 19

+30mV

Question 20

What is the usual hyperpolarisation voltage in an action potential?

Answer 20

-90mV

Question 21

Give all of the important voltages in an action potential.

Answer 21

• Resting potential = -70mV
• Threshold potential = -55mV
• Peak voltage = +30mV
• Hyperpolarisation = -90mV

Question 22

Remember to practise drawing out the shape of an action potential.

Answer 22

See diagram pg 146 of revision guide.

Question 23

What is the refractory period?

Answer 23

The period after an action potential, during which the neurone cell membrane can’t be excited again.

Question 24

What causes the refractory period?

Answer 24

The ion channels are recovering and can’t be made to open.

Question 25

Where on the graph of an action potential is the refractory period?

Answer 25

From the peak voltage to the start of the resting potential.

Question 26

Remember to practise writing out the order of an action potential.

Answer 26

Pg 146 of revision guide

Question 27

To what order is the potential difference across a cell membrane?

Answer 27

mV

Question 28

Describe how an action potential moves along a neurone.

Answer 28

1) When an action potential happens, some of the sodium ions that enter the neurone diffuse sideways.
2) This causes sodium ion channels in the next region to open, so sodium ions diffuse into that part.
3) This causes a wave of depolarisation to travel along the membrane.
4) The wave moves away from the parts of the membrane in the refractory period, because these can’t fire an action potential.

Question 29

Why does the wave of repolarisation not move the wrong way along a neurone (i.e. back along where it has just travelled)?

Answer 29

The part that is has just covered is in its refractory period, so it cannot trigger an action potential.

Question 30

What is the term for the movement of an action potential along a neurone?

Answer 30

Wave of depolarisation

Question 31

What is the purpose of the refractory period?

Answer 31

• Action potentials remain as discrete impulses
• Limit to the frequency at which nerve impulses can be transmitted
• Action potentials are unidirectional

Question 32

Does the strength of a stimulus have an effect on the peak voltage of the action potential across a membrane?

Answer 32

No, once the threshold is reached, an action potential will always fire with the same change in voltage.

Question 33

What happens if the threshold voltage in an action potential is not reached?

Answer 33

The action potential will not fire.

Question 34

How does the strength of a stimulus affect the action potential difference?

Answer 34

• It has NO effect on the peak voltage reached

* But a bigger signal causes action potentials to fire more frequently

Question 35

Remember to practise drawing the graphs for an action potential by a small and large stimulus.

Answer 35

See diagram pg 147 of revision guide

Question 36

What 3 factors affect the speed of conduction of action potentials?

Answer 36

1) Myelination
2) Axon diameter
3) Temperature

Question 37

What is myelination of a neurone?

Answer 37

When the neurone has a myelin sheath, which is an electrical insulator.

Question 38

What is a Schwann cell?

Answer 38

The type of cell that myelin sheaths are made of.

Question 39

Where are Schwann cells found?

Answer 39

On the neurones of the peripheral nervous system.

Question 40

What are the spaces between Schwann cells called?

Answer 40

Nodes of Ranvier

Question 41

What are nodes of Ranvier?

Answer 41

Small patches of bare membrane between Schwann cells where Na⁺ channels are concentrated.

Question 42

Describe the structure of a myelinated motor neurone.

Answer 42

• Cell body with nucleus
• Dendrites spread out on one side of the cell body
• Axon is on the other side of the cell body
• Schwann cells are along the axon, with small gaps between them (nodes of Ranvier)
• Axon ends in axon terminal (which joins to the effector)

Question 43

Remember to practise drawing out the structure of a myelinated motor neurone.

Answer 43

Pg 148 of revision guide

Question 44

On a myelinated motor neurone, what do the dendrites do?

Answer 44

Connect with other neurones to receive the impulse.

Question 45

On a myelinated motor neurone, what does the axon terminal do?

Answer 45

Connects to the effector.

Question 46

How does myelination affect the speed of conduction of an action potential and why?

