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

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Presentation on theme: "Outline Neuronal excitability Nature of neuronal electrical signals Convey information over distances Convey information to other cells via synapses Signals."— Presentation transcript:

1 Outline Neuronal excitability Nature of neuronal electrical signals Convey information over distances Convey information to other cells via synapses Signals depend on changes in electrical potential Resting potential concepts Action potential Properties of action potentials (APs) Dynamics of potential explained by changes in Na+ and K+ permeabilities Voltage clamp (review) Na+ channel activation and inactivation kinetics K+ channel activation (and inactivation) kinetics AP propagation Ion transporters and Ion channels Complementary functions to maintain and use electrochemical gradient Transporters… Generate concentration gradients Channels… Use concentration gradients to make electrical signals

2 Outline Neuronal excitability Nature of neuronal electrical signals Convey information over distances Convey information to other cells via synapses Signals depend on changes in electrical potential Resting potential concepts Action potential Properties of action potentials (APs) Dynamics of potential explained by changes in Na+ and K+ permeabilities Voltage clamp (review) Na+ channel activation and inactivation kinetics K+ channel activation (and inactivation) kinetics AP propagation Ion transporters and Ion channels Complementary functions to maintain and use electrochemical gradient Transporters… Generate concentration gradients Channels… Use concentration gradients to make electrical signals

3 Figure 2.1 Types of neuronal electrical signals

4 Figure 2.2 Recording passive and active electrical signals in a nerve cell

5 Outline Neuronal excitability Nature of neuronal electrical signals Convey information over distances Convey information to other cells via synapses Signals depend on changes in electrical potential Resting potential concepts Action potential Properties of action potentials (APs) Dynamics of potential explained by changes in Na+ and K+ permeabilities Voltage clamp (review) Na+ channel activation and inactivation kinetics K+ channel activation (and inactivation) kinetics AP propagation Ion transporters and Ion channels Complementary functions to maintain and use electrochemical gradient Transporters… Generate concentration gradients Channels… Use concentration gradients to make electrical signals

6 Figure 2.3 Transporters and channels move ions across neuronal membranes

7 Figure 2.4 Electrochemical equilibrium

8 Nernst equation E k = 58/z * log [K] 2 /[K] 1 = 58 log 1/10 = -58 mV

9 Figure 2.5 Membrane potential influences ion fluxes

10 Goldman equation – multiple ionic species and permeabilities V = 58 log (P K [K] 2 +P Na [Na] 2 +P Cl [Cl] 1 (P K [K] 1 +P Na [Na] 1 +P Cl [Cl] 2 E k = 58/z * log [K] 2 /[K] 1 = 58 log 1/10 = -58 mV Reduces to Nernst if only one ion present or permeable…

11 Figure 2.6 Resting and action potentials arise from differential permeability to ions

12 Figure 2.7 Resting membrane potential is determined by the K + concentration gradient

13 Box 2A The Remarkable Giant Nerve Cells of Squid

14 Figure 2.8 The role of Na + in the generation of an action potential in a squid giant axon

15 Box 2B Action Potential Form and Nomenclature

16

17 Outline Neuronal excitability Nature of neuronal electrical signals Convey information over distances Convey information to other cells via synapses Signals depend on changes in electrical potential Resting potential concepts Action potential Properties of action potentials (APs) Dynamics of potential explained by changes in Na+ and K+ permeabilities Voltage clamp (review) Na+ channel activation and inactivation kinetics K+ channel activation (and inactivation) kinetics AP propagation Ion transporters and Ion channels Complementary functions to maintain and use electrochemical gradient Transporters… Generate concentration gradients Channels… Use concentration gradients to make electrical signals

