Figure A1 Types of electrical signals in neurons

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Figure A1 Types of electrical signals in neurons
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Figure A1 Types of electrical signals in neurons
(Part 1)
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Figure A1 Types of electrical signals in neurons
(Part 2)
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Figure A1 Types of electrical signals in neurons
(Part 3)
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Figure A2 Ion transporters and ion channels
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Figure A2 Ion transporters and ion channels
(Part 1)
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Figure A2 Ion transporters and ion channels
(Part 2)
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Figure A3 Electrochemical equilibrium
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Figure A4 Resting and action potentials entail
permeabilities to different ions
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Figure A5 Functional states of voltage-gated Na
and K channels
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Figure A5 Functional states of voltage-gated Na
and K channels (Part 1)
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Figure A5 Functional states of voltage-gated Na
and K channels (Part 2)
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Figure A6 Changes in membrane permeability
underlie the action potential
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Figure A7 Recording passive and active
electrical signals in a nerve cell
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Figure A7 Recording passive and active
electrical signals in a nerve cell (Part 1)
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Figure A7 Recording passive and active
electrical signals in a nerve cell (Part 2)
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Figure A7 Recording passive and active
electrical signals in a nerve cell (Part 3)
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Figure A8 Positive and negative feedback loops
during an action potential
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Figure A9 Passive current flow in an axon
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Figure A10 Propagation of an action potential
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Figure A11 Action potential conduction requires
both active and passive current flow
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Figure A11 Action potential conduction requires
both active and passive current flow (Part 1)
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Figure A11 Action potential conduction requires
both active and passive current flow (Part 2)
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Figure A11 Action potential conduction requires
both active and passive current flow (Part 3)
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Figure A12 Saltatory action potential conduction
along a myelinated axon
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Figure A12 Saltatory action potential conduction
along a myelinated axon (Part 1)
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Figure A12 Saltatory action potential conduction
along a myelinated axon (Part 2)
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Figure A12 Saltatory action potential conduction
along a myelinated axon (Part 3)
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Figure A13 Electrical and chemical synapses
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Figure A13 Electrical and chemical synapses
(Part 1)
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Figure A13 Electrical and chemical synapses
(Part 2)
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Figure A14 Sequence of events at a typical
chemical synapse
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Figure A14 Sequence of events at a typical
chemical synapse
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Figure A15 Examples of small-molecule and
peptide neurotransmitters
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Figure A15 Examples of small-molecule and
peptide neurotransmitters (Part 1)
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Figure A15 Examples of small-molecule and
peptide neurotransmitters (Part 2)
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Figure A15 Examples of small-molecule and
peptide neurotransmitters (Part 3)
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Figure A15 Examples of small-molecule and
peptide neurotransmitters (Part 4)
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Figure A15 Examples of small-molecule and
peptide neurotransmitters (Part 5)
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Figure A16 Neurotransmitter receptors in the
postsynaptic cell
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Figure A16 Neurotransmitter receptors in the
postsynaptic cell (Part 1)
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Figure A16 Neurotransmitter receptors in the
postsynaptic cell (Part 2)
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Figure A17 Glutamate synthesis and cycling
between neurons and glia
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Figure A18 NMDA and AMPA/kainate receptors
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Figure A18 NMDA and AMPA/kainate receptors (Part
1)
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Figure A18 NMDA and AMPA/kainate receptors (Part
2)
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Figure A18 NMDA and AMPA/kainate receptors (Part
3)
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Figure A19 Reversal threshold potentials
determine postsynaptic excitation inhibition
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Figure A19 Reversal threshold potentials
determine postsynaptic excitation inhibition
(Part 1)
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Figure A19 Reversal threshold potentials
determine postsynaptic excitation inhibition
(Part 2)
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Figure A20 Summation of postsynaptic potentials
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Figure A20 Summation of postsynaptic potentials
(Part 1)
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Figure A20 Summation of postsynaptic potentials
(Part 2)
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