Explores the biophysics of ion channels and their vital role in neuronal signaling and physiological processes.
Explores the optimization of neuroprosthetic systems, including sensory feedback restoration and neural stimulation strategies.
Explores synaptic transmission, neurotransmitters, and neural plasticity principles.
Explores the structure, function, and classification of ion channels, their role in brain function, and their significance in various diseases.
Explores the modeling of neuron electrical activity, including ion channels and concentrations, Nernst equation, and resting potential.
Explores the challenges and solutions for managing electron dose in microscopy, emphasizing the importance of accurate dose tracking and analysis.
Discusses resting membrane potential, ion channels, and the Na+/K+ pump.
Explores detailed modeling of ion channels and neuronal morphologies in in silico neuroscience, covering neuron classification, ion channel kinetics, and experimental observations.
Explores the Hodgkin-Huxley model, action potential phases, ion dynamics, cable theory, and compartmental modeling in neuronal excitability.
Explores neural network simulation, activity dynamics, and validation processes to ensure accurate predictions.
