Nerve Impulses (DP IB Biology)
Revision Note
Generating the Resting Potential
Neurones transmit information in the form of impulses, which travel extremely quickly along the neurone from one end to the other
Note that an impulse is not an electrical current that flows along neurones as if they were wires
Instead, an impulse is a momentary reversal in the electrical potential difference across the neurone cell surface membrane
The electrical potential difference across a membrane can also be described as the voltage across a membrane, the difference in charge across a membrane, or the membrane potential
In an axon that is not transmitting an impulse the inside of the axon always has a negative electrical potential, or charge, compared to outside the axon, which has a positive electrical potential
This membrane potential in a resting neurone is known as resting potential
The resting potential is usually about -70 millivolts (mV)
This means that the inside of the resting axon has a more negative electrical charge than the outside by about 70 mV
Two main processes contribute to establishing and maintaining resting potential:
The active transport of sodium ions and potassium ions
A difference in rates of diffusion of sodium ions and potassium ions
In addition to these two main processes, negatively charged proteins inside the axon also contribute to the negative resting potential
The active transport of sodium ions and potassium ions
Carrier proteins called sodium-potassium pumps are present in the cell surface membranes of neurones
These pumps use ATP to actively transport sodium ions (Na⁺) out of the axon and potassium ions (K⁺) into the axon
The two types of ion are pumped at an unequal rate; for every 3 sodium ions that are pumped out of the axon, only 2 potassium ions are pumped in
This creates a concentration gradient across the membrane for both sodium ions and potassium ions
Difference in rates of diffusion of sodium ions and potassium ions
Because of the concentration gradient generated by the sodium-potassium pumps, both sodium and potassium ions will diffuse back across the membrane
The neurone cell surface membrane has sodium ion channels and potassium ion channels that allow sodium and potassium ions to move across the membrane by facilitated diffusion
The neurone membrane is much less permeable to sodium ions than potassium ions, so potassium ions inside the neurone can diffuse out at a faster rate than sodium ions can diffuse back in
This results in far more positive ions on the outside of the neurone than on the inside, generating a negative charge inside the neurone in relation to the outside
The result of this is that the neurone has a resting membrane potential of around -70 millivolts (mV)
Resting Potential Diagram
Sodium-potassium pumps in the membrane of a resting neurone generate a concentration gradient for both sodium ions and potassium ions. This process, together with the facilitated diffusion of potassium ions back out of the cell at a faster rate than sodium ions diffuse back into the cell, generates a negative resting potential across the membrane.
Nerve Impulses
Once resting potential is reached, the neurone membrane is said to be polarised
To initiate a nerve impulse in a neurone, the neurone membrane needs to be depolarised
Depolarisation is the reversal of the electrical potential difference across the membrane
The depolarisation of the membrane occurs when an action potential is generated
Action potentials lead to the reversal of resting potential from around -70 mV to around +40 mV
Action potentials involve the rapid movement of sodium ions and potassium ions across the membrane of the axon
An action potential is the potential electrical difference produced across the axon membrane when a neurone is stimulated e.g. when an environmental stimulus is detected by a receptor cell
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