SPPA 206: Hearing Science

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SPPA 6030, Study Guide for Exam 2

SPPA 6030: Study Guide for Exam 2

Notes: This study guide is intended to give you a general idea of some of the kinds of questions that might appear on the exam, and to help you organize your studying. It is not intended to cover all of the topics that might be appear on the exam. However, some of the exam questions may be taken almost verbatim from the study guide. In addition to the kinds of questions that are shown below, there may also be multiple choice questions, matching items, and diagrams that you would be asked to label. NOTE: The study guide is based on a guess about how much material we will cover prior to the exam. There may be material covered here which we do not get to and which, therefore, will not be on the exam. For example, I think it’s unlikely that we will get to the central auditory system, although this topic is covered on the study guide. If you are unsure, ask me.

1.  What are the three functional subsystems of the auditory system? What functions are performed by each subsystem?

2.  What does it mean to say that there is an impedance mismatch between the outside air and the inner ear? How large is this mismatch: (a) expressed as a ratio, and (b) expressed on a decibel scale? How does the middle ear overcome this mismatch?

3.  What does it mean to say that the auditory system is a spectrum analyzer? Give a general explanation of how the auditory system performs spectrum analysis.

4.  What is the acoustic reflex? What muscles participate in this reflex? What is thought to be the purpose of this reflex?

5.  Where is the Eustachian tube located? What are the functions of the Eustachian tube?

6.  What are the six surfaces of the tympanic cavity, and what structures are located on each surface?

7.  The tympanic membrane is composed of what three layers?

8.  What is a transducer? What transduction functions are performed by the auditory system?

9.  Explain what causes the "pop" that you hear when riding down (or up) an elevator in a tall building.

10.  The labyrinth contains what two sensory systems?

11.  The membranous labyrinth portion of the cochlea consists of what two membranes?

12.  Assuming an average length of 2.5 cm for the external auditory meatus (EAM), what is the lowest resonant frequency of this canal? Draw the frequency-response for the EAM showing the two lowest resonances.

13.  What is the maximum firing rate that a neuron can sustain for a short period of time? What is the maximum firing rate that a neuron can sustain for an extended period of time? What do these firing-rate limits have to do with absolute and relative refractory periods? Why are these facts important for understanding frequency analysis by the auditory system?

14.  How do the physical characteristics of the basilar membrane vary from the base of the cochlea to the apex? Why is this fact important for understanding frequency analysis by the auditory system?

15.  What anatomical structure lies immediately above the superior surface of the tympanic cavity?

16.  What portion of the malleus attaches to the tympanic membrane?

17.  What effects do the contraction of the tensor tympani and stapedius muscles have on the structures of the middle ear?

18.  How does the Eustachian tube of an infant or young child compare with that of an adult? Why are these anatomical differences important?

19.  The ______, a gap at the apex of the cochlea, allows the fluid in the vestibular canal to communicate with the fluid in the tympanic canal.

20.  This material is a fatty substance that coats the fibers of some but not all neurons. Fibers that contain this substance transmit neural signals more rapidly than uncoated fibers.

21.  Give an example that illustrates the difference between force and pressure. Why is this distinction important to the functioning of the auditory system?

22.  Explain the two schemes that might be used by the auditory system to code frequency.

23.  Draw graphs showing the amount of 8th-nerve electrical activity as a function of position along the basilar membrane for: (a) a high-frequency signal, (b) a mid-frequency signal, and (c) a low-frequency signal. What, if anything, does this graph have to do with Fourier analysis?

24.  Draw a graph showing how voltage varies over time in the generation of a neural spike potential. Label your graph and provide a scale for the voltage axis.

25.  What does it mean to say that the auditory pathway exhibits tonotopic organization?

26.  The peripheral auditory system consists of everything from the pinna up to and including the ______.

27.  The central auditory system consists of structures in the ______and the ______.

28.  What do neurons have in common with toilets?

29.  According to the Hallowell Davis model of hair-cell function, hair cells form part of an electrical circuit. Draw this circuit and briefly explain how it works.

30.  A hair cell channel consists of ______.

31.  What specific component of the hair cell channel is responsible for transduction?

32.  Most auditory nerve fibers are: (a) afferent, or (b) efferent.

33.  Most auditory nerve fibers synapse on: (a) IHCs, (b) OHCs, or (c) IHCs and OHCs about equally.

34.  The cochlea contains roughly this many channels ______.

35.  It is not uncommon for a disease process to affect both the sense of hearing and the sense of balance. Why might this be the case?

Terms for Exam 2 (Anatomy and Physiology)

Note: Items that are separated by slashes are alternate names for the same structure.

transducer

conductive mechanism

sensorineural mechanism

central auditory system

acoustic nerve/auditory nerve/8th cranial nerve

vestibular branch of the 8th nerve

cochlear branch of the 8th nerve

pinna

helix

antihelix

tragus

antitragus

concha

ear lobe

external auditory meatus/ear canal

sebaceous glands

cerumen

tympanic membrane/ear drum

tympanic sulcus

Shrapnell's membrane/pars flaccida

pars tensa

umbo

tympanic cavity/middle ear cavity

jugular vein

attic/epitympanic recess

tympanic cavity proper

oval window

annular ligament

round window

internal tympanic membrane

facial nerve/7th cranial nerve

promontory

pyramidal eminence

stapedius muscle

tensor tympani

Eustachian tube/auditory tube

malleus - manubrium, head, neck

incus - short process, body, long process

stapes - head, neck, posterior crus, anterior crus, footplate

impedance (resistance, mass reactance, capacitive reactance)

impedance mismatch

force

pressure

acoustic reflex

intensity control theory

labyrinth

bony labyrinth

membranous labyrinth

helicotrema

internal auditory meatus

vestibular mechanism

otolith system

semicircular canals

ampulla

utricle

saccule

cristae

maculae

angular acceleration/"head motion"

linear acceleration

perilymph

endolymph

cochlea

vestibule

basal, medial, and apical turns of the cochlea

modiolus

basilar membrane

Reissner's membrane

organ of Corti

spiral lamina/bony spiral lamina

scala vestibuli/vestibular canal

scala tympani/tympanic canal

scala media/cochlear duct/cochlear partition

stria vascularis

tectorial membrane

Dieter's cells

phalangeal process

limbus

inner hair cells

outer hair cells

cilia

cuticle/cuticular plate

tunnel of Corti

rods of Corti

neuron

dendrite

axon

cell body

afferent process

efferent process

myelin

spike potential

depolarization

absolute refractory period

relative refractory period

ganglion

nucleus

traveling wave

place theory/place principle

frequency theory/synchrony theory

volley principle

tonotopic organization