Depolarizing prepulse: Difference between revisions
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File:Hodgkin_Huxley_H_and_M_Gate_Model_Na_Channel.PNG|Hodgkin-Huxley H and M Gate Model Na Channel | |||
File:Hodgkin_Huxley_Model_Activation_Variables.PNG|Hodgkin-Huxley Model Activation Variables | |||
File:Hodgkin_Huxley_Model_Activation_Time_Constants.PNG|Hodgkin-Huxley Model Activation Time Constants | |||
File:Depolarizing_Prepulse.PNG|Depolarizing Prepulse | |||
File:Sodium-channel.svg|Sodium Channel | |||
File:Poletto_2002_pain_plot_2.PNG|Poletto 2002 Pain Plot | |||
File:Nerve_Fiber_Recruitment_Inversion_Plot.png|Nerve Fiber Recruitment Inversion Plot | |||
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Latest revision as of 11:32, 18 February 2025
Depolarizing prepulse is a term used in neuroscience and cardiology to describe a technique used to study the properties of voltage-gated ion channels. These channels are crucial for the propagation of action potentials in neurons and muscle cells.
Overview[edit]
A depolarizing prepulse is a brief, strong depolarization of the membrane potential that precedes the actual test pulse. This technique is used to inactivate certain types of voltage-gated ion channels, such as the Na+ channel, before the test pulse is applied. This allows researchers to isolate the properties of other types of channels, such as the K+ channel, that are not inactivated by the prepulse.
Mechanism[edit]
The depolarizing prepulse works by exploiting the inactivation properties of certain types of voltage-gated ion channels. These channels have a voltage-dependent inactivation mechanism, which means that they become inactivated, or unable to open, when the membrane potential is depolarized. By applying a strong depolarizing prepulse, these channels can be inactivated before the test pulse is applied. This allows the properties of other types of channels to be studied in isolation.
Applications[edit]
Depolarizing prepulses are used in a variety of research settings. They are commonly used in patch clamp studies to isolate the properties of specific types of ion channels. They can also be used in studies of neuronal excitability and cardiac electrophysiology.
See also[edit]
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Hodgkin-Huxley H and M Gate Model Na Channel
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Hodgkin-Huxley Model Activation Variables -
Hodgkin-Huxley Model Activation Time Constants
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Depolarizing Prepulse -
Sodium Channel -
Poletto 2002 Pain Plot -
Nerve Fiber Recruitment Inversion Plot
