Refractory period (physiology): Difference between revisions
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==Neurology refractory period== |
==Neurology refractory period== |
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The '''refractory period in a [[neuron]]''' occurs after an [[action potential]] and generally lasts one millisecond. An action potential consists of three phases. Phase one is depolarization. During depolarization, voltage-gated sodium ion channels open increasing the neuron's membrane conductance for sodium ions and depolarizing the cell's membrane potential (usually from -90mV towards 0). Phase two is repolarization. During repolarization, voltage-gated sodium ion channels inactivate (close) due to the now depolarized membrane, and voltage-gated potassium channels activate (open). Both the sodium ion channels closing and the potassium ion channels opening act to repolarize the cell's membrane potential back to its resting membrane potential. When the cell's membrane voltage overshoots its resting membrane potential (generally -90mV), the cell enters a phase of hyperpolarization. This is due to a larger than resting potassium conductance across the cell membrane. Eventually this potassium conductance drops and the cell returns to its resting membrane potential. |
The '''refractory period in a [[neuron]]''' occurs after an [[action potential]] and generally lasts one millisecond. An action potential consists of three phases. Phase one is depolarization. During depolarization, voltage-gated sodium ion channels open increasing the neuron's membrane conductance for sodium ions and depolarizing the cell's membrane potential (usually from -90mV towards 0). In other words, the membrane is made less negative. Phase two is repolarization. During repolarization, voltage-gated sodium ion channels inactivate (close) due to the now depolarized membrane, and voltage-gated potassium channels activate (open). Both the sodium ion channels closing and the potassium ion channels opening act to repolarize the cell's membrane potential back to its resting membrane potential. When the cell's membrane voltage overshoots its resting membrane potential (generally -90mV), the cell enters a phase of hyperpolarization. This is due to a larger than resting potassium conductance across the cell membrane. Eventually this potassium conductance drops and the cell returns to its resting membrane potential. |
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The refractory periods are due to the inactivation property of voltage-gated sodium channel and the lag of potassium channels in closing. Voltage-gated sodium channels have two gating mechanisms, one that opens the channel with depolarization and the inactivation mechanism that closes the channel with repolarization. While the channel is in the inactive state it will not open in response to depolarization. The period when the majority of sodium channels remain in the inactive state is the absolute refractory period. After this period there are enough voltage-activated sodium channels in the closed (active) state to respond to depolarization. However, voltage gated potassium channels that opened in response to depolarization don't close as quickly as voltage gated sodium channels return to the active closed state. During this time the extra potassium conductance means that the membrane is at a lower threshold and will require a greater stimulus to cause action potentials to fire. This period is the relative refractory period. |
The refractory periods are due to the inactivation property of voltage-gated sodium channel and the lag of potassium channels in closing. Voltage-gated sodium channels have two gating mechanisms, one that opens the channel with depolarization and the inactivation mechanism that closes the channel with repolarization. While the channel is in the inactive state it will not open in response to depolarization. The period when the majority of sodium channels remain in the inactive state is the absolute refractory period. After this period there are enough voltage-activated sodium channels in the closed (active) state to respond to depolarization. However, voltage gated potassium channels that opened in response to depolarization don't close as quickly as voltage gated sodium channels return to the active closed state. During this time the extra potassium conductance means that the membrane is at a lower threshold and will require a greater stimulus to cause action potentials to fire. This period is the relative refractory period. |
Revision as of 15:16, 29 October 2007
In physiology, a refractory period is a period of time during which an organ or cell is incapable of repeating a particular action, or (more precisely) the amount of time it takes for an excitable membrane to be ready for a second stimulus once it returns to its resting state following an excitation. It most commonly refers to electrically excitable muscle cells or neurons.
Electrochemical usage
- See also: Action potential
After initiation of an action potential, the refractory period is defined two ways:
- The absolute refractory period is the interval during which a second action potential absolutely cannot be initiated, no matter how large a stimulus is applied.
- The relative refractory period is the interval immediately following during which initiation of a second action potential is inhibited but not impossible.
The absolute refractory period coincides with nearly the entire duration of the action potential. In neurons, it is caused by the closure and inactivation of the Na+ channels that originally opened to depolarize the membrane. These channels remain inactivated until the membrane repolarizes, after which they regain their ability to open in response to stimulus.
