1. Figure 17-21 The Anatomy of the Ear
External Ear
Middle Ear
Internal Ear
Elastic cartilages
Auditory ossicles
Oval window
Semicircular canals
Petrous part of temporal bone
Auricle
Facial nerve (N VII)
Vestibulocochlear nerve (N VIII)
Bony labyrinth of internal ear
Cochlea
Tympanic cavity
Auditory tube
To nasopharynx
External acoustic meatus
Tympanic membrane
Round window
Vestibule
590 1

2. Figure 17-22a The Middle Ear.
Auditory Ossicles
Malleus
Incus
Stapes
Temporal bone (petrous part)
Stabilizing ligaments
Oval window
Muscles of the Middle Ear
Branch of facial nerve VII (cut)
Tensor tympani muscle
External acoustic meatus
Stapedius muscle
Tympanic cavity (middle ear)
Round window
Auditory tube
Tympanic membrane
592 a
The structures of the middle ear

3. © 2015 Pearson Education, Inc.
592
© 2015 Pearson Education, Inc.

4. Figure 17-22b The Middle Ear
Malleus attached to tympanic membrane
Tendon of tensor tympani muscle
Malleus
Incus
Base of stapes at oval window
Stapes
Stapedius muscle
Inner surface of tympanic membrane
592
The tympanic membrane and auditory ossicles 4

5. © 2015 Pearson Education, Inc.
593
© 2015 Pearson Education, Inc.

6. Figure 17-24a The Semicircular Ducts
Vestibular branch (N VIII)
Semicircular ducts
Anterior
Cochlea
Ampulla
Posterior
Lateral
Endolymphatic sac
Endolymphatic duct
Utricle
Saccule
Maculae
An anterior view of the right semicircular ducts, the utricle, and the saccule, showing the locations of sensory receptors
596 6

7. Figure 17-25ab The Saccule and Utricle.
Endolymphatic sac
Endolymphatic duct
Utricle
Saccule a
The location of the maculae
Otoliths
Gelatinous layer forming otolithic membrane
Hair cells
Nerve fibers
596 b
The structure of an individual macula

8. Figure 17-25c The Saccule and Utricle
Head in normal, upright position
Gravity
Head tilted posteriorly
Gravity
Otolith moves “downhill,” distorting hair cell processes
Receptor output increases
A diagrammatic view of macular function when the head is held horizontally and then tilted back
596 1 2 8

9. Figure 17-24a The Semicircular Ducts.
Vestibular branch (N VIII)
Semicircular ducts
Anterior
Cochlea
Ampulla
Posterior
Endolymphatic sac
Lateral
Endolymphatic duct
Utricle
Maculae
Saccule a
An anterior view of the right semicircular ducts, the utricle, and the saccule, showing the locations of sensory receptors.
594

10. Figure 17-24b The Semicircular Ducts
Ampulla filled with endolymph
Cupula
Hair cells
Crista
Supporting cells
Sensory nerve
A cross section through the ampulla of a semicircular duct
594 10

11. Figure 17-24c The Semicircular Ducts
Direction of duct rotation
Direction of relative endolymph movement
Direction of duct rotation
Semicircular duct
Ampulla
At rest
Endolymph movement along the length of the duct moves the cupula and stimulates the hair cells.
594 11

12. Figure 17-24d The Semicircular Ducts
Displacement in this direction stimulates hair cell
Displacement in this direction inhibits hair cell
Kinocilium
Stereocilia
Hair cell
Sensory nerve ending
Supporting cell
A representative hair cell (receptor) from the vestibular complex. Bending the sterocilia toward the kinocilium depolarizes the cell and stimulates the sensory neuron. Displacement in the opposite direction inhibits the sensory neuron.
594 12

13. Figure 17-26 Pathways for Equilibrium Sensations.
To superior colliculus and relay to cerebral cortex
Red nucleus
N III
Semicircular canals
Vestibular ganglion
N IV
Vestibular branch
Vestibular nucleus
N VI
To cerebellum
Vestibule
Cochlear branch
N XI
Vestibulocochlear nerve (VIII)
597
Vestibulospinal tracts

14. Vestibulocochlear nerve (VIII)
Figure 17-27a The Cochlea.
Round window
Stapes at oval window
Scala vestibuli
Cochlear duct
Scala tympani
Semicircular canals
KEY
Cochlear branch
Vestibular branch
From oval window to tip of spiral
Vestibulocochlear nerve (VIII)
From tip of spiral to round window a
The structure of the cochlea
598

