Instructions for Side by Side Printing
- Print the notecards
- Fold each page in half along the solid vertical line
- Cut out the notecards by cutting along each horizontal dotted line
- Optional: Glue, tape or staple the ends of each notecard together
Exercise 25 Special Senses: Hearing and Equilibrium
front 1 Auricle (pinna) External acoustic meatus Tympanic membrane | back 1 structures composing the external ear |
front 2 Semicircular canals Cochlea Vestibule | back 2 structures composing the internal ear |
front 3 Incus (anvil) Malleus (hammer) Stapes (stirrup) | back 3 collectively called the ossicles |
front 4 Pharyngotympanic (auditory) tube | back 4 - involved in equalizing the pressure in the middle ear with atmospheric pressure - passage between the throat and the tympanic cavity |
front 5 Tympanic membrane | back 5 vibrates at the same frequency as sound waves hitting it; transmits the vibrations to the ossicles |
front 6 Semicircular canals Vestibule | back 6 contain receptors for the sense of balance |
front 7 Oval window | back 7 transmits the vibratory motion of the stirrup to the fluid in the scala vestibuli of the internal ear |
front 8 Round window | back 8 acts as a pressure relief valve for the increased fluid pressure in the scala tympani; bulges into the tympanic cavity |
front 9 Endolymph | back 9 fluid contained within the membranous labyrinth |
front 10 Perilymph | back 10 fluid contained within the bony labyrinth and bathing the membranous labyrinth |
front 11  | back 11 no data |
front 12 Saccule, Utricle | back 12 - sacs found within the vestibule - sites of the maculae |
front 13 Cochlear duct | back 13 contains the spiral organ |
front 14 Semicircular ducts | back 14 positioned in all spatial planes |
front 15 Basilar membrane | back 15 hair cells of the spiral organ rest on this membrane |
front 16 Tectorial membrane | back 16 gelatinous membrane overlying the hair cells of the spiral organ |
front 17 Ampulla | back 17 contains the crista ampullaris |
front 18 Otoliths, Saccule, Utricle, Vestibular nerve | back 18 function in static equilibrium |
front 19 Ampulla, Ampullary cupula, Semicircular ducts, Vestibular nerve | back 19 function in dynamic equilibrium |
front 20 Cochlear nerve | back 20 carries auditory information to the brain |
front 21 Ampullary cupula | back 21 gelatinous cap overlying hair cells of the crista ampullaris |
front 22 Otoliths | back 22 grains of calcium carbonate in the maculae |
front 23 Trace the pathway through which vibrations are transmitted to stimulate the hair cells in the spiral organ. | back 23 Tympanic membrane > malleus > incus > stapes > oval window > perilymph > cochlear duct > endolymph > basilar membrane with hair cells |
front 24 Describe how sounds of different frequency (pitch) are differentiated in the cochlea. | back 24 The frequency determined by the length and tension of the basilar membrane fibers. High pitch sounds = oval window. low pitch = basilar membrane near apex of cochlea. |
front 25 Explain the role of the endolymph of the semicircular canals in activating the receptors during angular motion. | back 25 When angular motion occurs in one direction, the endolymph in a semicircular canal lags behind, pushing the cupula in a direction opposite to that of the angular motion. Depending on the ear, this depolarizes or hyperpolarizes the hair cells, resulting in enhanced or reduced impulses to the brain. |
front 26 Explain the role of the otoliths in perception of static equilibrium (head position). | back 26 When the head moves, otoliths move in response to variation in gravitational pull. As the deflect different hair cells, they hyper polarize or depolarize hair cells and modify the rate of impulse transmission along vestibular nerve. |
front 27 Conduction deafness | back 27 - can result from the fusion of the ossicles - can result from impacted cerumen or a perforated eardrum |
front 28 Sensorineural deafness | back 28 - can result from a lesion on the cochlear nerve - sound heard in one ear but not in the other during bone and air conduction - can result from a blood clot in the primary auditory cortex |
front 29 Conduction deafness and Sensorineural deafness | back 29 - can result from otitis media |
front 30 The Rinne test evaluates an individual's ability to hear sounds conducted by air or bone. Which is more indicative of normal hearing? | back 30 Air-conducted sound |
front 31 Nsytagmus | back 31 involuntary rolling of the eyes in any direction or the trailing of the eyes slowly in one direction, followed by rapid eye movement in the opposite direction |
front 32 Vertigo | back 32 sensation of dizziness and rotational movement when such movement is not occurring or has ceased |
front 33 The Barany test investigated the effect that rotatory acceleration had on the semicircular canals. Explain why the subject still had the sensation of rotation immediately after being stopped. | back 33 subject has vertigo |
front 34 What is the usual reason for conduction the Romberg test? | back 34 to determine if impulses are being transmitted up the spinal cord to the brain properly |
front 35 Wast he degree of sway greater with the eyes open or closed? why? | back 35 closed; you lose visual reference points |
front 36 Normal balance, or equilibrium, depends on input from a number of sensory receptors. Name them. | back 36 vestibular receptors, visual receptors, somatic receptors |
front 37 What effect does alcohol consumption have on balance and equilibrium? Explain. | back 37 alcohol depresses the neurons and enhances the inhibition of coordination and causes a loss of equilibrium reflexes |