The relative refractory period immediately follows the absolute. As voltage-gated potassium channels open to terminate the action potential by repolarizing the membrane, the potassium conductance of the membrane increases dramatically. K+ ions flooding out of the cell bring the membrane potential closer to the equilibrium potential for potassium. This causes brief hyperpolarization of the membrane, that is, the membrane potential becomes transiently more negative than the normal resting potential. Until the potassium conductance returns to the resting value, a greater stimulus will be required to reach the initiation threshold for a second depolarization. The return to the equilibrium resting potential marks the end of the relative refractory period.
Cardiac refractory period
The refractory period in cardiac physiology is related to the ion currents which, in cardiac cells as in nerve cells, flow into and out of the cell. The flow of ions translates into a change in the voltage of the inside of the cell relative to the extracellular space. As in nerve cells, this characteristic change in voltage is referred to as an action potential. Unlike nerve cells, the cardiac action potential duration is closer to 100 ms (with variations depending on cell type, autonomic tone, etc.). After an action potential initiates, the cardiac cell is unable to initiate another action potential for some duration of time (which is slightly shorter than the "true" action potential duration). This period of time is referred to as the refractory period.
Classically, the cardiac refractory period is separated into an absolute refractory period and a relative refractory period. During the absolute refractory period, a new action potential cannot be elicited. During the relative refractory period, a new action potential can be elicited under the correct circumstances.
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Effective Refractory Period
Neurology refractory period
The refractory period in a neuron occurs after an action potential and generally lasts one millisecond. An action potential consists of three phases. Phase one is depolarization. During depolarization, voltage-gated sodium ion channels open increasing the neuron's membrane conductance for sodium ions and depolarizing the cell's membrane potential (usually from -90mV towards 0). In other words, the membrane is made less negative. Phase two is repolarization. During repolarization, voltage-gated sodium ion channels inactivate (close) due to the now depolarized membrane, and voltage-gated potassium channels activate (open). Both the sodium ion channels closing and the potassium ion channels opening act to repolarize the cell's membrane potential back to its resting membrane potential. When the cell's membrane voltage overshoots its resting membrane potential (generally -90mV), the cell enters a phase of hyperpolarization. This is due to a larger than resting potassium conductance across the cell membrane. Eventually this potassium conductance drops and the cell returns to its resting membrane potential.
The refractory periods are due to the inactivation property of voltage-gated sodium channel and the lag of potassium channels in closing. Voltage-gated sodium channels have two gating mechanisms, one that opens the channel with depolarization and the inactivation mechanism that closes the channel with repolarization. While the channel is in the inactive state it will not open in response to depolarization. The period when the majority of sodium channels remain in the inactive state is the absolute refractory period. After this period there are enough voltage-activated sodium channels in the closed (active) state to respond to depolarization. However, voltage gated potassium channels that opened in response to depolarization don't close as quickly as voltage gated sodium channels return to the active closed state. During this time the extra potassium conductance means that the membrane is at a lower threshold and will require a greater stimulus to cause action potentials to fire. This period is the relative refractory period.
Sexual refractory period
In sexual intercourse, the refractory period is a recovery phase after orgasm during which it is physiologically impossible for a person to experience continued arousal or additional orgasms. The clitoris/penis glans may be hypersensitive and further sexual stimulation may even feel painful during this time frame.
The refractory period varies widely between individuals and across species, ranging from minutes to hours. An increased infusion of the hormone prolactin (which represses dopamine, which is responsible for sexual arousal) during orgasm is believed to be chiefly responsible for the refractory period and the amount by which prolactin is increased may affect the length of each refractory period.
Another chemical which is considered to be responsible for this effect is oxytocin, although oxytocin has a half-life of typically about three minutes in the blood it would not create a long-term refractory period.
Some individuals do not experience a refractory period immediately after orgasm and in many cases are capable of attaining additional, multiple orgasms through further stimulation (mainly oral-genital stimulation or through masturbation). The female sexual response is more alike that of men than previously thought. Most men and women experience hypersensitivity after orgasm, which effectively creates a refractory period. During a refractory period it is almost impossible to be aroused by physical stimulation alone, thus an element of mental stimulation is required to achieve further sexual pleasure .
In general it is the males of the species that have orgasm on a frequent basis (due to the design of the penis which makes it easier to achieve orgasm) which in turn increases the levels of prolactin which represses the arousal properties of dopamine. It is also true that due to the way men rush their way to orgasm, or suppress their orgasm they are not building adequate amounts of the hormone dopamine leading to a less than satisfying orgasm with an inevitable refractory period.