Action Potential in Neurons, Animation.

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Neurons communicate with each other through their dendrites and axon. Generally, incoming signals are received at dendrites, while outgoing signal travels along the axon to the nerve terminal. In order to achieve rapid communication over its long axon, the neuron sends electrical signals, from the cell’s body to the nerve terminal, along the axon. These are known as nerve impulses, or action potentials. An action potential is essentially a brief reversal of electric polarity across the cell membrane. Cells are polarized, meaning there is an electrical voltage across the cell membrane. In a resting neuron, the typical voltage, known as the resting membrane potential, is about -70mV. The negative value means the cell is more negative on the inside. At this resting state, there are concentration gradients of sodium and potassium across the cell membrane: more sodium outside the cell and more potassium inside the cell. These gradients are maintained by the sodium-potassium pump which constantly brings potassium IN and pumps sodium OUT of the cell. A neuron is typically stimulated at dendrites and the signals spread through the soma. Excitatory signals at dendrites open ligand-gated sodium channels and allow sodium to flow into the cell. This neutralizes some of the negative charge inside the cell and makes the membrane voltage LESS negative. This is known as depolarization as the cell membrane becomes LESS polarized. The influx of sodium diffuses inside the neuron and produces a current that travels toward the axon hillock. If the summation of all input signals is excitatory and is strong enough when it reaches the axon hillock, an action potential is generated and travels down the axon to the nerve terminal. The axon hillock is also known as the cell’s “trigger zone” as this is where action potentials usually start. This is because action potentials are produced by voltage-gated ion channels that are most concentrated at the axon hillock. Voltage-gated ion channels are passageways for ions in and out of the cell, and as their names suggest, are regulated by membrane voltage. They open at some values of the membrane potential and close at others. For an action potential to be generated, the signal must be strong enough to bring the membrane voltage to a critical value called the threshold, typically about -55mV. This is the minimum required to open voltage-gated ion channels. At threshold, sodium channels open quickly. Potassium channels also open but do so more slowly. The initial effect is therefore due to sodium influx. As sodium ions rush into the cell, the inside of the cell becomes more positive and this further depolarizes the cell membrane. The increasing voltage in turn causes even more sodium channels to open. This positive feedback continues until all the sodium channels are open and corresponds to the rising phase of the action potential. Note that the polarity across the cell membrane is now reversed. As the action potential nears its peak, sodium channels begin to close. By this time, the slow potassium channels are fully open. Potassium ions rush out of the cell and the voltage quickly returns to its original resting value. This corresponds to the falling phase of the action potential. Note that sodium and potassium have now switched places across the membrane. As the potassium gates are also slow to close, potassium continues to leave the cell a little longer resulting in a negative overshoot called hyper-polarization. The resting membrane potential is then slowly restored thanks to diffusion and the sodium-potassium pump. During and shortly after an action potential is generated, it is impossible or very difficult to stimulate that part of the membrane to fire again. This is known as the refractory period. The refractory period is divided into absolute refractory and relative refractory. The absolute refractory period lasts from the start of an action potential to the point the voltage first returns to the resting membrane value. During this time, the sodium channels are open and subsequently inactivated while closing and thus unable to respond to any new stimulation. The relative refractory period lasts until the end of hyper-polarization. During this time, some of the potassium channels are still open, making it difficult for the membrane to depolarize, and a much stronger signal is required to induce a new response. During an action potential, the sodium influx at a point on the axon spreads along the axon, depolarizing the adjacent patch of the membrane, generating a similar action potential in it. The sodium currents diffuse in both directions on the axon, but the refractory properties of ion channels ensure that action potential propagates ONLY in ONE direction. This is because ONLY the unfired patch of the axon can respond with an action potential; the part that has just fired is unresponsive until the action potential is safely out of range. An action potential generated at the axon hillock usually travels down the axon to the nerve terminal and not back to the cell body. This is because the concentrations of voltage-gated ions channels are higher in the axon than in the cell body.
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Channel: Alila Medical Media
Views: 983,317
Rating: undefined out of 5
Keywords: yt:quality=high, absolute refractory period, action potentials, anatomy, animated, animation, axon hillock, biology, brain, cytoplasm, depolarization, illustration, ion channel, ligand, local potential, medical, medicine, Na, narrated, narration, nerve, nervous, neural, neurobiology, neurology, neuron, neuroscience, plasma membrane, resting membrane potential, science, sodium, sodium-potassium pump, structure, threshold, trigger zone, voltage-gated ion channels, tutorial, neuropathology, neurophysiology
Id: iBDXOt_uHTQ
Channel Id: undefined
Length: 6min 30sec (390 seconds)
Published: Mon Apr 25 2016
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