15. 598 Diagrammatic and sectional views of the cochlear spiral
Figure 17-27b The Cochlea
Temporal bone (petrous part)
Vestibular membrane
Scala vestibuli (contains perilymph)
Tectorial membrane
Cochlear duct (contains endolymph)
Basilar membrane
From oval window
Spiral organ
Spiral ganglion
To round window
Scala tympani (contains perilymph)
Cochlear nerve
Vestibulocochlear nerve (N VIII)
598
Diagrammatic and sectional views of the cochlear spiral 15

16. Figure 17-28a The Spiral Organ.
Bony cochlear wall
Scala vestibuli
Spiral ganglion
Vestibular membrane
Cochlear duct
Tectorial membrane
Basilar membrane
Scala tympani
Spiral organ
Cochlear branch
of N VIII a
A three-dimensional section of the cochlea, showing the compartments, tectorial membrane, and spiral organ
599

17. Figure 17-28b The Spiral Organ
Tectorial membrane
Outer hair cell
Basilar membrane
Inner hair cell
Nerve fibers
Diagrammatic and sectional views of the receptor hair cell complex of the spiral organ
599 17

18. Figure 17-28b The Spiral Organ
Cochlear duct (scala media)
Vestibular membrane
Tectorial membrane
Scala tympani
Basilar membrane
Hair cells of spiral organ
Spiral ganglion cells of cochlear nerve
Spiral organ
LM  125
Diagrammatic and sectional views of the receptor hair cell complex of the spiral organ
599 18

19. © 2015 Pearson Education, Inc.
600
© 2015 Pearson Education, Inc.

20. Figure 17-31a Frequency Discrimination
Stapes at oval window
Cochlea
16,000 Hz
6000 Hz
1000 Hz
Round window
Basilar membrane
The flexibility of the basilar membrane varies along its length, so pressure waves of different frequencies affect different parts of the membrane.
602 20

21. Figure 17-31b Frequency Discrimination
Stapes moves inward
Basilar membrane distorts toward round window
Round window pushed outward
The effects of a vibration of the stapes at a frequency of 6000 Hz. When the stapes moves inward, as shown here, the basilar membrane distorts toward the round window, which bulges into the middle-ear cavity.
602 21

22. Figure 17-31c Frequency Discrimination
Stapes moves outward
Round window pulled inward
Basilar membrane distorts toward oval window
When the stapes moves outward, as shown here, the basilar membrane rebounds and distorts toward the oval window.
602 22

23. Figure 17-30 Sound and Hearing
External acoustic meatus
Malleus
Incus
Stapes
Oval window
Movement
of sound waves
Tympanic membrane
Round window
Sound waves arrive at tympanic membrane.
Movement of the tympanic membrane causes displacement of the auditory ossicles.
Movement of the stapes at the oval window establishes pressure waves in the perilymph of the scala vestibuli.
601 23

24. Figure 17-30 Sound and Hearing (Part 2 of 2).
Cochlear branch of cranial nerve VIII 6
Scala vestibuli
(contains perilymph)
Vestibular membrane
Cochlear duct (contains endolymph)
Basilar membrane 4
Scala tympani (contains perilymph) 5 4 5 6
The pressure waves distort the basilar membrane on their way to the round window of the scala tympani.
Vibration of the basilar membrane causes hair cells to vibrate against the tectorial
membrane.
Information about the region and the intensity of stimulation is relayed to the CNS over the cochlear branch of cranial nerve VIII.
601

27. Figure 17-32 Pathways for Auditory Sensations
Stimulation of hair cells at a specific location along the basilar membrane activates sensory neurons.
KEY
Primary pathway
Secondary pathway
Motor output
Cochlea
Low-frequency sounds
High-frequency sounds
Vestibular branch
Sensory neurons carry the sound information in the cochlear branch of the vestibulocochlear nerve (VIII) to the cochlear nucleus on that side.
Vestibulocochlear nerve (VIII)
603 27

28. Figure 17-32 Pathways for Auditory Sensations
Projection fibers then deliver the information to specific locations within the auditory cortex of the temporal lobe.
High- frequency sounds
Low-frequency sounds
Thalamus
Ascending acoustic information goes to the medial geniculate nucleus.
The inferior colliculi direct a variety of unconscious motor responses to sounds.
To cerebellum
To reticular formation and motor nuclei of cranial nerves
Information ascends from each cochlear nucleus to the inferior colliculi of the midbrain.
KEY
603
Primary pathway
Motor output to spinal cord through the tectospinal tracts
Secondary pathway
Motor output 28

29. 603

30. Table 17-1 Intensity of Representative Sounds.
600

31. http://www. healthtree