Lecture

Ion channels: Structure and Function

Related lectures (32)

Covers the role of ion channels in biological processes, from bacterial resistance to neuronal signaling and pain modulation.

Ion Channels: Structure and Function

Explores the biophysics of ion channels and their vital role in neuronal signaling and physiological processes.

Ion Channels: Structure and Function

Explores the structure, function, and classification of ion channels, their role in brain function, and their significance in various diseases.

Ion Channels: Structure and Function

Explores the structure and function of ion channels, their classification, membrane permeability, and role in single-cell activities.

Electricity in Cells

Explores the physical basis of signal propagation in neurons, focusing on membrane potential setup and ion channels.

Action Potentials and Electrical Excitability

Explores the generation and propagation of action potentials in neurons, including the historical significance of Hodgkin & Huxley's work.

Cellular Mechanisms of Brain Function

Explores the electrical properties of cell membranes and their role in brain function.

Resting Membrane Potential

Discusses resting membrane potential, ion channels, and the Na+/K+ pump.

Cellular Mechanisms of Brain Function

Explores cellular mechanisms of brain function, focusing on ion channels and action potentials.

Ion Channels

Explores the profiling and behavior of ion channels, including their diversity and classes.

Electrophysiology: Ion Channels and Recordings

Explores electrophysiology principles, ion channels modulation, recording techniques, and analysis of cellular activity.

Modeling the electrical activity of the neuron

Explores the modeling of neuron electrical activity, including ion channels and concentrations, Nernst equation, and resting potential.

Voltage-gated channels

Explores the cellular mechanisms of brain function through voltage-gated ion channels and their role in regulating membrane potential.

Micro-ElectroMechanical Systems (MEMS)

Explores Micro-ElectroMechanical Systems (MEMS) development, ion channels, patch clamp technique, drug discovery, and PDMS integration in microfluidic systems.

Hodgkin & Huxley model: Spike Dynamics

Explores the Hodgkin & Huxley model, focusing on spike dynamics and membrane currents in excitable cells.

Untitled

Nicotinic Receptors: Structure and Function

Explores the structure and function of nicotinic receptors, focusing on Cys-loop receptors, ion conductance, and the effects of nicotine.

Membrane potential: Cellular mechanisms

Explains membrane potential, equilibrium potentials, and ion conductances' role in determining the membrane potential.

Untitled

Action potential propagation: Mechanisms and Speed

Explores the cellular mechanisms and speed of action potential propagation in neurons.