Answer 46

Speeds it up, because:
• Along the axon are Schwann cells that are insulators
• Depolarisation can only happen at the nodes of Ranvier between them, which have many sodium channels
• The cytoplasm conducts enough electrical charge to depolarise the next node, so the impulse jumps between them by saltatory conduction
• This is faster than normal conduction

Question 47

What is the term for the impulse jumping between nodes of Ranvier in a myelinated neurone?

Answer 47

Saltatory conduction

Question 48

What allows the impulse to jump between nodes of Ranvier in a myelinated neurone?

Answer 48

The neurone’s cytoplasm conducts enough charge to depolarise the next node.

Question 49

Does wide axon diameter speed up or slow down conduction along a neurone?

Answer 49

Speeds up

Question 50

How does wide axon diameter affect the speed of conduction along a neurone and why?

Answer 50

Speeds it up, because:
• There is less resistance to the flow of ions in the cytoplasm
• So depolarisation reaches other parts of the neurone quicker, transmitting the impulse quicker

Question 51

How does temperature affect the speed of conduction along a neurone and why?

Answer 51

Speeds it up (until about 40°C), because:
• Ions diffuse faster
• BUT above 40°C, the proteins begin to denature

Question 52

Why does the speed of conduction along a neurone decrease above 40°C?

Answer 52

The proteins involved begin to denature.

Question 53

What is a synapse?

Answer 53

A junction between:
• A neurone and another neurone
OR
• A neurone and an effector call

Question 54

What is the gap between the cells in a synapse called?

Answer 54

Synaptic cleft

Question 55

What is the neurone before a synapse called?

Answer 55

Presynaptic membrane

Question 56

What is the swelling on the presynaptic neurone called?

Answer 56

Presynaptic knob

Question 57

What is found in the presynaptic membrane?

Answer 57

Synaptic vesicles filled with neurotransmitters.

Question 58

What is on the surface of the postsynaptic membrane?

Answer 58

Receptors

Question 59

Give two examples of neurotransmitters.

Answer 59

• Acetylcholine

* Nonadrenaline

Question 60

Describe briefly how a synapse works in general.

Answer 60

1) Action potential reaches end of neurone
2) This causes neurotransmitters to be released into the synaptic cleft, which diffuse across it
3) These then bind to specific receptors on the postsynaptic membrane
4) This triggers an action potential, muscle contraction or hormone secretion
5) The neurotransmitter is removed from the cleft to stop the response happening over and over

Question 61

What type of synapse do you need to know about?

Answer 61

Cholinergic synapse (one that uses acetylcholine as a neurotransmitter)

Question 62

Describe how a cholinergic synapse works.

Answer 62

1) Action potential arrives at synaptic knob of presynaptic neurone
2) This stimulates voltage-gated calcium ion channels to open
3) Ca²⁺ ions diffuse into the synaptic knob
4) Influx of Ca²⁺ ions into the synaptic knob causes the synaptic vesicles to move to the presynaptic membrane, where they then fuse with it
5) The vesicles release acetylcholine into the synaptic cleft
6) Acetylcholine diffuses across the synaptic cleft and binds to the cholinergic receptors on the postsynaptic membrane
7) This causes Na⁺ channels in be postsynaptic membrane to open
8) Influx of Na⁺ ions causes depolarisation, which triggers an action potential if the threshold is reached
9) Acetylcholine is removed by acetylcholinesterase and the products are re-absorbed by the presynaptic neurone

Question 63

What are voltage-caged ion channels?

Answer 63

Ion channels that only open at a certain voltage.

Question 64

What is the technical term for vesicles releasing acetylcholine into the synaptic cleft?

Answer 64

Exocytosis

Question 65

What is the name of the enzyme that breaks down acetylcholine?

Answer 65

Acetylcholinesterase

Question 66

What is the shorthand for acetylcholine?

Answer 66

ACh

Question 67

What is the shorthand for acetylcholinesterase?

Answer 67

AChE

Question 68

Why are synapses unidirectional?

Answer 68

They only have receptors on the postsynaptic membrane.

Question 69

What are the different types of neurotransmitter?

Answer 69

• Excitatory

* Inhibitory

Question 70

What are excitatory neurotransmitters?

