Lecture 1 - The Action Of Drugs On Nerve Cell Function 1 & 2

Question 1

Why is the Na-K ATP-are pump referred to as an electrogenic pump?

Answer 1

Creates a charge disparity (between the outside and inside of the membrane)

Question 2

Why do ions need specific ion channel?

Answer 2

(Charged) ions cannot pass through the phospholipid bilayer, due to the hydrophobic (fatty acid) tails
Specific ion channels (proteins) create hydrophilic pathways for ions to pass through

Question 3

Why are Na+ ions used in the generation of APs?

Answer 3

Because at membrane potential (-70mV), Na+ is out of equilibrium (ENa = +30mV)
Therefore Na+ ions will want to flow into the cell down the conc / electrical gradient

Question 4

Where does the Na+K+ ATP-are pump get its energy from?

Answer 4

ATP hydrolysis

Question 5

Where does depolarisation occur in myelinated neurones?

Answer 5

Nodes of Ranvier

Question 6

What should be the target of drugs for MS (multiple sclerosis) and why?

Answer 6

Blocking K+ channels

In MS, you want to PROLONG the duration of the AP (i.e. depolarisation) to give more chance of the AP jumping across the plaque
Do this by blocking K+ channels that cause repolarisation

Question 7

What provides connectivity in the NS?

Answer 7

Neural networks

Question 8

What structures protect the CNS?

Answer 8

Brain - skull
Spinal cord - vertebral column

Question 9

What is used to record electrical activity of the brain?

Answer 9

Electroencephalograms (EEG)

Question 10

What is the purpose of keeping Na+ ions out of equilibrium across the cell membrane?

Answer 10

Resting membrane potential = -70mV
(Inside of the cell is more negative than the outside)
Maintained by selective permeability of cell membrane to different ions and the Na+/K+ pump

The Na+ ion concentration is much higher outside the cell than inside, and this concentration gradient tends to drive Na+ ions into the cell. However, the cell membrane is relatively impermeable to Na+ ions, which are prevented from freely entering the cell by ion channels that are mostly closed at rest.

By keeping the concentration of Na+ ions out of equilibrium across the membrane, the neuron is primed to generate an action potential when the appropriate stimulus is received. When the neuron is stimulated, ion channels open, allowing Na+ ions to rapidly flow into the cell, depolarizing the membrane and generating an action potential.

Thus, by maintaining an unequal distribution of Na+ ions across the membrane, the neuron is able to generate and propagate action potentials in response to appropriate stimuli, allowing for proper communication between neurons and other cells in the body.

Question 11

What is the normal direction of an impulse in a neurone?
From the… to the …

Answer 11

From the SOMA to the AXON TERMINALS

Question 12

What is the net gradient (and movement) of K+ ions?

Answer 12

K+ ions move out of the cell down the CONC GRAD - bc there’s greater [K+] inside the cell than outside

K+ ions move into the cell down ELECTRICAL GRAD - bc +ve charged ions are attracted to net -ve charge inside the cell

The conc grad > electrical grad = net movement of K+ ions OUT of the cell

Question 13

What is the net gradient for Na+ ions?

Answer 13

Na+ ions move INTO cell down conc & electrical gradients
Net gradient INTO cell

Question 14

What is the Nernst / Equilibrium potential for Na+?

Answer 14

ENa = (RT/zF).ln([Na]o/[Na]i)

ENa ~ +30mV

Question 15

What is the intracellular concentration of organic anions (A-)?

Answer 15

130mM

(These don’t have ion channels)

Question 16

What is the function of the NS?

Answer 16

Acts as a communications network

Receives sensory info

Initiates actions - i.e. hormone release / muscle contraction

Question 17

What is the function of neurones?

Answer 17

Communication / memory

Question 18

What is the function of glia?

Answer 18

Support / communication

Question 19

What is the equation for the Nernst / Equilibrium potential of K+?

Answer 19

Ek = (RT/zF).ln ([K]o/[K]i)

Ek~ -70mV
(Approximately equal to [resting] membrane potential)

Question 20

Explain the variables in the Nernst / Equilibrium potential

Ex = (RT/zF).ln ([X]o/[X]i)

Answer 20

R = gas constant
T = temp (K)
z = valency of ion (Na+ / K+)
F = faraday constant
[X]o = conc X+ outside the cell
[X]i = conc X+ inside the cell

Question 21

Explain the Nernst / Equilibrium equation

Answer 21

The Nernst equation is a mathematical formula used to calculate the equilibrium potential for an ion across a membrane.

It tells us the electrical potential required to balance the conc gradient of an ion across a membrane. At equilibrium, the electrical potential generated by the conc gradient is equal and opposite to the membrane potential, resulting in no net movement of the ion across the membrane.

If the membrane potential of a neurone is more + than the equilibrium potential, then ions will tend to move INTO the cell. If the membrane potential of a neurone is less + than the equilibrium potential, ions will tend to move OUT of the cell.

Question 22

What is the difference between myelinated and unmyelinated neurones?

Answer 22

Myelinated neurones - axon is insulated by the myelin sheath - made up of several Schwann cells wrapped around the axon.

This prevents ionic leakage and therefore conduction is faster as impulses ‘jump’ between the Nodes of Ranvier in saltatory conduction

Question 23

What are the nodes of Ranvier?

Answer 23

Sections of axon without myelin sheath, bathed in external fluid

Question 24

What is the CNS made up of?

Answer 24

The brain and spinal cord

Question 25

What happens to the net gradient of K+ ions over time (generation of membrane potential)?

