The membrane potential in a cell derives ultimately from two factors: electrical force and diffusion. Electrical force arises from the mutual attraction between particles with opposite electrical charges (positive and negative) and the mutual repulsion between particles with the same type of charge (both positive or both negative). Diffusion arises from the statistical tendency of particles to redistribute from regions where they are highly concentrated to regions where the concentration is low.
Voltage Voltage, which is synonymous with
difference in electrical potential, is the ability to drive an electric current across a resistance. Indeed, the simplest definition of a voltage is given by
Ohm's law: V=IR, where V is voltage, I is current and R is resistance. If a voltage source such as a battery is placed in an electrical circuit, the higher the voltage of the source the greater the amount of current that it will drive across the available resistance. The functional significance of voltage lies only in potential
differences between two points in a circuit. The idea of a voltage at a single point is meaningless. It is conventional in electronics to assign a voltage of zero to some arbitrarily chosen element of the circuit, and then assign voltages for other elements measured relative to that zero point. There is no significance in which element is chosen as the zero point—the function of a circuit depends only on the differences not on voltages
per se. However, in most cases and by convention, the zero level is most often assigned to the portion of a circuit that is in contact with
ground. The same principle applies to voltage in cell biology. In electrically active tissue, the potential difference between any two points can be measured by inserting an electrode at each point, for example one inside and one outside the cell, and connecting both electrodes to the leads of what is in essence a specialized voltmeter. By convention, the zero potential value is assigned to the outside of the cell and the sign of the potential difference between the outside and the inside is determined by the potential of the inside relative to the outside zero. In mathematical terms, the definition of voltage begins with the concept of an
electric field , a vector field assigning a magnitude and direction to each point in space. In many situations, the electric field is a
conservative field, which means that it can be expressed as the
gradient of a scalar function , that is, . This scalar field is referred to as the voltage distribution. The definition allows for an arbitrary constant of integration—this is why absolute values of voltage are not meaningful. In general, electric fields can be treated as conservative only if magnetic fields do not significantly influence them, but this condition usually applies well to biological tissue. Because the electric field is the gradient of the voltage distribution, rapid changes in voltage within a small region imply a strong electric field; on the converse, if the voltage remains approximately the same over a large region, the electric fields in that region must be weak. A strong electric field, equivalent to a strong voltage gradient, implies that a strong force is exerted on any charged particles that lie within the region.
Ions and the forces driving their motion Electrical signals within biological organisms are, in general, driven by
ions. The most important cations for the action potential are
sodium (Na+) and
potassium (K+). Both of these are
monovalent cations that carry a single positive charge. Action potentials can also involve
calcium (Ca2+), which is a
divalent cation that carries a double positive charge. The
chloride anion (Cl−) plays a major role in the action potentials of some
algae, but plays a negligible role in the action potentials of most animals. Ions cross the cell membrane under two influences:
diffusion and
electric fields. A simple example wherein two solutions—A and B—are separated by a porous barrier illustrates that diffusion will ensure that they will eventually mix into equal solutions. This mixing occurs because of the difference in their concentrations. The region with high concentration will diffuse out toward the region with low concentration. To extend the example, let solution A have 30 sodium ions and 30 chloride ions. Also, let solution B have only 20 sodium ions and 20 chloride ions. Assuming the barrier allows both types of ions to travel through it, then a steady state will be reached whereby both solutions have 25 sodium ions and 25 chloride ions. If, however, the porous barrier is selective to which ions are let through, then diffusion alone will not determine the resulting solution. Returning to the previous example, let's now construct a barrier that is permeable only to sodium ions. Now, only sodium is allowed to diffuse cross the barrier from its higher concentration in solution A to the lower concentration in solution B. This will result in a greater accumulation of sodium ions than chloride ions in solution B and a lesser number of sodium ions than chloride ions in solution A. This means that there is a net positive charge in solution B from the higher concentration of positively charged sodium ions than negatively charged chloride ions. Likewise, there is a net negative charge in solution A from the greater concentration of negative chloride ions than positive sodium ions. Since opposite charges attract and like charges repel, the ions are now also influenced by electrical fields as well as forces of diffusion. Therefore, positive sodium ions will be less likely to travel to the now-more-positive B solution and remain in the now-more-negative A solution. The point at which the forces of the electric fields completely counteract the force due to diffusion is called the equilibrium potential. At this point, the net flow of the specific ion (in this case sodium) is zero.
