Figure 48 17 Functional hierarchy of the peripheral

Figure 48. 17 Functional hierarchy of the peripheral nervous system

Figure 48. 2 Structure of a vertebrate neuron

Figure 48. 4 Structural diversity of neurons

Figure 48. 5 Schwann cells

Figure 48. 1 Overview of a vertebrate nervous system

Figure 48. 3 The knee-jerk reflex

Figure 48. 6 Measuring membrane potentials

Figure 48. 7 The basis of the membrane potential

Figure 48. 8 Graded potentials and the action potential in a neuron

Figure 48. 9 The role of voltage-gated ion channels in the action potential (Layer

Figure 48. 9 The role of voltage-gated ion channels in the action potential (Layer

Figure 48. 9 The role of voltage-gated ion channels in the action potential (Layer

Figure 48. 9 The role of voltage-gated ion channels in the action potential (Layer

Figure 48. 9 The role of voltage-gated ion channels in the action potential (Layer

Figure 48. 10 Propagation of the action potential

Figure 48. 11 Saltatory conduction

Figure 48. 12 A chemical synapse

Figure 48. 13 Integration of multiple synaptic inputs

Figure 48. 14 Summation of postsynaptic potentials

Table 48. 1 The Major Known Neurotransmitters

Figure 48. 15 Diversity in nervous systems

Figure 48. 16 The nervous system of a vertebrate

Figure 48. 16 x Spinal cord

Figure 48. 18 The main roles of the parasympathetic and sympathetic nerves in regulating

Figure 48. 20 x 1 Cerebral cortex, gray and white matter

Figure 48. 19 Embryonic development of the brain

Figure 48. 20 The main parts of the human brain

Figure 48. 20 x 2 Cerebral cortex

Figure 48. 24 Structure and functional areas of the cerebrum

Figure 48. 26 Mapping language areas of the cerebral cortex

Figure 48. 25 Primary motor and somatosensory areas of the human cerebral cortex

Figure 48. 27 The limbic system

Figure 48. 21 The reticular formation

Fugure 48. 22 a Electroencephalogram (EEG) electrodes

Figure 48. 22 b-d Brain waves recorded by an electroencephalogram (EEG)

Figure 48. 23 Activity rhythms in a nocturnal mammal, the northern flying squirrel

Figure 48. 28 How do developing axons know which way to go?

Figure 48. 28 x 1 Brain MRI

Figure 48. 29 Neural progenitor cell

Figure 48. 0 x 1 Aplysia neuron

Figure 48. 0 x 2 Frog neuron

Figure 48. 2 x Neurons

Figure 48. 0 A neuron on a microprocessor

Slides: 43

Download presentation

Figure 48. 17 Functional hierarchy of the peripheral nervous system

Figure 48. 17 Functional hierarchy of the peripheral nervous system

Figure 48. 2 Structure of a vertebrate neuron

Figure 48. 2 Structure of a vertebrate neuron

Figure 48. 4 Structural diversity of neurons

Figure 48. 4 Structural diversity of neurons

Figure 48. 5 Schwann cells

Figure 48. 5 Schwann cells

Figure 48. 1 Overview of a vertebrate nervous system

Figure 48. 1 Overview of a vertebrate nervous system

Figure 48. 3 The knee-jerk reflex

Figure 48. 3 The knee-jerk reflex

Figure 48. 6 Measuring membrane potentials

Figure 48. 6 Measuring membrane potentials

Figure 48. 7 The basis of the membrane potential

Figure 48. 7 The basis of the membrane potential

Figure 48. 8 Graded potentials and the action potential in a neuron

Figure 48. 8 Graded potentials and the action potential in a neuron

Figure 48. 9 The role of voltage-gated ion channels in the action potential (Layer

Figure 48. 9 The role of voltage-gated ion channels in the action potential (Layer 1)

Figure 48. 9 The role of voltage-gated ion channels in the action potential (Layer

