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This article is about the biological application of the Nernst equation. For the general equation, see Nernst equation.

In a biological membrane, the reversal potential (also known as the Nernst potential) of an ion is the membrane potential at which there is no net (overall) flow of ions from one side of the membrane to the other. In the case of post-synaptic neurons, the reversal potential is the membrane potential at which a given neurotransmitter causes no net current flow of ions.^[1]

In a single-ion system, reversal potential is synonymous with equilibrium potential; their numerical values are identical. The two terms refer to different aspects of the difference in membrane potential. Equilibrium refers to the fact that the net ion flux at a particular voltage is zero. That is, the outward and inward rates of ion movement are the same; the ion flux is in equilibrium. Reversal refers to the fact that a change of membrane potential on either side of the equilibrium potential reverses the overall direction of ion flux.^[1]

The reversal potential is often called the "Nernst potential", as it can be calculated from the Nernst equation. Ion channels conduct most of the flow of simple ions in and out of cells. When a channel type that is selective to one species of ion dominates within the membrane of a cell (because other ion channels are closed, for example) then the voltage inside the cell will equilibrate (i.e. become equal) to the reversal potential for that ion (assuming the outside of the cell is at 0 volts). For example, the resting potential of most cells is close to the K⁺ (potassium ion) reversal potential. This is because at resting potential, potassium conductance dominates. During a typical action potential, the small resting ion conductance mediated by potassium channels is overwhelmed by the opening of a large number of Na⁺ (sodium ion) channels, which brings the membrane potential close to the reversal potential of sodium.

The relationship between the terms "reversal potential" and "equilibrium potential" only holds true for single-ion systems. In multi-ion systems, there are areas of the cell membrane where the summed currents of the multiple ions will equal zero. While this is a reversal potential in the sense that membrane current reverses direction, it is not an equilibrium potential because not all (and in some cases, none) of the ions are in equilibrium and thus have net fluxes across the membrane. When a cell has significant permeabilities to more than one ion, the cell potential can be calculated from the Goldman-Hodgkin-Katz equation rather than the Nernst equation.

[edit] Mathematical models

The term driving force is related to equilibrium potential, and is likewise useful in understanding the current in biological membranes. Driving force refers to the difference between an ion's equilibrium potential and the actual membrane potential. It is defined by the following equation:

${Driving Force} = ({V_m}-{E_{ion}})\,$

${I_{ion}} = {G_{ion}} ({Driving Force})\,$

${I_{ion}} = {G_{ion}} ({V_m}-{E_{ion}})\,$

In words, this equation says that: the ionic current (I_ion) is equal to that ion's conductance (g_ion) multiplied by the driving force, which is represented by the difference between the membrane potential and the ion's equilibrium potential (i.e. V_m-E_ion). Note that the ionic current will be zero if the membrane is impermeable (g_ion = 0) to the ion in question, regardless of the size of the driving force.

A related equation (which is derived from the more general equation above) determines the magnitude of an end plate current (EPC), at a given membrane potential, in the neuromuscular junction:

$EPC = {G_{ACh}} ({V_m}-{E_{rev}})\,$

where EPC is the end plate current, G_ACh is the ionic conductance activated by acetylcholine, V_m is the membrane potential, and E_rev is the reversal potential. When the membrane potential is equal to the reversal potential, V_m-E_rev is equal to 0 and there is no driving force on the ions involved.^[1]

[edit] Use in research

When V_m is at the reversal potential (V_m-E_rev is equal to 0), the identity of the ions that flow during an EPC can be deduced by comparing the reversal potential of the EPC to the equilibrium potential for various ions. For instance, if acetylcholine opens an ion channel that is permeable only to K⁺, then the reversal potential of the EPC is at the equilibrium potential for K⁺, which is around -100mV in muscle cells. If, however, the acetylcholine-activated channels were permeable only to Na⁺, the reversal potential would then be around +70mV (which is the Na⁺ equilibrium potential of muscle cells). If the channels were only permeable to Cl^-, then the reversal potential would be around -50mV. On the other hand, if the acetylcholine-activated channels were permeable to both Na⁺ and K⁺, then the reversal potential would be somewhere between +70mV and -100mV.^[1]

This line of reasoning led to the development of experiments (by Akira Takeuchi and Noriko Takeuchi in 1960) that proved that acetylcholine-activated ion channels are approximately equally permeable to Na⁺ and K⁺ ions. The experiment was performed by lowering the external Na⁺ concentration, which lowers (more negative) the Na⁺ equilibrium potential and produces a negative shift in reversal potential. Conversely, increasing the external K⁺ concentration raises (more positive) the K⁺ equilibrium potential and produces a positive shift in reversal potential.^[1]

[edit] References

^ ^a ^b ^c ^d ^e Dale Purves, et al. (2008). Neuroscience, 4th Edition. Sinauer Associates. pp. 109–11. ISBN 9780878936977.

[edit] See also

[Purves-0] Dale Purves, et al. (2008). Neuroscience, 4th Edition. Sinauer Associates. pp. 109–11. ISBN 9780878936977.

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Contents

[edit] Mathematical models

[edit] Use in research

[edit] References

[edit] See also