Plasma membranes lipid bilayer common to all living cells. It contains a variety of biological molecules, primarily proteins and lipids, which are involved in a vast array of cellular processes. Every cell is enclosed in a
plasma membrane, which has the structure of a
lipid bilayer with many types of large molecules embedded in it. Because it is made of lipid molecules, the plasma membrane intrinsically has a high electrical resistivity, in other words a low intrinsic permeability to ions. However, some of the molecules embedded in the membrane are capable either of actively transporting ions from one side of the membrane to the other or of providing channels through which they can move. In electrical terminology, the plasma membrane functions as a combined
resistor and
capacitor. Resistance arises from the fact that the membrane impedes the movement of charges across it. Capacitance arises from the fact that the lipid bilayer is so thin that an accumulation of charged particles on one side gives rise to an electrical force that pulls oppositely charged particles toward the other side. The capacitance of the membrane is relatively unaffected by the molecules that are embedded in it, so it has a more or less invariant value estimated at 2 μF/cm2 (the total capacitance of a patch of membrane is proportional to its area). The conductance of a pure lipid bilayer is so low, on the other hand, that in biological situations it is always dominated by the conductance of alternative pathways provided by embedded molecules. Thus, the capacitance of the membrane is more or less fixed, but the resistance is highly variable. The thickness of a plasma membrane is estimated to be about 7–8 nanometers. Because the membrane is so thin, it does not take a very large transmembrane voltage to create a strong electric field within it. Typical membrane potentials in animal cells are on the order of 100 millivolts (that is, one tenth of a volt), but calculations show that this generates an electric field close to the maximum that the membrane can sustain—it has been calculated that a voltage difference much larger than 200 millivolts could cause
dielectric breakdown, that is, arcing across the membrane.
Facilitated diffusion and transport The resistance of a pure lipid bilayer to the passage of ions across it is very high, but structures embedded in the membrane can greatly enhance ion movement, either
actively or
passively. This is achieved via the mechanisms of
active transport and
facilitated diffusion. The two types of structure that play the largest roles are ion channels and
ion pumps, both usually formed from assemblages of protein molecules. Ion channels provide passageways through which ions can move. In most cases, an ion channel is permeable only to specific types of ions (for example, sodium and potassium but not chloride or calcium), and sometimes the permeability varies depending on the direction of ion movement. Ion pumps, also known as ion transporters or carrier proteins, actively transport specific types of ions from one side of the membrane to the other, sometimes using energy derived from metabolic processes to do so.
Ion pumps Ion pumps are
integral membrane proteins that carry out
active transport, i.e., use cellular energy (ATP) to "pump" the ions against their concentration gradient. Such ion pumps take in ions from one side of the membrane (decreasing its concentration there) and release them on the other side (increasing its concentration there). The ion pump most relevant to the action potential is the
sodium–potassium pump, which transports three sodium ions out of the cell and two potassium ions in. In a similar manner, other ions have different concentrations inside and outside the neuron, such as
calcium,
chloride and
magnesium. ions rarely go through the "wrong" channel. For example, sodium or calcium ions rarely pass through a potassium channel.|alt=Seven spheres whose radii are proportional to the radii of mono-valent lithium, sodium, potassium, rubidium, cesium cations (0.76, 1.02, 1.38, 1.52, and 1.67 Å, respectively), divalent calcium cation (1.00 Å) and mono-valent chloride (1.81 Å).
Ion channels are
integral membrane proteins with a pore through which ions can travel between extracellular space and cell interior. Most channels are specific (selective) for one ion; for example, most potassium channels are characterized by 1000:1 selectivity ratio for potassium over sodium, though potassium and sodium ions have the same charge and differ only slightly in their radius. The channel pore is typically so small that ions must pass through it in single-file order. Channel pores can be either open or closed for ion passage, although a number of channels demonstrate various sub-conductance levels. When a channel is open, ions permeate through the channel pore down the transmembrane concentration gradient for that particular ion. Rate of ionic flow through the channel, i.e. single-channel current amplitude, is determined by the maximum channel conductance and electrochemical driving force for that ion, which is the difference between the instantaneous value of the membrane potential and the value of the
reversal potential. A channel may have several different states (corresponding to different
conformations of the protein), but each such state is either open or closed. In general, closed states correspond either to a contraction of the pore—making it impassable to the ion—or to a separate part of the protein, stoppering the pore. For example, the voltage-dependent sodium channel undergoes
inactivation, in which a portion of the protein swings into the pore, sealing it. This inactivation shuts off the sodium current and plays a critical role in the action potential. Ion channels can be classified by how they respond to their environment. For example, the ion channels involved in the action potential are
voltage-sensitive channels; they open and close in response to the voltage across the membrane.
