Presentation is loading. Please wait.

Presentation is loading. Please wait.

Intro to Neurobiology 20041 Membrane excitability The action potential.

Published byDarlene Fox Modified over 8 years ago

Similar presentations

Presentation on theme: "Intro to Neurobiology 20041 Membrane excitability The action potential."— Presentation transcript:

1 Intro to Neurobiology 20041 Membrane excitability The action potential

2 Intro to Neurobiology 20042 Outline Passive and active conduction in neurons Action potential phenomenology Participating currents Voltage clamp experiments Voltage dependence: activation and inactivation Qualitative mechanistic description of action potential phenomenology

3 Intro to Neurobiology 20043 Reminder: passive conduction

4 Intro to Neurobiology 20044 Propagation of action potentials Depends on passive membrane properties Conduction velocity increases with λ And decreases with τ

5 Intro to Neurobiology 20045 Improving conduction velocity Increased diameter (squid…) –Problem: limited space Myelin –Increases R m –Decreases C –Allows energetically efficient signaling

6 Intro to Neurobiology 20046 Myelin PNS-Schwann cells –1 per internode CNS- Oligodendrocytes –1 per several axonal processes 10-160 membrane wraps –Cytoplasm is squeezed out

7 Intro to Neurobiology 20047 Saltatory conduction Passive conductance in internodes Active AP regeneration in nodes of Ranvier

8 Intro to Neurobiology 20048 Differential channel constitution

9 Intro to Neurobiology 20049 Demyelination Slowing of conduction Desynchronization of different fibers Conduction block –Complete –At high frequencies

10 Intro to Neurobiology 200410 Conduction velocity Mylinated: –Aα 80-120m/s –Aβ30-80m/s –aδ5-30m/s Unmylinated: –C<2m/s

11 Intro to Neurobiology 200411 Geometrical considerations Theoretically, myelin=0.7 total diameter –Experimentally, 0.6-0.8 Theoretically, internodes should be 100*d –Experimentally they are. Problems may arise at –Sudden expansion of membranes –Branching –Unmyelinated regions Safety factor

12 Intro to Neurobiology 200412 The action potential- phenomenology Rapidly conducting Non-attenuated Fast electrical signal

13 Intro to Neurobiology 200413 Characterized by Voltage overshoot All or none Refractoriness Accommodation phenomena –Accommodation to depolarization –Accommodation to hyperpolarization

14 Intro to Neurobiology 200414 All-or-none Explosive depolarization upon threshold crossing

15 Intro to Neurobiology 200415 Refractoriness Refractory period –Absolute: No amount of current will produce a second action potential –Relative: Second action potential will be achieved with only with larger currents

16 Intro to Neurobiology 200416 Accommodation phenomena Accommodation I –After prolonged depolarization subsequent APs to are Less frequent Smaller Depolarization block –Prolonged hyperpolarization Lowers threshold of action potential Increases its amplitude Anodic break response

17 Intro to Neurobiology 200417 Role of Na + and K +

18 Intro to Neurobiology 200418 Early clues Total conductance is increased during action potential (Cole and Curtis, 1938) Voltage overshoot at the peak of the action potential (Hodgkin and Huxley, 1939) Rapid repolarization of the membrane

19 Intro to Neurobiology 200419 Early findings Action potential amplitude depends on extracellular Na + concentration (Hodgkin and Katz, 1949)

20 Intro to Neurobiology 200420 Participating currents Hodgkin Huxley experiments Captured voltage dependence and kinetics of the participating currents in the squid giant axon

21 Intro to Neurobiology 200421 Recall I ion =g ion (V m -E ion ) g ion =I ion V m -E ion But they are interdependent: g(V m )V m (g) I total =I C +I R

22 Intro to Neurobiology 200422 Voltage clamp setup V m is controlled Vm=Vc After 1 st step

23 Intro to Neurobiology 200423 Voltage clamp experiments I early =I total -I late substitute Na + out with cholineH +

24 Intro to Neurobiology 200424 Or use selective neurotoxins TTX - High affinity voltage dependent Na + channel blocker Saxitoxin -’’- Cocaine – Low affinity voltage dependent Na + channel blocker TEA - Low affinity voltage dependent K + channel blocker

25 Intro to Neurobiology 200425 Na+ and K+ currents Note: direction time course inactivation

26 Intro to Neurobiology 200426 Voltage dependence

27 Intro to Neurobiology 200427 IV curve

28 Intro to Neurobiology 200428 Single channel recordings

29 Intro to Neurobiology 200429 Activation Activation: Increased probablity of channel opening with depolarization Deactivation: decreased probability of channel opening with repolarization

30 Intro to Neurobiology 200430 Peak conductance (V m ) g ion =I ion V m -E ion

31 Intro to Neurobiology 200431 Peak conductance (t)

Download ppt "Intro to Neurobiology 20041 Membrane excitability The action potential."

