Figure 23.1 Growth cones guide axons in the developing nervous system.

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Presentation transcript:

Figure 23.1 Growth cones guide axons in the developing nervous system

Figure 23.1 Growth cones guide axons in the developing nervous system (Part 1)

Figure 23.1 Growth cones guide axons in the developing nervous system (Part 2)

Figure 23.2 The structure and action of growth cones

Figure 23.2 The structure and action of growth cones (Part 1)

Figure 23.2 The structure and action of growth cones (Part 2)

Figure 23.2 The structure and action of growth cones (Part 3)

Box 23A Choosing Sides: Axon Guidance at the Optic Chiasm

Figure 23.3 The major classes of axon guidance molecules

Figure 23.3 The major classes of axon guidance molecules (Part 1)

Figure 23.3 The major classes of axon guidance molecules (Part 2)

Figure 23.3 The major classes of axon guidance molecules (Part 3)

Figure 23.3 The major classes of axon guidance molecules (Part 4)

Figure 23.3 The major classes of axon guidance molecules (Part 5)

Figure 23.3 The major classes of axon guidance molecules (Part 6)

Figure 23.4 Signals in embryo affect growth cones and growing axons

Figure 23.4 Signals in embryo affect growth cones and growing axons (Part 1)

Figure 23.4 Signals in embryo affect growth cones and growing axons (Part 2)

Figure 23.5 Netrins chemotropically regulate pathway formation in a developing spinal cord

Figure 23.5 Netrins chemotropically regulate pathway formation in a developing spinal cord (Part 1)

Figure 23.5 Netrins chemotropically regulate pathway formation in a developing spinal cord (Part 2)

Figure 23.6 Mechanisms of topographic mapping in the vertebrate visual system

Figure 23.6 Mechanisms of topographic mapping in the vertebrate visual system (Part 1)

Figure 23.6 Mechanisms of topographic mapping in the vertebrate visual system (Part 2)

Figure 23.6 Mechanisms of topographic mapping in the vertebrate visual system (Part 3)

Box 23B Molecular Signals That Promote Synapse Formation

Figure 23.7 Molecular mechanisms involved in synapse formation

Figure 23.7 Molecular mechanisms involved in synapse formation (Part 1)

Figure 23.7 Molecular mechanisms involved in synapse formation (Part 2)

Figure 23.7 Molecular mechanisms involved in synapse formation (Part 3)

Figure 23.8 Potential molecular mediators of synapse identity

Figure 23.8 Potential molecular mediators of synapse identity (Part 1)

Figure 23.8 Potential molecular mediators of synapse identity (Part 2)

Figure 23.9 Target-derived trophic support regulates survival of related neurons

Figure Changes to synapses during early postnatal life in the mammalian PNS

Figure The elimination of multiple innervation at the neuromuscular junction

Box 23C(1) Why Do Neurons Have Dendrites?

Box 23C(2) Why Do Neurons Have Dendrites?

Figure Effect of the neurotrophin NGF on the outgrowth of neurites and survival of neurons

Figure Effect of NGF on the outgrowth of neurites and survival of neurons (Part 1)

Figure Effect of NGF on the outgrowth of neurites and survival of neurons (Part 2)

Box 23D The Discovery of BDNF and the Neurotrophin Family

Figure Neurotrophins have distinct effects on different target neurons

Figure Neurotrophins have distinct effects on different target neurons (Part 1)

Figure Neurotrophins have distinct effects on different target neurons (Part 2)

Figure Neurotrophins influence neurite growth by local action

Figure Neurotrophins influence neurite growth by local action (Part 1)

Figure Neurotrophins influence neurite growth by local action (Part 2)

Figure Neurotrophin receptors and their specificity for the neurotrophins

Figure Signaling through the neurotrophins and their receptors

Figure Signaling through the neurotrophins and their receptors (Part 1)

Figure Signaling through the neurotrophins and their receptors (Part 2)