Nervous coordination

Created by

Alima Fuseini

Cards (20)

Myelinated motor neurone 
Dendrites carry impulses to cell body
Axon carries impulses away from cell body
Myelin sheath provides electrical insulation
Node of Ranvier is a gap between adjacent Schwann cells where axon membrane is bare
Cell body 
Contains the nucleus
Some neurones are unmyelinated
Refractory period 
When the membrane is hyperpolarised and then returning to resting potential, the ion channels are recovering and cannot be made to reopen for a brief period
The refractory period acts as a time delay and makes sure action potentials cannot overlap and can pass along as discrete separate impulses
The refractory period also means the action potentials are unidirectional (only pass along in one direction)
All-or-Nothing Principle 
The events of an action potential will only be set into motion if the initial stimulus is big enough to cause a generator potential that reaches threshold value
If the initial stimulus is not large enough, then not enough voltage-gated Na channels will open and the axon membrane will not become fully depolarised, i.e., no action potential will be generated
If the stimulus is large enough, then the impulse will be generated at a constant size and speed
Increasing the initial stimulus will not produce a larger or faster action potential
A stronger stimulus will, however, increase the frequency of action potentials
Wave of depolarisation 
1. Action potential fires, Na+ that entered the neurone diffuses sideways
2. This stimulates voltage-gated Na channels to open in the adjoining region of the axon, depolarising the next section
3. This results in a wave of depolarisation along length of neurone
The wave of depolarisation moves away from parts of the membrane in refractory period (channels cannot open during the refractory period)
Propagation of action potential 
This is called the nerve impulse
Myelination of the axon
In non-myelinated neurones, the wave of depolarisation travels along the whole length of the axon membrane, resulting in relatively slow conduction
In myelinated neurones, the action potential 'jumps from node to node' (saltatory conduction), greatly increasing the speed of the nerve impulse
Axon diameter 
The greater the axon diameter, the faster the conduction of action potentials along the axon, due to less resistance to flow of ions
Temperature 
The higher the temperature (up to 40 °C), the faster the conduction of action potentials along the axon, due to increased rate of diffusion of ions and enzyme-controlled reactions
Above 40 °C, proteins begin to denature and the speed decreases
Summation 
The effect of different impulses can be combined to build up enough neurotransmitter to generate an action potential
Spatial summation 
2 or more presynaptic neurones release their neurotransmitter at the same time onto one postsynaptic neurone
Temporal summation 
Two or more impulses arrive in quick succession from the same presynaptic neurone, making an action potential more likely because more neurotransmitter is released into the synaptic cleft