Answer 70

Those that depolarise the postsynaptic membrane, making it fire an action potential if the threshold is reached.

Question 71

What are inhibitory neurotransmitters?

Answer 71

Those that hyperpolarise the postsynaptic membrane and prevent it from firing an action potential.

Question 72

Are neurotransmitters either excitatory or inhibitory?

Answer 72

No, a single neurotransmitter can be both, depending on the location where they are.

Question 73

Give an example of where acetylcholine is excitatory.

Answer 73

• CNS

* Neuromuscular junctions

Question 74

Give an example of where acetylcholine is inhibitory.

Answer 74

• Heart

Question 75

Describe how an inhibitory synapse works.

Answer 75

• Pre-synaptic membrane releases neurotransmitter that binds to the Cl⁻ channels on the postsynaptic membrane
• This causes the Cl⁻ channels to open, so Cl⁻ moves into the postsynaptic membrane by facilitated diffusion
• The binding of the neurotransmitter also causes the opening of nearby K⁺ channels, so K⁺ moves out of the postsynaptic membrane and into the synapse
• The combined effect of the Cl⁻ moving in and K⁺ moving out hyperpolarises the membrane, making it harder to trigger an action potential

Question 76

What is summation?

Answer 76

Where the effect of neurotransmitter released from many neurones (or one neurone stimulated rapidly) is added together.

Question 77

What are the two types of summation?

Answer 77

• Spatial summation

* Temporal summation

Question 78

What is spatial summation?

Answer 78

• When many neurones connect to one neurone
• A small amount of neurotransmitter released from each can be enough together to reach the threshold and trigger an action potential

Question 79

Does spatial summation only involve excitatory neurotransmitters?

Answer 79

No, it can also involve inhibitory neurotransmitters, which can override the effect of the excitatory neurotransmitters.

Question 80

What is temporal summation?

Answer 80

• When two of more nerve impulses arrive in quick succession from the same presynaptic membrane
• A small amount of neurotransmitter released each time can quickly build up to reach the threshold and trigger an action potential

Question 81

What is the advantage of summation?

Answer 81

Synapses can accurately process information, finely tuning the response.

Question 82

What is a neuromuscular junction?

Answer 82

A synapse between a neurone and muscle.

Question 83

What are the two types of synapse you need to be able to compare?

Answer 83

• Cholinergic synapse

* Neuromuscular junction

Question 84

What neurotransmitter and receptors do neuromuscular junctions use?

Answer 84

• Neurotransmitter: Acetylcholine

* Receptor: Nicotinic cholinergic receptors

Question 85

Compare a cholinergic synapse and a neuromuscular junction.

Answer 85

They work in basically the same way, except in the neuromuscular junction:
• Postsynaptic membrane has lots of folds called clefts -> These store acetylcholinesterase
• Postsynaptic membrane has more receptors
• Acetylcholine is always excitatory

Question 86

Remember to practise drawing out the stricture of a neuromuscular junction.

Answer 86

See diagram pg 150 of revision guide

Question 87

What are the folds in the postsynaptic membrane of a neuromuscular junction called?

Answer 87

Clefts

Question 88

What are the clefts in the postsynaptic membrane of a neuromuscular junction for?

Answer 88

They store acetylcholinesterase (an enzyme that breaks down acetylcholine).

Question 89

What are some of the types of drug that can affect a synapse?

Answer 89

• Mimic action of neurotransmitter
• Block receptors
• Inhibit enzymes that break down neurotransmitter
• Stimulate release of neurotransmitter
• Inhibit release of neurotransmitter

Question 90

Predict the effect of this drug:

Molecule with same shape as the neurotransmitter.

Answer 90

Binds to receptors and activate them.

Question 91

Predict the effect of this drug:

Molecule with similar shape to the enzyme that breaks down the neurotransmitter.

Answer 91

Binds to the enzyme, which allows it to slowly accumulate.

Question 92

Predict the effect of this drug:

Molecule with complementary shape to the neurotransmitter.

Answer 92

Breaks down neurotransmitters.