Similar presentations

Outline Neuronal excitability Nature of neuronal electrical signals Convey information over distances Convey information to other cells via synapses Signals.

Outline Neuronal excitability Nature of neuronal electrical signals Convey information over distances Convey information to other cells via synapses Signals.
Outline Neuronal excitability Nature of neuronal electrical signals Convey information over distances Convey information to other cells via synapses Signals.

Outline Neuronal excitability Nature of neuronal electrical signals Convey information over distances Convey information to other cells via synapses Signals.
Neuroscience: Exploring the Brain, 3e

Neuroscience: Exploring the Brain, 3e
Excitable membranes action potential & propagation Basic Neuroscience NBL 120 (2007)

Excitable membranes action potential & propagation Basic Neuroscience NBL 120 (2007)
Copyright © 2007 Wolters Kluwer Health | Lippincott Williams & Wilkins Neuroscience: Exploring the Brain, 3e Chapter 4: The Action Potential.

Copyright © 2007 Wolters Kluwer Health | Lippincott Williams & Wilkins Neuroscience: Exploring the Brain, 3e Chapter 4: The Action Potential.
Resting potential Action potential

Resting potential Action potential
Gated Ion Channels A. Voltage-gated Na + channels 5. generation of AP dependent only on Na + repolarization is required before another AP can occur K +

Gated Ion Channels A. Voltage-gated Na + channels 5. generation of AP dependent only on Na + repolarization is required before another AP can occur K +
Excitability Information processing in the retina Artificial neural networks Introduction to Neurobiology - 2004.

Excitability Information processing in the retina Artificial neural networks Introduction to Neurobiology
Cellular Neuroscience (207) Ian Parker Lecture # 4 - The Hodgkin- Huxley Axon

Cellular Neuroscience (207) Ian Parker Lecture # 4 - The Hodgkin- Huxley Axon
Equivalent Circuit of an Axon Membrane

Equivalent Circuit of an Axon Membrane
Chapter 4 The Action Potential. Introduction Action Potential in the Nervous System –Conveys information over long distances –Cytosol has negative charge.

Chapter 4 The Action Potential. Introduction Action Potential in the Nervous System –Conveys information over long distances –Cytosol has negative charge.
Figure 48.1 Overview of a vertebrate nervous system.

Figure 48.1 Overview of a vertebrate nervous system.
Propagation of the Action Potential The Central Dogma Of Excitable Tissues.

Propagation of the Action Potential The Central Dogma Of Excitable Tissues.
1 5. Chemical basis of action potentials a. Sodium hypothesis: (Hodgkin and Katz, 1949) [Na + ] e reduction affects a.p., not E M Proposed Na + hypothesis:

1 5. Chemical basis of action potentials a. Sodium hypothesis: (Hodgkin and Katz, 1949) [Na + ] e reduction affects a.p., not E M Proposed Na + hypothesis:
Chapter 4 The Action Potential. Introduction Action Potential –Cytosol (cytoplasm) has negative charge relative to extracellular space –Its pusatile nature.

Chapter 4 The Action Potential. Introduction Action Potential –Cytosol (cytoplasm) has negative charge relative to extracellular space –Its pusatile nature.
The Action Potential.

The Action Potential.
Cellular Neuroscience (207) Ian Parker Lecture # 5 - Action potential propagation

Cellular Neuroscience (207) Ian Parker Lecture # 5 - Action potential propagation
Action potentials do/are NOT - Proportional to the stimulus size - Act locally - Attenuate with distance - Spread in both directions - Take place in many.

Action potentials do/are NOT - Proportional to the stimulus size - Act locally - Attenuate with distance - Spread in both directions - Take place in many.
Nervous System Neurophysiology.

Nervous System Neurophysiology.
Chapter 5 Membrane Potential and Action Potential Copyright © 2014 Elsevier Inc. All rights reserved.

Chapter 5 Membrane Potential and Action Potential Copyright © 2014 Elsevier Inc. All rights reserved.

Similar presentations

Ads by Google