Answer 25

Over time, the inc movement of K+ ions OUT of the cell decreases [K+] inside the cell

Electrical gradient gets stronger as the inside of the cell gets more negatively charged

Concentration gradient gets weaker as there is less difference between the intra & extracellular ion concentrations

This occurs until the gradients are equal, equilibrium is reached and there is NO NET MOVEMENT (or gradient)

This is membrane potential (-70mV)

Question 26

What does the somatic NS control?

Answer 26

Skeletal muscle contraction (limbs)

Question 27

What does the sensory NS control?

Answer 27

Skin

Viscera - i.e. heart, kidneys, gut

Question 28

What does the Na+/K+ ATP-ase pump do?

Answer 28

Pumps 3Na+ OUT of the cell

Pumps 2K+ INTO cell

Generating an overall -ve charge inside the cell

Question 29

What does the autonomic NS control?

Answer 29

Involuntary actions

(E.g. HR / BP / digestion / filtration of blood kidneys)

Question 30

What controls ion movement across the neuronal cell membrane ?

Answer 30

Voltage-gated ion channels that span the membrane

Question 31

What causes MS (multiple sclerosis?)

Answer 31

Damage to the myelin sheath

Therefore APs cannot ‘jump’ across Nodes of Ranvier

Causing transmission failure

Question 32

What are the intracellular & extracellular concentrations of Na+ ions ?

Answer 32

Intracellular = 10mM
Extracellular = 120mM

= net movement INTO cell down conc gradient

Question 33

What are the intracellular and extracellular concentrations of K+ ions?

Answer 33

Intracellular = 125mM
Extracellular = 5mM

= net movement OUT of the cell down conc gradient

Question 34

What are the intracellular & extracellular concentrations of Cl- ions

Answer 34

Intracellular = 5mM
Extracellular = 125mM

= net movement INTO cell down concentration gradient

Question 35

What are the 4 stages in the generation of an AP?

Answer 35

1. Resting / membrane potential ~ -70mV
2. Stimulus causes DEPOLARISATION, influx of Na+ ions increases membrane potential to above threshold (-50mV)
3. Action potential generated (~ +30mV)
4. K+ ion channels open, K+ ions move out - REPOLARISATION (decreases membrane potential)
5. Membrane repolarises below membrane potential - HYPERPOLARISATION - ensures discrete impulses
6. Return to resting / membrane potential

Question 36

What are the 3 main divisions of the PNS?

Answer 36

1. Somatic NS
2. Sensory NS
3. Autonomic NS

Question 37

What are the 2 phases of inactivation?

Answer 37

1. Absolute - nothing will open the channels
2. Relative - if you increase stimulus activity, some action potential will fire

Question 38

What are the 2 major cell types in the NS?

Answer 38

1. Neurones
2. Glia (Neuroglia)

Question 39

What are the 2 gradients generated by ions?

Answer 39

1. Concentration gradient
2. Electrical gradient

Question 40

What are the 2 divisions of the autonomic NS?

Answer 40

1. Sympathetic - increases HR / BP
2. Parasympathetic - decreases HR / BP

Question 41

What are the 2 different types of glial cell in the CNS & PNS?

Answer 41

In CNS - oligodendrocytes
In PNS - Schwann cell

Question 42

What are some symptoms of multiple sclerosis (MS) caused by transmission failure of action potentials?

Answer 42

Difficulty breathing / moving
Eye problems

Question 43

What are the names of 2 K+ channel blockers (drugs) used in the treatment of MS?

Answer 43

4,aminopyridine

Tetraethylammonium (TEA)

Question 44

If you stimulate an axon directly, can action potentials travel up and down an axon simultaneously?

Answer 44

Yes

Question 45

How is the electrical gradient generated?

Answer 45

+ve charged ions are attracted to region of net -ve charge inside the cell

Question 46

How is the concentration gradient generated?

Answer 46

By a difference in concentration of ions across a membrane
Ions move down the concentration gradient from a region of high(er) to a region of low(er) concentration

Question 47

How are ion gradients established ?

Answer 47

Na+/K+ pump

Pumps 3Na+ OUT
Pumps 2K+ IN

Generates electrical & concentration gradients

Question 48

How do ions move across cell membranes?

Answer 48

In response to gradients
Through specific ion channels

Question 49

How do action potential communicate sensory info to cells?

Answer 49

The frequency of the action potential

*it is not the amplitude - All-or-Nothing principle (AP must reach above threshold)

Question 50

Describe the states of the Na+ & K+ channels at resting membrane potential (-70mV)

Answer 50

Both K+ and Na+ channels closed - K+ ions can’t leave the cell, Na+ ions can’t enter the cell

Na+ channel ready for activation - inactivation gate is open

Question 51

Describe the states of the K+ and Na+ ion channels at repolarisation

Answer 51

SODIUM INACTIVATION - Na+ channel inactivation gate closes, preventing Na+ ions moving into the cell

K+ channels open - K+ ions diffuse out of the cell

This decreases the positive charge within the cell = repolarisation

Question 52

Describe the states of the K+ and Na+ channels in hyperpolarisation

Answer 52

Na+ inactivation gate shut, K+ channels open

This allows for the loss of excess +ve charge
Providing some level of control over the frequency of AP firing and ensuring that impulses are discrete

Question 53

Describe the states of the K+ and Na+ ion channels at depolarisation

Answer 53

Na+ channels are open (both activation & inactivation gates) - causing an influx of Na+ ions into the cell - causing depolarisation

K+ ion channels closed - preventing loss of +ve charge

Question 54

After arriving at nerve terminals, can APs reflect back along the axon to the soma?

Answer 54

No because the section of membrane that it has just travelled along will be undergoing the ‘refractory period’ due to hyperpolarisation

This makes it harder for an action potential to be generated, ensuring that the impulses are unidirectional