Ligand-gated channels form another important class; these ion channels open and close in response to the binding of a
ligand molecule, such as a
neurotransmitter. Other ion channels open and close with mechanical forces. Still other ion channels—such as those of
sensory neurons—open and close in response to other stimuli, such as light, temperature or pressure.
Leakage channels Leakage channels are the simplest type of ion channel, in that their permeability is more or less constant. The types of leakage channels that have the greatest significance in neurons are potassium and chloride channels. Even these are not perfectly constant in their properties: First, most of them are voltage-dependent in the sense that they conduct better in one direction than the other (in other words, they are
rectifiers); second, some of them are capable of being shut off by chemical ligands even though they do not require ligands in order to operate.
Ligand-gated channels Ligand-gated ion channels are channels whose permeability is greatly increased when some type of chemical ligand binds to the protein structure. Animal cells contain hundreds, if not thousands, of types of these. A large subset function as
neurotransmitter receptors—they occur at
postsynaptic sites, and the chemical ligand that gates them is released by the presynaptic
axon terminal. One example of this type is the
AMPA receptor, a receptor for the neurotransmitter
glutamate that when activated allows passage of sodium and potassium ions. Another example is the
GABAA receptor, a receptor for the neurotransmitter
GABA that when activated allows passage of chloride ions. Neurotransmitter receptors are activated by ligands that appear in the extracellular area, but there are other types of ligand-gated channels that are controlled by interactions on the intracellular side.
Voltage-dependent channels Voltage-gated ion channels, also known as
voltage dependent ion channels, are channels whose permeability is influenced by the membrane potential. They form another very large group, with each member having a particular ion selectivity and a particular voltage dependence. Many are also time-dependent—in other words, they do not respond immediately to a voltage change but only after a delay. One of the most important members of this group is a type of voltage-gated sodium channel that underlies action potentials—these are sometimes called
Hodgkin-Huxley sodium channels because they were initially characterized by
Alan Lloyd Hodgkin and
Andrew Huxley in their Nobel Prize-winning studies of the physiology of the action potential. The channel is closed at the resting voltage level, but opens abruptly when the voltage exceeds a certain threshold, allowing a large influx of sodium ions that produces a very rapid change in the membrane potential. Recovery from an action potential is partly dependent on a type of voltage-gated potassium channel that is closed at the resting voltage level but opens as a consequence of the large voltage change produced during the action potential.
Reversal potential The
reversal potential (or
equilibrium potential) of an ion is the value of transmembrane voltage at which diffusive and electrical forces counterbalance, so that there is no net ion flow across the membrane. This means that the transmembrane voltage exactly opposes the force of diffusion of the ion, such that the net current of the ion across the membrane is zero and unchanging. The reversal potential is important because it gives the voltage that acts on channels permeable to that ion—in other words, it gives the voltage that the ion concentration gradient generates when it acts as a
battery. The equilibrium potential of a particular ion is usually designated by the notation
Eion.The equilibrium potential for any ion can be calculated using the
Nernst equation. For example, reversal potential for potassium ions will be as follows: :E_{eq,K^+} = \frac{RT}{zF} \ln \frac{[K^+]_{o}}{[K^+]_{i}} where •
Eeq,K+= equilibrium potential for potassium, measured in
volts •
R = universal
gas constant, equal to 8.314
joules·K−1·mol−1 •
T =
absolute temperature, measured in
kelvins (= K = degrees Celsius + 273.15) •
z = number of
elementary charges of the ion in question involved in the reaction •
F =
Faraday constant, equal to 96,485
coulombs·mol−1 or J·V−1·mol−1 • [K+]o= extracellular concentration of potassium, measured in
mol·m−3 or mmol·l−1 • [K+]i= intracellular concentration of potassium Even if two different ions have the same charge (i.e., K+ and Na+), they can still have very different equilibrium potentials, provided their outside and/or inside concentrations differ. Take, for example, the equilibrium potentials of potassium and sodium in neurons. The potassium equilibrium potential
EK is −84 mV with 5 mM potassium outside and 140 mM inside. On the other hand, the sodium equilibrium potential,
ENa, is approximately +66 mV with approximately 12 mM sodium inside and 140 mM outside.