Figure 48. 9 The role of voltage-gated ion channels in the action potential (Layer 2)

Figure 48. 9 The role of voltage-gated ion channels in the action potential (Layer

Figure 48. 9 The role of voltage-gated ion channels in the action potential (Layer 3)

Figure 48. 9 The role of voltage-gated ion channels in the action potential (Layer

Figure 48. 9 The role of voltage-gated ion channels in the action potential (Layer 4)

Figure 48. 9 The role of voltage-gated ion channels in the action potential (Layer

Figure 48. 9 The role of voltage-gated ion channels in the action potential (Layer 5)

Figure 48. 10 Propagation of the action potential

Figure 48. 10 Propagation of the action potential

Figure 48. 11 Saltatory conduction

Figure 48. 11 Saltatory conduction

Figure 48. 12 A chemical synapse

Figure 48. 12 A chemical synapse

Figure 48. 13 Integration of multiple synaptic inputs

Figure 48. 13 Integration of multiple synaptic inputs

Figure 48. 14 Summation of postsynaptic potentials

Figure 48. 14 Summation of postsynaptic potentials

Table 48. 1 The Major Known Neurotransmitters

Table 48. 1 The Major Known Neurotransmitters

Figure 48. 15 Diversity in nervous systems

Figure 48. 15 Diversity in nervous systems

Figure 48. 16 The nervous system of a vertebrate

Figure 48. 16 The nervous system of a vertebrate

Figure 48. 16 x Spinal cord

Figure 48. 16 x Spinal cord

Figure 48. 18 The main roles of the parasympathetic and sympathetic nerves in regulating

Figure 48. 18 The main roles of the parasympathetic and sympathetic nerves in regulating internal body functions

Figure 48. 20 x 1 Cerebral cortex, gray and white matter

Figure 48. 20 x 1 Cerebral cortex, gray and white matter

Figure 48. 19 Embryonic development of the brain

Figure 48. 19 Embryonic development of the brain

Figure 48. 20 The main parts of the human brain

Figure 48. 20 The main parts of the human brain

Figure 48. 20 x 2 Cerebral cortex

Figure 48. 20 x 2 Cerebral cortex

Figure 48. 24 Structure and functional areas of the cerebrum

Figure 48. 24 Structure and functional areas of the cerebrum

Figure 48. 26 Mapping language areas of the cerebral cortex

Figure 48. 26 Mapping language areas of the cerebral cortex

Figure 48. 25 Primary motor and somatosensory areas of the human cerebral cortex

Figure 48. 25 Primary motor and somatosensory areas of the human cerebral cortex

Figure 48. 27 The limbic system

Figure 48. 27 The limbic system

Figure 48. 21 The reticular formation

Figure 48. 21 The reticular formation

Fugure 48. 22 a Electroencephalogram (EEG) electrodes

Fugure 48. 22 a Electroencephalogram (EEG) electrodes

Figure 48. 22 b-d Brain waves recorded by an electroencephalogram (EEG)

Figure 48. 22 b-d Brain waves recorded by an electroencephalogram (EEG)

Figure 48. 23 Activity rhythms in a nocturnal mammal, the northern flying squirrel

Figure 48. 23 Activity rhythms in a nocturnal mammal, the northern flying squirrel

Figure 48. 28 How do developing axons know which way to go?

Figure 48. 28 How do developing axons know which way to go?

Figure 48. 28 x 1 Brain MRI

Figure 48. 28 x 1 Brain MRI

Figure 48. 29 Neural progenitor cell

Figure 48. 29 Neural progenitor cell

Figure 48. 0 x 1 Aplysia neuron

Figure 48. 0 x 1 Aplysia neuron

Figure 48. 0 x 2 Frog neuron

Figure 48. 0 x 2 Frog neuron

Figure 48. 2 x Neurons

Figure 48. 2 x Neurons

Figure 48. 0 A neuron on a microprocessor

Figure 48. 0 A neuron on a microprocessor