Question 93

Remember to practise practise drawing out and explaining the effect of various drugs that affect synapses.

Answer 93

Pg 151 of revision guide

Question 94

What is skeletal muscle?

Answer 94

The type of muscle used to move.

Question 95

What are some other names for skeletal muscle?

Answer 95

• Striated
• Striped
• Voluntary

Question 96

What attached muscles to bones?

Answer 96

Tendons

Question 97

What holds bones together?

Answer 97

Ligaments

Question 98

How many muscles work in a joint movement?

Answer 98

Two - one relaxes and one contracts.

Question 99

What does the bone at a joint work as?

Answer 99

A lever, giving the muscles something to pull against.

Question 100

Why do muscles work in pairs?

Answer 100

They can only pull, not push.

Question 101

What is the term for two muscles that work together to move a bone?

Answer 101

Antagonistic pairs

Question 102

What is each of the muscles in an antagonistic pair called?

Answer 102

• Contracting muscle -> Agonist

* Relaxing muscle -> Antagonist

Question 103

During a bicep curl upwards, which muscle is the agonist and which is the antagonist?

Answer 103

• Agonist -> Biceps

* Antagonist -> Triceps

Question 104

In the nervous system, what do muscles act as?

Answer 104

Effectors

Question 105

Describe the structure of skeletal muscle.

Answer 105

• Muscle is made up of large bundles of long cells, called muscles fibres
• The cell membrane surrounding each membrane is called the sarcolemma
• Parts of the sarcolemma fold inwards into the sarcoplasm (cytoplasm of a muscle cell). These are called transverse (T) tubules and they help spread electrical impulses throughout the sarcoplasm.
• A network of internal membranes called the sarcoplasmic reticulum runs through the sarcoplasm. It stores and releases Ca²⁺ ions for muscle contraction.
• Muscle fibres have lots of nuclei and lots of mitochondria.
• Muscle fibres also contain lots of long, cylindrical organelles called myofibrils.

(See diagram pg 152 of revision guide)

Question 106

What is the sarcolemma?

Answer 106

The cell membrane that surrounds a muscle fibre cell.

Question 107

What is the sarcoplasm?

Answer 107

The cytoplasm of a muscle fibre cell.

Question 108

What are transverse (T) tubules?

Answer 108

Bits of sarcolemma that fold inwards across a muscle fibre.

Question 109

What is the purpose of transverse (T) tubules?

Answer 109

They help spread electrical impulses throughout the sarcoplasm so they reach all parts of the muscle fibre.

Question 110

What is the sarcoplasmic reticulum?

Answer 110

A network of internal membranes that runs through the sarcoplasmic reticulum.

Question 111

What is the purpose of the sarcoplasmic reticulum?

Answer 111

It stores and released Ca²⁺ ions that are needed for muscle contraction.

Question 112

What important organelles does a muscle cell contain?

Answer 112

• Mitochondria
• Multiple nuclei
• Sarcoplasmic reticulum
• Myofibrils

Question 113

What is the term for muscle cells having many nuclei?

Answer 113

Multinucleate

Question 114

What are myofibrils?

Answer 114

Long, cylindrical organelles in muscle cells that are specialised for contraction.

Question 115

What molecule are myofibrils made of?

Answer 115

Protein

Question 116

Describe the general structure of a myofibril.

Answer 116

Made up of myofilaments:
• Thick myofilaments -> Made of myosin
• Thin myofilaments -> Made of actin

Question 117

What are the thick myofilaments in a myofibril made of?

Answer 117

Myosin

Question 118

What are the thin myofilaments in a myofibril made of?

Answer 118

Actin

Question 119

What type of molecule are myosin and actin?

Answer 119

Proteins

Question 120

How does a myofibril look like under a microscope?

Answer 120

Alternating light and dark bands

Question 121

What do the dark bands in a myofibril contain?

Answer 121

Thick myosin filaments and some overlapping parts of thin actin filaments

Question 122

What do the light bands in a myofibril contain?

Answer 122

Thin actin filaments ONLY

Question 123

What is the name for the dark bands in a myofibril?

