Voltage-gated channels are crucial in action potential initiation and propagation and there are many diseases and disorders related to them. Additionally, the classical mechanics are the main mechanics used to describe the function of the voltage-gated channels and their related abnormalities. However, the quantum mechanics should be considered to unravel new aspects in the voltage-gated channels and resolve the problems and challenges that classical mechanics cannot solve. In the present study, the aim is to mathematically show that quantum mechanics can exhibit a powerful tendency to unveil novel electrical features in voltage-gated channels and be used as a promising tool to solve the problems and challenges in the pathophysiology of exc...
Ion channels, which are found in every biological cell, regulate the concentration of electrolytes, ...
We have approached the problem of nerve excitability through three questions: (a) What is the diagra...
Ion channels are biological nanotubes that are formed by membrane proteins. Because ion channels reg...
Voltage-sensitive ion channels are macromolecules embedded in the membranes of nerve and muscle fibe...
Over two-thirds of a century ago, Hodgkin and Huxley proposed the existence of voltage gated ion cha...
GABA (gamma-aminobutyric acid) receptors represent the major inhibitory receptors in the nervous sys...
We present a comparison of a classical and a quantum mechanical calculation of the motion of K+ ions...
We consider a model for voltage-dependent gating of channels in which the gating charges are on the ...
Quantum mechanics -by using what we know about the system now- provides us information about the fut...
Voltage-gated ion channels play fundamental roles in neural excitability and thus dysfunctional chan...
Lithium imposes several cellular effects allegedly through multiple physiological mechanisms. Membra...
Proper ion channels’ functioning is a prerequisite for a normal cell and disorders involving ion cha...
International audienceEditorial on the Research Topic Molecular Mechanisms of Voltage-Gating in Ion ...
Voltage-gated ion channels are of great importance in the generation and propagation of electrical s...
A general quantum-mechanical description of molecular transport across biological membranes has been...
Ion channels, which are found in every biological cell, regulate the concentration of electrolytes, ...
We have approached the problem of nerve excitability through three questions: (a) What is the diagra...
Ion channels are biological nanotubes that are formed by membrane proteins. Because ion channels reg...
Voltage-sensitive ion channels are macromolecules embedded in the membranes of nerve and muscle fibe...
Over two-thirds of a century ago, Hodgkin and Huxley proposed the existence of voltage gated ion cha...
GABA (gamma-aminobutyric acid) receptors represent the major inhibitory receptors in the nervous sys...
We present a comparison of a classical and a quantum mechanical calculation of the motion of K+ ions...
We consider a model for voltage-dependent gating of channels in which the gating charges are on the ...
Quantum mechanics -by using what we know about the system now- provides us information about the fut...
Voltage-gated ion channels play fundamental roles in neural excitability and thus dysfunctional chan...
Lithium imposes several cellular effects allegedly through multiple physiological mechanisms. Membra...
Proper ion channels’ functioning is a prerequisite for a normal cell and disorders involving ion cha...
International audienceEditorial on the Research Topic Molecular Mechanisms of Voltage-Gating in Ion ...
Voltage-gated ion channels are of great importance in the generation and propagation of electrical s...
A general quantum-mechanical description of molecular transport across biological membranes has been...
Ion channels, which are found in every biological cell, regulate the concentration of electrolytes, ...
We have approached the problem of nerve excitability through three questions: (a) What is the diagra...
Ion channels are biological nanotubes that are formed by membrane proteins. Because ion channels reg...