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3 Fundamentals of the Formation of Biosignals
Propagation of the Action Potential
The electrical communication of the nerve cells with each other in the brain, with
sensory cells or to stimulate the contraction of distant muscle cells occurs by means
of the action potential. Accordingly, there are nerve pathways in the body on which
the action potentials can spread, the so-called axon. Basically, a distinction is made
between two forms of conduction, the continuous, i.e. the conduction from one point
of the axon to the directly adjacent one, and the so-called saltatory conduction, in
which the action potential spreads abruptly along the axon.
Saltatory excitation conduction is mainly found in vertebrates due to the faster
propagation of the action potential, as here usually larger distances have to be over-
come and delays in the transmission of nerve stimuli would be intolerable. An ex-
ample of this is the whale, in which a nerve stimulus may have to travel over 50 m be-
fore it reaches the brain. The basic structure of saltatory nervous system differs from
the continuous form by an additional insulation of the axon in the form of the so-
called myelin sheath (cf. Figure 3.8). The saving of the myelin sheath in continuous
nerve conduction is due to space problems, which is why it is mainly absent in smaller
creatures such as insects and on the last centimetres of a vertebrate nerve conduction.
Besides the lower propagation speed, another disadvantage of continuous excitation
conduction is that action potentials are subject to strong attenuation. In contrast to
saltatory excitation conduction, the action potential is not re-formed at the approx-
imately five millimetre long node of Ranvier between the sections of the insulating
myelin sheath. Because the action potential is constantly regenerated in saltatory ex-
citation conduction, attenuation along even long pathways is negligible. This means
it doesn’t just arrive faster, it is also transmitted with constant amplitude. At the same
time, it can be concluded that the amplitude of an action potential cannot stand for its
stimulus intensity, i.e. stronger stimuli produce constant amplitudes, but an increased
frequency of action potentials. However, there is also an upper stimulus limit for this,
which can be explained with the help of the previously discussed refractory period of
the nerve cell. When the upper stimulus limit is exceeded, the frequency of the action
potentials no longer increases, although the stimulus continues to increase.
Continuous Excitation Conduction
In continuous excitation conduction, the action potential is transmitted by depolar-
isation of directly adjacent nerve cells in the axon. This means that after stimulation of
a nerve cell, e.g. by incoming signal stimuli in the synaptic cleft between the dendrites
and the nerve cell, an action potential spreads along the axon by depolarising directly
adjacent nerve cells in the axon due to the increase in potential and these in turn de-
polarise the adjacent ones and so on. Thus, each nerve cell must depolarise in turn in
the axon before the signal arrives at the other end of the nerve. The propagation velo-
cities achieved in this process range from 1 to 5 m/s. The nerve conduction velocity is