Fundamentals of Bioelectricity - Mammalian Nervous System and Neuromodulation

Fundamentals of Bioelectricity - Mammalian Nervous System and Neuromodulation

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nanoHUB-U Bioelectricity L5.1: Applications of Bioelectricity - Parkinson's Disease

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nanoHUB-U Bioelectricity L5.1: Applications of Bioelectricity - Parkinson's Disease

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Fundamentals of Bioelectricity - Mammalian Nervous System and Neuromodulation

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  1. 1 nanoHUB-U Bioelectricity L1.1: The Nervous System - Basic Organization of CNS & PNS
  2. 2 nanoHUB-U Bioelectricity L1.2: The Nervous System - Simple Neural Circuits
  3. 3 nanoHUB-U Bioelectricity L1.3: The Nervous System - Electrical Signals in Cells
  4. 4 nanoHUB-U Bioelectricity L1.4: The Nervous System - Resting Potential of Neuron Membranes
  5. 5 nanoHUB-U Bioelectricity L1.5: The Nervous System - Nernst Equation
  6. 6 nanoHUB-U Bioelectricity L2.1: Chemical Basis - TIC & DOC
  7. 7 nanoHUB-U Bioelectricity L2.2: Chemical Basis - Time & Space in Propagating Signals
  8. 8 nanoHUB-U Bioelectricity L2.3: Chemical Basis - Ion Channels
  9. 9 nanoHUB-U Bioelectricity L2.4: Chemical Basis - Post-Synaptic Receptors
  10. 10 nanoHUB-U Bioelectricity L2.5: Chemical Basis - Neurotransmitters and Pathology
  11. 11 nanoHUB-U Bioelectricity L3.1: Biological Conductors - Electrical Variables in Cells
  12. 12 nanoHUB-U Bioelectricity L3.2: Biological Conductors - Core Conductor Model
  13. 13 nanoHUB-U Bioelectricity L3.3: Biological Conductors - Observations from Action Potentials
  14. 14 nanoHUB-U Bioelectricity L3.4: Biological Conductors - Derivation of the Cable Model
  15. 15 nanoHUB-U Bioelectricity L3.5: Biological Conductors - Time-dependent Solutions
  16. 16 nanoHUB-U Bioelectricity L4.1: Hodgkin-Huxley Model - Alan Hodgkin and Andrew Huxley
  17. 17 nanoHUB-U Bioelectricity L4.2: Hodgkin-Huxley Model - Ionic Conductances
  18. 18 nanoHUB-U Bioelectricity L4.3: Hodgkin-Huxley Model - Derivation of the Hodgkin-Huxley Equation
  19. 19 nanoHUB-U Bioelectricity L4.4: Hodgkin-Huxley Model - Insights from Hodgkin-Huxley
  20. 20 nanoHUB-U Bioelectricity L4.5: Hodgkin-Huxley Model - Further Insights from Hodgkin-Huxley
  21. 21 nanoHUB-U Bioelectricity L5.1: Applications of Bioelectricity - Parkinson's Disease
  22. 22 nanoHUB-U Bioelectricity L5.2: Applications of Bioelectricity - Epilepsy
  23. 23 nanoHUB-U Bioelectricity L5.3: Applications of Bioelectricity - Drug Addiction
  24. 24 nanoHUB-U Bioelectricity L5.4: Applications of Bioelectricity - Targeted Muscle Reinnervation
  25. 25 nanoHUB-U Bioelectricity L5.5: Applications of Bioelectricity - Optogenetics
  26. 26 nanoHUB-U Bioelectricity L6.1: Discrete-time Solutions to Continuous-time Problems
  27. 27 nanoHUB-U Bioelectricity L6.2: Euler Method
  28. 28 nanoHUB-U Bioelectricity L6.3: Runge-Kutta Method
  29. 29 nanoHUB-U Bioelectricity L6.4: Solving Hodgkin-Huxley
  30. 30 nanoHUB-U Bioelectricity L6.5: 4th Order Runge-Kutta HH Solution in Python
  31. 31 nanoHUB-U Bioelectricity L7.1: Analog Front End
  32. 32 nanoHUB-U Bioelectricity L7.2: Filtering
  33. 33 nanoHUB-U Bioelectricity L7.3: Analog-to-digital Conversion
  34. 34 nanoHUB-U Bioelectricity L7.4: Full System
  35. 35 nanoHUB-U Bioelectricity L7.5: Bioelectric Prosthesis Control

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