Neuroscience, Page 2Dale Purves Created primarily for medical and premedical students, 'Neuroscience' emphasizes the structure of the nervous system, the correlation of structure and function, and the structure/function relationships particularly pertinent to the practice of medicine. |
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Page 332
... auditory " space . " That auditory space can be perceived is remarkable , given that the cochlea , unlike the retina , cannot repre- sent space directly . A final point is that auditory nerve activity patterns are not simply faithful ...
... auditory " space . " That auditory space can be perceived is remarkable , given that the cochlea , unlike the retina , cannot repre- sent space directly . A final point is that auditory nerve activity patterns are not simply faithful ...
Page 338
... auditory cortex are in red . The Al has a tonotopic organization , as shown in this blowup diagram of a seg- ment of A1 ( right ) . ( B ) Diagram of the brain in left lateral view , showing loca- tions of human auditory cortical areas ...
... auditory cortex are in red . The Al has a tonotopic organization , as shown in this blowup diagram of a seg- ment of A1 ( right ) . ( B ) Diagram of the brain in left lateral view , showing loca- tions of human auditory cortical areas ...
Page 342
... auditory system . Projections from the cochlea travel via the auditory nerve to the three main divisions of the cochlear nucleus . The tar- gets of the cochlear nucleus neurons include the superior olivary complex and nuclei of the ...
... auditory system . Projections from the cochlea travel via the auditory nerve to the three main divisions of the cochlear nucleus . The tar- gets of the cochlear nucleus neurons include the superior olivary complex and nuclei of the ...
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action potential activity afferents AMPA receptors amygdala areas auditory axons basal ganglia behavior binding brain brainstem Ca2+ cell bodies cellular cerebellar cerebellum cerebral cortex changes Chapter circuitry circuits complex cortical damage dendrites depolarization dorsal electrical excitatory eye movements Figure frontal function GABA ganglion cells gene glial glutamate hair cells hemisphere human hypothalamus increase inhibitory innervate inputs intracellular ion channels K+ channels kinase layer lesions lobe lower motor neurons mechanisms medial membrane potential molecular molecules monkey motor cortex nerve cells nervous system neural Neurosci neurotransmitter normal nucleus odorant olfactory optic organization pathways patients peripheral postsynaptic presynaptic terminal primary processes projections proteins Purkinje cells receptors reflex regions release response result reticular retina saccade segment signals sleep somatic sensory specific spinal cord stimulation structures superior colliculus synaptic vesicles target temporal thalamus tion tissue transduction transmitter upper motor neurons vestibular visceral motor visual field