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Box 3A The Voltage Clamp Technique

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Presentation on theme: "Box 3A The Voltage Clamp Technique"— Presentation transcript:

1 Box 3A The Voltage Clamp Technique
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2 Box 3A The Voltage Clamp Technique
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3 Figure 3.1 Current flow across a squid axon membrane during a voltage clamp experiment
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4 Figure 3.1 Current flow across a squid axon membrane during a voltage clamp experiment (Part 1)
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5 Figure 3.1 Current flow across a squid axon membrane during a voltage clamp experiment (Part 2)
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6 Figure 3.2 Current produced by membrane depolarizations to several different potentials
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7 Figure 3.2 Current produced by membrane depolarizations to several different potentials (Part 1)
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8 Figure 3.2 Current produced by membrane depolarizations to several different potentials (Part 2)
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9 Figure 3.3 Relationship between current amplitude and membrane potential
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10 Figure 3.4 Dependence of the early inward current on sodium
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11 Figure 3.5 Pharmacological separation of Na+ and K+ currents
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12 Figure 3.6 Membrane conductance changes underlying the action potential are time- and voltage-dependent neuro4e-fig jpg

13 Figure 3.6 Membrane conductance changes underlying the action potential are time- and voltage-dependent (Part 1) neuro4e-fig r.jpg

14 Figure 3.6 Membrane conductance changes underlying the action potential are time- and voltage-dependent (Part 2) neuro4e-fig r.jpg

15 Figure 3.6 Membrane conductance changes underlying the action potential are time- and voltage-dependent (Part 3) neuro4e-fig r.jpg

16 Figure 3.6 Membrane conductance changes underlying the action potential are time- and voltage-dependent (Part 4) neuro4e-fig r.jpg

17 Figure 3.7 Depolarization increases Na+ and K+ conductances of the squid giant axon
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18 Figure 3.8 Mathematical reconstruction of the action potential
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19 Figure 3.8 Mathematical reconstruction of the action potential (Part 1)
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20 Figure 3.8 Mathematical reconstruction of the action potential (Part 2)
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21 Figure 3.8 Mathematical reconstruction of the action potential (Part 3)
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22 Figure 3.9 Feedback cycles responsible for membrane potential changes during an action potential
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23 Box 3B Threshold neuro4e-box-03-b-0.jpg

24 Figure 3.10 Passive current flow in an axon
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25 Figure 3.10 Passive current flow in an axon (Part 1)
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26 Figure 3.10 Passive current flow in an axon (Part 2)
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27 Box 3C(1) Passive Membrane Properties
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28 Box 3C(2) Passive Membrane Properties
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29 Figure 3.11 Propagation of an action potential
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30 Figure 3.12 Action potential conduction requires both active and passive current flow
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31 Figure 3.12 Action potential conduction requires both active and passive current flow (Part 1)
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32 Figure 3.12 Action potential conduction requires both active and passive current flow (Part 2)
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33 Figure 3.13 Saltatory action potential conduction along a myelinated axon
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34 Figure 3.13 Saltatory action potential conduction along a myelinated axon (Part 1)
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35 Figure 3.13 Saltatory action potential conduction along a myelinated axon (Part 2)
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36 Figure 3.13 Saltatory action potential conduction along a myelinated axon (Part 3)
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37 Figure 3.14 Speed of action potential conduction in unmyelinated versus myelinated axons
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38 Figure 3.14 Speed of action potential conduction in unmyelinated versus myelinated axons (Part 1)
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39 Figure 3.14 Speed of action potential conduction in unmyelinated versus myelinated axons (Part 2)
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40 Figure 3.14 Speed of action potential conduction in unmyelinated versus myelinated axons (Part 3)
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