18 Box 3A The Voltage Clamp Technique

19 Figure 3.1 Current flow across a squid axon membrane during a voltage clamp experiment

20 Figure 3.2 Current produced by membrane depolarizations to several different potentials

21 Figure 3.3 Relationship between current amplitude and membrane potential

22 Figure 3.4 Dependence of the early inward current on sodium

23 Outline Neuronal excitability Nature of neuronal electrical signals Convey information over distances Convey information to other cells via synapses Signals depend on changes in electrical potential Resting potential concepts Action potential Properties of action potentials (APs) Dynamics of potential explained by changes in Na+ and K+ permeabilities Voltage clamp (review) Na+ channel activation and inactivation kinetics K+ channel activation (and inactivation) kinetics AP propagation Ion transporters and Ion channels Complementary functions to maintain and use electrochemical gradient Transporters… Generate concentration gradients Channels… Use concentration gradients to make electrical signals

24 Figure 3.5 Pharmacological separation of Na + and K + currents

25 Figure 3.6 Membrane conductance changes underlying the action potential are time- and voltage- dependent

26 Figure 3.7 Depolarization increases Na + and K + conductances of the squid giant axon

27 Figure 3.8 Mathematical reconstruction of the action potential

28 Box 3B Threshold

29 Figure 3.10 Passive current flow in an axon

30 Box 3C(1) Passive Membrane Properties

31 Box 3C(2) Passive Membrane Properties

32 Outline Neuronal excitability Nature of neuronal electrical signals Convey information over distances Convey information to other cells via synapses Signals depend on changes in electrical potential Resting potential concepts Action potential Properties of action potentials (APs) Dynamics of potential explained by changes in Na+ and K+ permeabilities Voltage clamp (review) Na+ channel activation and inactivation kinetics K+ channel activation (and inactivation) kinetics AP propagation Ion transporters and Ion channels Complementary functions to maintain and use electrochemical gradient Transporters… Generate concentration gradients Channels… Use concentration gradients to make electrical signals

33 Figure 3.11 Propagation of an action potential

34 Figure 3.12 Action potential conduction requires both active and passive current flow

35 Figure 3.12 Action potential conduction requires both active and passive current flow (Part 2)

36 Figure 3.13 Saltatory action potential conduction along a myelinated axon

37 Figure 3.13 Saltatory action potential conduction along a myelinated axon (Part 1)

38 Figure 3.13 Saltatory action potential conduction along a myelinated axon (Part 2)

39 Figure 3.13 Saltatory action potential conduction along a myelinated axon (Part 3)

40 Figure 3.14 Speed of action potential conduction in unmyelinated versus myelinated axons

41 Outline Neuronal excitability Nature of neuronal electrical signals Convey information over distances Convey information to other cells via synapses Signals depend on changes in electrical potential Resting potential concepts Action potential Properties of action potentials (APs) Dynamics of potential explained by changes in Na+ and K+ permeabilities Voltage clamp (review) Na+ channel activation and inactivation kinetics K+ channel activation (and inactivation) kinetics AP propagation Ion transporters and Ion channels Complementary functions to maintain and use electrochemical gradient Transporters… Generate concentration gradients Channels… Use concentration gradients to make electrical signals

42 Figure 4.1 Patch clamp measurements of ionic currents through single Na + channels

43 Box 4A The Patch Clamp Method

44 Figure 4.2 Patch clamp measurements of ionic currents through single K + channels (Part 1)

45 Figure 4.2 Patch clamp measurements of ionic currents through single K + channels (Part 2)

46 Figure 4.3 Functional states of voltage-gated Na + and K + channels

47 Figure 4.4 Types of voltage-gated ion channels

48 Figure 4.5 Diverse properties of K + channels

49 Figure 4.6 Topology of principal subunits of voltage-gated Na +, Ca 2+, K +, and Cl – channels

50 Box 4C Toxins That Poison Ion Channels

51 Figure 4.7 A charged voltage sensor permits voltage-dependent gating of ion channels

52 Box 4D(1) Diseases Caused by Altered Ion Channels

53 Box 4D(2) Diseases Caused by Altered Ion Channels

54 Figure 4.10 Examples of ion transporters found in cell membranes (Part 1)

55 Figure 4.10 Examples of ion transporters found in cell membranes (Part 2)

56 Figure 4.11 Ion movements due to the Na + /K + pump

57 Figure 4.12 Electrogenic transport of ions by the Na +/ K + pump can influence membrane potential

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