Changes

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At a given moment voltage-gated sodium channels within the membrane of the axon will open resulting in an influx of ions following their electro-chemical gradient. This Na⁺ influx causes the axon to accumulate a positive charge and results in cellular depolarisation. The extracellular

At a given moment voltage-gated sodium channels within the membrane of the axon will open resulting in an influx of ions following their electro-chemical gradient. This Na⁺ influx causes the axon to accumulate a positive charge and results in cellular depolarisation. The extracellular area of the axon therefore looses its positive charge, becoming more negative resulting in a current of positive charge that flows  through the tissue towards the axon. The membrane of the axon is not a perfect insulator and at some regions on the axon, particularly within the area of the axon infront of the action potential, the voltage-dependant ion channels have not activated yet. This means that some of the positive charge is able to flow out of the axon membrane in these regions and this positive charge outflow is mainly via potassium. This outward leakage of potassium results in the current within the axon only being able to travel a short distance before the nerve impulse decays. However the effect of the current locally on the voltage-gated channels means that the nerve impulse is able to open voltage-gated channels within it's immediate vicinity and this is enough for the signal to propagate along the nerve.

====Myelinated Axons====

====Myelinated Axons====