News & Research
All in One: The false dichotomy of electrical vs mechanical nature of action potentials
The article summarises our approach to the physics of action potential at a fundamental level and addresses some of the criticism and misconception related to its application to nerves, such as how it addresses the dissipation and temperature dependence of action potentials.
All in One: The false dichotomy of electrical vs mechanical nature of action potentials
The article summarises our approach to the physics of action potential at a fundamental level and addresses some of the criticism and misconception related to its application to nerves, such as how it addresses the dissipation and temperature dependence of action potentials.
Action Potentials are all in one: The false dichotomy of electrical vs mechanical
The article summarises our approach to the physics of action potential and addresses some of the criticism and misconception related to its application to nerves, in particular, how it addresses the dissipation and temperature dependence of action potentials.
Action Potentials are all in one: The false dichotomy of electrical vs mechanical
The article summarises our approach to the physics of action potential and addresses some of the criticism and misconception related to its application to nerves, in particular, how it addresses the dissipation and temperature dependence of action potentials.
A list of key recent papers on action potentials and channels in pure lipid interfaces
The following is a list of my key papers on electromechanical waves in pure lipid monolayers, essentially a negative control for Hodgkin and Huxley based description of Action Potentials (AP) (without channel, pumps and chemical gradient).
A list of key recent papers on action potentials and channels in pure lipid interfaces
The following is a list of my key papers on electromechanical waves in pure lipid monolayers, essentially a negative control for Hodgkin and Huxley based description of Action Potentials (AP) (without channel, pumps and chemical gradient).
Sound waves in lipid films can annihilate each other upon collision, just like action potentials in neurons
Nerve impulses, also known as action potentials, are believed to propagate in a manner similar to the conduction of current in an electrical cable.
Sound waves in lipid films can annihilate each other upon collision, just like action potentials in neurons
Nerve impulses, also known as action potentials, are believed to propagate in a manner similar to the conduction of current in an electrical cable.
Sound waves can annihilate each other upon collision, just like action potentials in neurons
Nerve impulses, also known as action potentials, are believed to propagate in a manner similar to the conduction of current in an electrical cable.
Sound waves can annihilate each other upon collision, just like action potentials in neurons
Nerve impulses, also known as action potentials, are believed to propagate in a manner similar to the conduction of current in an electrical cable.
Brain Cells Communicate with Mechanical Pulses, Not Electric Signals
Physicists who have revived experiments from 50 years ago say nerve cells communicate with mechanical pulses, not electric ones
Brain Cells Communicate with Mechanical Pulses, Not Electric Signals
Physicists who have revived experiments from 50 years ago say nerve cells communicate with mechanical pulses, not electric ones
What if a machine could help you feel the true texture of a material, the taste of an ingredient, the efficacy of a new drug?