Answer 123

A-bands

Question 124

What is the name for the light bands in a myofibril?

Answer 124

I-bands

Question 125

How can you remember the names of the light and dark bands in a myofibril?

Answer 125

• L(I)GHT -> I-bands

* D(A)RK -> A-bands

Question 126

What are the short units in a myofibril called?

Answer 126

Sarcomere

Question 127

What marks each end of a sarcomere?

Answer 127

Z-line

Question 128

What marks the middle of each sarcomere?

Answer 128

M-line

Question 129

How do you remember what the M-line is?

Answer 129

M-line, middle, myosin

Question 130

What is the H-zone?

Answer 130

The part of the sarcomere that contains only myosin filaments.

Question 131

Describe the parts of a sarcomere.

Answer 131

• Z-line at each end of the sarcomere -> Actin is attached to this (A to Z)
• M-line is in the middle of sarcomere -> It is in the middle of myosin
• I-band is the area with just actin
• A-band is the area with myosin and myosin overlapping with actin
• H-zone is the area with just myosin

(See diagram pg 153 of revision guide)

Question 132

Remember to practise drawing out the structure of a sarcomere.

Answer 132

Pg 153 of revision guide

Question 133

What is the theory that explains how muscle contraction works?

Answer 133

Sliding filament theory

Question 134

What is the sliding filament theory?

Answer 134

The way in which myosin and actin filaments slide over one another to make the sarcomeres contract.

Question 135

Describe what happens to A-bands when sarcomeres contract.

Answer 135

Stay the same length

Question 136

Describe what happens to I-bands when sarcomeres contract.

Answer 136

Get shorter

Question 137

Describe what happens to H-zone when sarcomeres contract.

Answer 137

Get shorter

Question 138

Describe what happens to A-bands, I-bands and H-zones when sarcomeres contract.

Answer 138

• A-bands -> Stay the same length
• I-bands -> Get shorter
• H-zones -> Get shorter

Question 139

Describe the structure of a myosin filament.

Answer 139

• Have globular heads that are hinged, so they can move back and forth
• Each head has a binding site for actin and a binding site for ATP

Question 140

Describe the structure of an actin filament.

Answer 140

• Have binding sites for myosin heads

* These are called actin-myosin bonding sites

Question 141

What is tropomyosin and what does it do?

Answer 141

• A protein found between actin filaments

* It helps myofilaments move past each other

Question 142

In a muscle’s resting state, what does tropomyosin do?

Answer 142

• Tropomyosin blocks the actin-myosin binding site
• So the myofilaments can’t slide past each other because the myosin heads can’t bind to the actin-myosin binding site on the actin filaments

Question 143

Describe how a muscle contraction is triggered.

Answer 143

1) Action potential from a motor neurone depolarises the sarcolemma. This depolarisation spreads down the T-tubules to the sarcoplasmic reticulum.
2) This causes the sarcoplasmic reticulum to release stored Ca²⁺ ions into the sarcoplasm.
3) Ca²⁺ ions bind to a protein attached to tropomyosin, causing the tropomyosin to change shape and pulling it out of the binding site, so it is revealed.
4) The myosin head can now bind to the binding site (forming an actin-myosin cross bridge).
5) Ca²⁺ ions also activate ATP hydrolyse, which hydrolyses ATP to provide energy for the myosin head to bend, which pulls the actin along in a rowing-like motion.
6) Another ATP molecule is hydrolysed to break the actin-myosin cross bridge.
7) The myosin head moves back and reattaches to another binding site.
8) This process is repeated multiple times as long as Ca²⁺ ions are present.

Question 144

Do Ca²⁺ ions bind to tropomyosin?

Answer 144

No, they bind to a protein in tropomyosin, which changes its shape.

Question 145

What is the name for a myosin head joined to actin?

Answer 145

Actin-myosin cross bridge

Question 146

What is ATP used for in muscle contraction?

Answer 146

• Moving the myosin head during contraction

* Breaking the actin-myosin cross bridge

Question 147

Describe how muscle contraction is stopped.

