Nerve impulse

process by which neurons communicate with each other by changes in their membrane potentials.
(Redirected from Action potential)

A nerve impulse are the series of electrical signals that is generated in the neurons (nerve cells) in a response to stimulus.[1]

Approximate plot of a typical action potential

Mechanism of Conduction

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Polarisation

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When a neuron is not conduction or is in resting state the axonal membrane is more permeable to K+ ions and impermeable to Na+ ions. The sodium potassium pump actively pumps out 3Na+ ions to the extracellular fluid and takes in 2K+ ions into the cell. Due to the imbalance in charge, a potential difference is developed across the axonal membrane, also known as the resting potential (-70mV). The outer side of the membrane will have a positive charge while the inner side will have a negative charge.[2]

 

Depolarisation

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When a stimulus (chemical, mechanical or electrical) is applied to the membrane the sodium potassium pump stops working. The Na+ ions will rush inside the cell followed by the reversal of polarity of the axonal membrane. Its also called depolarisation of the nerve fibre. The electric potential difference at the site of stimulus is called the action potential (+40mV).[2]

Repolarisation

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As a result, the current will flow from depolarised part of nerve fibre to polarised part of the nerve fibre in the axoplasm, while current flows in opposite direction on the cell surface. Thus in this way a new action potential is generated up ahead in the nerve fibre. The time taken by the axonal membrane to get polarised again is called the refractory period (1ms). After the refractory period the sodium potassium pump will operate again and the membrane will return to resting state again.[2]

Special faster connections

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Faster electrical synapses are used in escape reflexes, the retina of vertebrates, and the heart. They are faster because they do not need the slow diffusion of neurotransmitters across the synaptic gap. Therefore, electrical synapses are used whenever fast response and coordination of timing are crucial.

These synapses connect the presynaptic and postsynaptic cells directly together.[3] When an action potential reaches such a synapse, the ionic currents cross the two cell membranes and enter the postsynaptic cell through pores known as connexons.[4] Thus, presynaptic action potential directly stimulates the postsynaptic cell.

References

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  1. Reinis, Stanislav; Goldman, Jerome M. (1982), Reinis, Stanislav; Goldman, Jerome M. (eds.), "The Nerve Impulse", The Chemistry of Behavior: A Molecular Approach to Neuronal Plasticity, Boston, MA: Springer US, pp. 51–58, doi:10.1007/978-1-4613-3590-0_3, ISBN 978-1-4613-3590-0, retrieved 2022-10-08
  2. 2.0 2.1 2.2 Newman, P. P. (1980), "Nerve Impulses", Neurophysiology, Dordrecht: Springer Netherlands, pp. 27–57, doi:10.1007/978-94-011-6681-2_2, ISBN 978-94-011-6683-6, retrieved 2022-10-08
  3. Zoidl G. & Dermietzel R. (2002). "On the search for the electrical synapse: a glimpse at the future". Cell Tissue Res. 310 (2): 137–42. doi:10.1007/s00441-002-0632-x. PMID 12397368. S2CID 22414506.
  4. Brink P.R; Cronin K. & Ramanan S.V. (1996). "Gap junctions in excitable cells". J. Bioenerg. Biomembr. 28 (4): 351–8. doi:10.1007/BF02110111. PMID 8844332. S2CID 46371790.{{cite journal}}: CS1 maint: multiple names: authors list (link)

Other websites

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