Title: Figure A1 Types of electrical signals in neurons
1Figure A1 Types of electrical signals in neurons
2Figure A1 Types of electrical signals in neurons
(Part 1)
3Figure A1 Types of electrical signals in neurons
(Part 2)
4Figure A1 Types of electrical signals in neurons
(Part 3)
5Figure A2 Ion transporters and ion channels
6Figure A2 Ion transporters and ion channels
(Part 1)
7Figure A2 Ion transporters and ion channels
(Part 2)
8Figure A3 Electrochemical equilibrium
9Figure A4 Resting and action potentials entail
permeabilities to different ions
10Figure A5 Functional states of voltage-gated Na
and K channels
11Figure A5 Functional states of voltage-gated Na
and K channels (Part 1)
12Figure A5 Functional states of voltage-gated Na
and K channels (Part 2)
13Figure A6 Changes in membrane permeability
underlie the action potential
14Figure A7 Recording passive and active
electrical signals in a nerve cell
15Figure A7 Recording passive and active
electrical signals in a nerve cell (Part 1)
16Figure A7 Recording passive and active
electrical signals in a nerve cell (Part 2)
17Figure A7 Recording passive and active
electrical signals in a nerve cell (Part 3)
18Figure A8 Positive and negative feedback loops
during an action potential
19Figure A9 Passive current flow in an axon
20Figure A10 Propagation of an action potential
21Figure A11 Action potential conduction requires
both active and passive current flow
22Figure A11 Action potential conduction requires
both active and passive current flow (Part 1)
23Figure A11 Action potential conduction requires
both active and passive current flow (Part 2)
24Figure A11 Action potential conduction requires
both active and passive current flow (Part 3)
25Figure A12 Saltatory action potential conduction
along a myelinated axon
26Figure A12 Saltatory action potential conduction
along a myelinated axon (Part 1)
27Figure A12 Saltatory action potential conduction
along a myelinated axon (Part 2)
28Figure A12 Saltatory action potential conduction
along a myelinated axon (Part 3)
29Figure A13 Electrical and chemical synapses
30Figure A13 Electrical and chemical synapses
(Part 1)
31Figure A13 Electrical and chemical synapses
(Part 2)
32Figure A14 Sequence of events at a typical
chemical synapse
33Figure A14 Sequence of events at a typical
chemical synapse
34Figure A15 Examples of small-molecule and
peptide neurotransmitters
35Figure A15 Examples of small-molecule and
peptide neurotransmitters (Part 1)
36Figure A15 Examples of small-molecule and
peptide neurotransmitters (Part 2)
37Figure A15 Examples of small-molecule and
peptide neurotransmitters (Part 3)
38Figure A15 Examples of small-molecule and
peptide neurotransmitters (Part 4)
39Figure A15 Examples of small-molecule and
peptide neurotransmitters (Part 5)
40Figure A16 Neurotransmitter receptors in the
postsynaptic cell
41Figure A16 Neurotransmitter receptors in the
postsynaptic cell (Part 1)
42Figure A16 Neurotransmitter receptors in the
postsynaptic cell (Part 2)
43Figure A17 Glutamate synthesis and cycling
between neurons and glia
44Figure A18 NMDA and AMPA/kainate receptors
45Figure A18 NMDA and AMPA/kainate receptors (Part
1)
46Figure A18 NMDA and AMPA/kainate receptors (Part
2)
47Figure A18 NMDA and AMPA/kainate receptors (Part
3)
48Figure A19 Reversal threshold potentials
determine postsynaptic excitation inhibition
49Figure A19 Reversal threshold potentials
determine postsynaptic excitation inhibition
(Part 1)
50Figure A19 Reversal threshold potentials
determine postsynaptic excitation inhibition
(Part 2)
51Figure A20 Summation of postsynaptic potentials
52Figure A20 Summation of postsynaptic potentials
(Part 1)
53Figure A20 Summation of postsynaptic potentials
(Part 2)
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