Answer 147

• When the muscle stops being stimulated, Ca²⁺ ions leave their binding sites and are actively transported back into the sarcoplasmic reticulum
• This causes the tropomyosin to move back to blocking the actin-myosin binding sites
• The actin filaments slide back to their relaxed position, which lengthens the sarcomere

Question 148

How do Ca²⁺ ions leave the sarcoplasm once contraction is finished?

Answer 148

Active transport into the sarcoplasmic reticulum

Question 149

Remember to practise writing and drawing out the process of muscle contraction.

Answer 149

Pg 154 of revision guide

Question 150

What are the 3 ways of generating ATP for muscle contraction?

Answer 150

1) Aerobic respiration
2) Anaerobic respiration
3) ATP-Phosphocreatine (PCr) system

Question 151

Describe briefly how ATP is produced in aerobic respiration.

Answer 151

Oxidative phosphorylation in the cells’ mitochondria.

Question 152

Describe briefly how ATP is produced in anaerobic respiration.

Answer 152

Glycolysis, which has an end product of pyruvate (which is converted back to lactate and can cause muscle fatigue).

Question 153

Describe how ATP is produced by ATP-Phosphocreatine system.

Answer 153

• A phosphate group is taken from PCr and used to phosphorylase ADP
• ADP + PCr -> ATP + Cr
(Cr = Creatine)

Question 154

What are the advantages and disadvantages of using an ATP-Phosphocreatine system to generate ATP?

Answer 154

ADV.
• Very fast
• Anaerobic and alactic (so lactate is not formed)
DIS.
• PCr runs out very fast

Question 155

What is the equation for an ATP-Phosphocreatine system generating ATP?

Answer 155

ADP + PCr -> ATP + Cr

Cr = Creatine

Question 156

When is each method of generating ATP used?

Answer 156

• Aerobic respiration -> Long period of low-intensity exercise
• Anaerobic respiration -> Short periods of hard exercise
• ATP-Phosphocreatine system -> Very short bursts of vigorous exercise (e.g. a tennis serve)

Question 157

What happens to creatine produced by an ATP-Phosphocreatine system?

Answer 157

• Some of it is broken down into creatinine

* This is removed through the kidneys

Question 158

What sort of people are likely to have high levels of creatinine?

Answer 158

Those who:
• Exercise regularly
• Have a high muscle mass

Question 159

What might very high creatinine levels suggest?

Answer 159

Kidney damage (since it is removed through them)

Question 160

What are the two types of muscle fibres?

Answer 160

• Slow twitch

* Fast twitch

Question 161

Compare the contraction speed of slow twitch and fast twitch muscle fibres.

Answer 161

• Slow twitch -> Slow contractions

* Fast twitch -> Fast contractions

Question 162

Compare which muscles will have a high proportion of slow twitch and fast twitch muscle fibres.

Answer 162

• Slow twitch -> Muscles used for posture

* Fast twitch -> Muscles used for fast movement

Question 163

Compare what slow twitch and fast twitch muscle fibres are good for.

Answer 163

• Slow twitch -> Endurance activities without getting tired

* Fast twitch -> Short bursts of speed and power

Question 164

Compare the respiration type and rate of slow twitch and fast twitch muscle fibres.

Answer 164

• Slow twitch -> Slow energy release + Aerobic respiration

* Fast twitch -> Fast energy release + Anaerobic respiration

Question 165

Compare the mitochondria and blood vessels in slow twitch and fast twitch muscle fibres.

Answer 165

• Slow twitch -> Many mitochondria and blood vessels

* Fast twitch -> Few mitochondria or blood vessels

Question 166

Compare and explain the colour of slow twitch and fast twitch muscle fibres.

Answer 166

• Slow twitch -> Reddish, because they’re rich in myoglobin (protein that stores oxygen)
• Fast twitch -> Whitish, because they don’t have much myoglobin (protein that stores oxygen)

Question 167

Remember to practise drawing out a table comparing slow twitch and fast twitch muscles.

Answer 167

Pg 155 of revision guide