Changes to membrane potential during development A
neuron's resting membrane potential actually changes during the
development of an organism. In order for a neuron to eventually adopt its full adult function, its potential must be tightly regulated during development. As an organism progresses through development the resting membrane potential becomes more negative.
Glial cells are also differentiating and proliferating as development progresses in the
brain. The addition of these glial cells increases the organism's ability to regulate extracellular
potassium. The drop in extracellular potassium can lead to a decrease in membrane potential of 35 mV.
Cell excitability Cell excitability is the change in membrane potential that is necessary for cellular responses in various tissues. Cell excitability is a property that is induced during early embryogenesis. Excitability of a cell has also been defined as the ease with which a response may be triggered. The resting and
threshold potentials forms the basis of cell excitability and these processes are fundamental for the generation of graded and action potentials. The most important
regulators of cell excitability are the extracellular
electrolyte concentrations (i.e. Na+, K+,
Ca2+, Cl−,
Mg2+) and associated proteins. Important proteins that regulate cell excitability are
voltage-gated ion channels,
ion transporters (e.g.
Na+/K+-ATPase,
magnesium transporters,
acid–base transporters),
membrane receptors and
hyperpolarization-activated cyclic-nucleotide-gated channels. For example,
potassium channels and
calcium-sensing receptors are important regulators of excitability in
neurons,
cardiac myocytes and many other excitable cells like
astrocytes. Calcium ion is also the most important
second messenger in excitable
cell signaling. Activation of synaptic receptors initiates
long-lasting changes in neuronal excitability.
Thyroid,
adrenal and other hormones also regulate cell excitability, for example,
progesterone and
estrogen modulate
myometrial smooth muscle cell excitability. Many cell types are considered to have an excitable membrane. Excitable cells are neurons,
muscle (
cardiac,
skeletal,
smooth), vascular
endothelial cells,
pericytes,
juxtaglomerular cells,
interstitial cells of Cajal, many types of
epithelial cells (e.g.
beta cells,
alpha cells,
delta cells,
enteroendocrine cells,
pulmonary neuroendocrine cells,
pinealocytes),
glial cells (e.g. astrocytes),
mechanoreceptor cells (e.g.
hair cells and
Merkel cells),
chemoreceptor cells (e.g.
glomus cells,
taste receptors), some
plant cells and possibly
immune cells. Astrocytes display a form of non-electrical excitability based on intracellular calcium variations related to the expression of several receptors through which they can detect the synaptic signal. In neurons, there are different membrane properties in some portions of the cell, for example, dendritic excitability endows neurons with the capacity for coincidence detection of spatially separated inputs.
Equivalent circuit Electrophysiologists model the effects of ionic concentration differences, ion channels, and membrane capacitance in terms of an
equivalent circuit, which is intended to represent the electrical properties of a small patch of membrane. The equivalent circuit consists of a capacitor in parallel with four pathways each consisting of a battery in series with a variable conductance. The capacitance is determined by the properties of the lipid bilayer, and is taken to be fixed. Each of the four parallel pathways comes from one of the principal ions, sodium, potassium, chloride, and calcium. The voltage of each ionic pathway is determined by the concentrations of the ion on each side of the membrane; see the
Reversal potential section above. The conductance of each ionic pathway at any point in time is determined by the states of all the ion channels that are potentially permeable to that ion, including leakage channels, ligand-gated channels, and voltage-gated ion channels. For fixed ion concentrations and fixed values of ion channel conductance, the equivalent circuit can be further reduced, using the
Goldman equation as described below, to a circuit containing a capacitance in parallel with a battery and conductance. In electrical terms, this is a type of
RC circuit (resistance-capacitance circuit), and its electrical properties are very simple. Starting from any initial state, the current flowing across either the conductance or the capacitance decays with an exponential time course, with a time constant of , where is the capacitance of the membrane patch, and is the net resistance. For realistic situations, the time constant usually lies in the 1–100 millisecond range. In most cases, changes in the conductance of ion channels occur on a faster time scale, so an RC circuit is not a good approximation; however, the differential equation used to model a membrane patch is commonly a modified version of the RC circuit equation. ==Resting potential==