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Learn about the refractory period after an action potential, how it limits impulse frequency, and the factors affecting the speed of an action potential. Discover how myelinated neurons enable faster propagation of nerve impulses.
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AP - Overview (Click here for animation of the gates)
The Refractory Period • There is a time after depolarisation where no new AP can start – called the refractory period. • Time is needed to restore the proteins of voltage sensitive ion channels to their original resting conditions. • Na+ channels cannot be opened, as it can’t be depolarised again. WHY? • AP travel in one direction only. • Produces discrete impulses. • Limits the frequency of impulses.
After the action Potential • During the action potential, the membrane is depolarised. • Following the impulse K+ ions move out of the membrane, this is repolarisation • The membrane briefly becomes hyperpolarised (more negative on the inside than usual) • The Na+ / K+ channels close
The refractory period • With the Na+ / K+ channels closed, the cation pumps can now begin to restore the balance between the ions • Na+ is pumped out and K+ pumped in. • During this time a new action potential can not be set up until resting potential is achieved.
Purpose of refractory period • Ensures action potential move in one direction (from receptor to effector) • To distinguish between one action potential and the next (the greater the stimulus, the higher the frequency).
Waves of Depolarisation • After an action potential, some of the sodium diffuse sideways. • Causing sodium ion channels in the next region of the neurone to open. • Causes impulse to propagate along the neurone.
AP – All or nothing • AP only happens if the stimulus reaches a threshold value. • Stimulus is strong enough to cause an AP • It is an ‘all or nothing event’ because once it starts, it travels to the synapse. • AP is always the same size • An AP is the same size all the way along the axon. • The transmission of the AP along the axon is the nerve impulse. • Bigger stimulus will cause more frequent action potentials.
Unmyelinated Neurones • Localised electrical currents are set up and the action potential is propagated along the neurone. • The wave travels the whole length of the neurone.
Na+ Na+ Na+ Sodium channel Nodes of Ranvier Myelinated Neurones • The axons of many neurones are encased in a fatty myelin sheath (Schwann cells). • Where the sheath of one Schwann cell meets the next, the axon is unprotected. • The voltage-gated sodium channels of myelinated neurons are confined to these spots (called nodes of Ranvier).
Na+ Na+ Na+ Sodium channel Nodes of Ranvier Myelinated Neurones • The in rush of sodium ions at one node creates just enough depolarisation to reach the threshold of the next. • In this way, the action potential jumps from one node to the next (1-3mm) – called saltatory propagation • Results in much faster propagation of the nerve impulse than is possible in unmyelinated neurons.
Factors Affecting the Speed of an AP 1. Myelin sheath – electrical insulator – the AP jumps from one Node of Ranvier to another = SALTATORY CONDUCTION. • Myelinated = 90ms-1 • Unmyelinated = 30ms-1
Factors Affecting the Speed of an AP 2. Diameter of the axon – greater diameter = faster conductance (due to less leakage).
Factors Affecting the Speed of an AP 3. Temperature – higher temp = faster nerve impulse (rate of diffusion is faster, enzyme activity is faster e.g. ATPase.
How do we detect the size of a stimulus? • The number of impulses in a given time – the larger the stimulus, the more impulses generated. • By having neurones with different threshold values – the brain interprets the number and type of neurones and therby determines its size.