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nanoHUB-U Bioelectricity L3.2: Biological Conductors - Core Conductor Model

nanoHUB-U Bioelectricity L3.2: Biological Conductors - Core Conductor Model

nanoHUB-U Bioelectricity L3.1: Biological Conductors - Electrical Variables in Cells

nanoHUB-U Bioelectricity L3.1: Biological Conductors - Electrical Variables in Cells

nanoHUB-U Bioelectricity L3.1: Biological Conductors - Electrical Variables in Cells

nanoHUB-U Bioelectricity L3.1: Biological Conductors - Electrical Variables in Cells

nanoHUB-U Bioelectricity L3.3: Biological Conductors - Observations from Action Potentials

nanoHUB-U Bioelectricity L3.3: Biological Conductors - Observations from Action Potentials

nanoHUB-U Bioelectricity L3.5: Biological Conductors - Time-dependent Solutions

nanoHUB-U Bioelectricity L3.5: Biological Conductors - Time-dependent Solutions

nanoHUB-U Bioelectricity L1.3: The Nervous System - Electrical Signals in Cells

nanoHUB-U Bioelectricity L1.3: The Nervous System - Electrical Signals in Cells

nanoHUB-U Introduction to Bioelectricity: Scientific Overview

nanoHUB-U Introduction to Bioelectricity: Scientific Overview

nanoHUB-U Bioelectricity L2.5: Chemical Basis - Neurotransmitters and Pathology

nanoHUB-U Bioelectricity L2.5: Chemical Basis - Neurotransmitters and Pathology

nanoHUB-U Bioelectricity L3.4: Biological Conductors - Derivation of the Cable Model

nanoHUB-U Bioelectricity L3.4: Biological Conductors - Derivation of the Cable Model

nanoHUB-U Bioelectricity L4.3: Hodgkin-Huxley Model - Derivation of the Hodgkin-Huxley Equation

nanoHUB-U Bioelectricity L4.3: Hodgkin-Huxley Model - Derivation of the Hodgkin-Huxley Equation

nanoHUB-U Bioelectricity L5.2: Applications of Bioelectricity - Epilepsy

nanoHUB-U Bioelectricity L5.2: Applications of Bioelectricity - Epilepsy

nanoHUB-U Fundamentals of AFM L2.3: Analytical Theory - Nonlinearity, Virial, and Dissipation

nanoHUB-U Fundamentals of AFM L2.3: Analytical Theory - Nonlinearity, Virial, and Dissipation

nanoHUB-U Bioelectricity L2.2: Chemical Basis - Time & Space in Propagating Signals

nanoHUB-U Bioelectricity L2.2: Chemical Basis - Time & Space in Propagating Signals

Introduction to Bioelectricity | PurdueX on edX | Course About Video

Introduction to Bioelectricity | PurdueX on edX | Course About Video

nanoHUB-U Bioelectricity L2.1: Chemical Basis - TIC & DOC

nanoHUB-U Bioelectricity L2.1: Chemical Basis - TIC & DOC

nanoHUB-U Bioelectricity L2.3: Chemical Basis - Ion Channels

nanoHUB-U Bioelectricity L2.3: Chemical Basis - Ion Channels

nanoHUB-U Bioelectricity L4.1: Hodgkin-Huxley Model - Alan Hodgkin and Andrew Huxley

nanoHUB-U Bioelectricity L4.1: Hodgkin-Huxley Model - Alan Hodgkin and Andrew Huxley

nanoHUB-U Bioelectricity L4.2: Hodgkin-Huxley Model - Ionic Conductances

nanoHUB-U Bioelectricity L4.2: Hodgkin-Huxley Model - Ionic Conductances

nanoHUB-U Biodesign L1.1: Introduction - Cells by the Numbers

nanoHUB-U Biodesign L1.1: Introduction - Cells by the Numbers

nanoHUB-U Bioelectricity L1.5: The Nervous System - Nernst Equation

nanoHUB-U Bioelectricity L1.5: The Nervous System - Nernst Equation

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