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Published byAlexia Dorthy Morris Modified over 9 years ago
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Figure 18.1 Motor components of the human basal ganglia
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Figure 18.1 Motor components of the human basal ganglia (Part 1)
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Figure 18.1 Motor components of the human basal ganglia (Part 2)
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Figure 18.2 Anatomical organization of the inputs to the basal ganglia
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Figure 18.3 Neurons and circuits of the basal ganglia
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Figure 18.3 Neurons and circuits of the basal ganglia (Part 1)
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Figure 18.3 Neurons and circuits of the basal ganglia (Part 2)
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Figure 18.4 Regions of the cerebral cortex that project to the corpus striatum
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Figure 18.5 Functional organization of intrinsic circuitry and outputs of basal ganglia
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Figure 18.5 Functional organization of intrinsic circuitry and outputs of basal ganglia (Part 1)
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Figure 18.5 Functional organization of intrinsic circuitry and outputs of the basal ganglia (Part 2)
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Figure 18.6 A chain of nerve cells arranged in a disinhibitory circuit
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Figure 18.6 A chain of nerve cells arranged in a disinhibitory circuit (Part 1)
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Figure 18.6 A chain of nerve cells arranged in a disinhibitory circuit (Part 2)
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Figure 18.7 Basal ganglia disinhibition and the generation of saccadic eye movements
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Figure 18.7 Basal ganglia disinhibition and the generation of saccadic eye movements (Part 1)
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Figure 18.7 Basal ganglia disinhibition and the generation of saccadic eye movements (Part 2)
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Figure 18.8 Disinhibition in the direct and indirect pathways through the basal ganglia
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Figure 18.8 Disinhibition in the direct and indirect pathways through the basal ganglia (Part 1)
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Figure 18.8 Disinhibition in the direct and indirect pathways through the basal ganglia (Part 2)
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Figure 18.9 Center-surround functional organization of the direct and indirect pathways
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Figure 18.10 Neurological diseases provide insights into function of the basal ganglia
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Figure 18.11 Hypo- and hyperkinetic disorders alter the balance of inhibitory signals in the direct and indirect pathways
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Figure 18.11 Hypo- and hyperkinetic disorders alter the balance of inhibitory signals in the direct and indirect pathways (Part 1)
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Figure 18.11 Hypo- and hyperkinetic disorders alter the balance of inhibitory signals in the direct and indirect pathways (Part 2)
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Box 18C Deep Brain Stimulation
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Box 18C Deep Brain Stimulation (Part 1)
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Box 18C Deep Brain Stimulation (Part 2)
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Figure 18.12 Inactivation of tonically active cells of substantia nigra pars reticulata causes saccades
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Box 18D Basal Ganglia Loops and Non-Motor Brain Functions
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Box 18D Basal Ganglia Loops and Non-Motor Brain Functions (Part 1)
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Box 18D Basal Ganglia Loops and Non-Motor Brain Functions (Part 2)
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