Chapter 15- Special Senses Flashcards

Question 1

Q

What are special senses?

Answer

A

Any of the senses with special sensory receptors. These receptors are extremely specific and will only respond to one type of stimulus. Only found in the head and sit very close to the surface (considered exteroceptors).

Question 2

Q

Special senses (5)

Answer

A

Vision
Olfaction (smell)
Gustation (taste)
Hearing
Equilibrium

Question 3

Q

Why is touch not considered a special sense?

Answer

A

Touch doesn’t count because receptors are scattered throughout the body and the receptors are mechanoreceptors

Question 4

Q

What is our most dominant sense?

Answer

A

Vision. 50% of our sensory receptors are photoreceptors and more than 50% of the cerebral cortex is responsible for integrating visual information. The eyes are anatomically and physiologically complex and very well protected

Question 5

Q

Function of eyebrows

Answer

A

Provide shade, prevent sweat from running into eyes. Sweat has a high salt concentration and can be irritating to the eyes. Eyebrows are usually darker in color, which provides the shade.

Question 6

Q

Conjunctiva

Answer

A

Transparent mucous membrane- there are 2 types. Produces lubricating mucus.

Question 7

Q

Palpebral conjunctiva

Answer

A

Portion of the conjunctiva that covers the inner eyelids

Question 8

Q

Bulbar conjunctiva

Answer

A

Portion that covers the anterior surface of the eye (except cornea)

Question 9

Q

Conjunctivitis

Answer

A

“Pink eye”- the color is caused by irritation as the conjunctival membrane secretes more mucus. This infection can be viral or bacterial.

Question 10

Q

Palpebrae function

Answer

A

Eyelids- open and close the eyes

Question 11

Q

Which muscles allow the eye to open and close (2)?

Answer

A

Orbicularis oculi- encircles the eye
Levator palpebrae superioris
Both of these muscles are skeletal

Question 12

Q

Lacrimal caruncle

Answer

A

Located on medial portion of the eyelid- this is the pink tissue you can see in the medial corner of the eye. Crusty secretions you sometimes see in the corner of your eyes is the secretion of the lacrimal caruncle. The sebaceous and sweat glands here produce an oily secretion.

Question 13

Q

What is the function of eyelashes?

Answer

A

Eyelashes project from the upper and lower lid to protect the eye from debris, which can be irritating or damaging.

Question 14

Q

Lacrimal apparatus function

Answer

A

Production and drainage of tears

Question 15

Q

Parts of the lacrimal apparatus (3)

Answer

A

Lacrimal glands
Lacrimal canaliculi
Nasolacrimal duct

Question 16

Q

Lacrimal glands

Answer

A

Produces and releases dilute saline solution (tears)

Question 17

Q

Lacrimal canaliculi

Answer

A

Drains tears from the eye surface at the medial portion of the eye.

Question 18

Q

Nasolacrimal duct

Answer

A

Drains tears from lacrimal canaliculi into nasal cavity. We produce tears constantly, but not enough to constantly produce a runny nose

Question 19

Q

What is the function of tears?

Answer

A

Tears contain lysozyme, an enzyme that kills bacteria. They also lubricate the eye surface and wash away foreign bodies in the eye

Question 20

Q

Function of extrinsic eye muscles

Answer

A

Allows movement of the eye in the orbit- lets you follow the movement of objects without turning your head.

Question 21

Q

Where do extrinsic eye muscles attach?

Answer

A

To the sclera of the eye

Question 22

Q

Extrinsic eye muscles (6)

Answer

A

Superior rectus
Inferior rectus
Lateral rectus
Medial rectus
Superior oblique
Inferior oblique

Question 23

Q

Rectus muscles function

Answer

A

Rectus muscles (4) pull the eye in the direction indicated by the name of the muscle.

Question 24

Q

Oblique muscles function

Answer

A

Oblique muscles (2) either elevate or depress the eye and turn it laterally

Question 25

Q

Why do we need oblique muscles?

Answer

A

Lateral pull of oblique muscles resists medial pull of rectus muscles

Question 26

Q

Layers of the eye (3)

Answer

A

Fibrous layer- superficial
Vascular layer
Retina- deep

Question 27

Q

Regions of the fibrous layer of the eye (2)

Answer

A

Sclera

2. Cornea

Question 28

Q

Sclera

Answer

A

The whites of the eyes. Functions- gives the eyeball shape, provides sturdy anchors for extrinsic muscles.

Question 29

Q

Cornea

Answer

A

Transparent layer at the most anterior region of the eye. Supplied with many pain receptors- can be very painful if anything gets in the eye, causes tear production and reflexive blinking. High regenerative and repair capacity, but doesn’t have any blood vessels. If there were blood vessels, we would be able to see them and it would obscure your vision.

Question 30

Q

Cornea functions

Answer

A

Functions- allows light to enter the eye, bends light as it passes.

Question 31

Q

Why don’t cornea transplants have a risk of rejection?

Answer

A

The cornea doesn’t have blood supply, so there is a lack of immune system supply.

Question 32

Q

Regions of the vascular layer of the eye (3)

Answer

A

This is the middle layer.

Choroid
Ciliary body
Iris

Question 33

Q

Choroid

Answer

A

Well vascularized layer, dark in color (to absorb light). Blood vessels here nourish surrounding layers of the eye

Question 34

Q

Ciliary body

Answer

A

The region of the eye that encircles the lens. Includes the ciliary muscle, ciliary processes, and suspensory ligaments

Question 35

Q

Ciliary muscle

Answer

A

Smooth muscle bundles that control lens shape

Question 36

Q

Ciliary processes

Answer

A

Secrete aqueous humor

Question 37

Q

Suspensory ligaments

Answer

A

Extend from ciliary processes to lens. Functions- holds lens in place, transmits tension from ciliary muscle to lens

Question 38

Q

Iris

Answer

A

The colored portion of the eye

Question 39

Q

What does the color of the iris depend on?

Answer

A

Color depends on amount of brown pigment in the eyes. People with blue eyes do have melanin, but in much smaller amounts. If you have no melanin at all, you would have red eyes (seen with albinism).

Question 40

Q

Pupil

Answer

A

Central opening of iris that lets light enter the eye

Question 41

Q

What structures allow for constriction or dilation of the pupil?

Answer

A

Smooth muscle layers of iris allow for constriction or dilation of the pupil. Sphincter pupillae and dilator pupillae

Question 42

Q

Sphincter pupillae

Answer

A

When contracted, the muscle becomes thicker and the pupil constricts

Question 43

Q

Dilator pupillae

Answer

A

When contracted, the pupil dilates

Question 44

Q

If an individual’s pupils are different sizes, what can that indicate?

Answer

A

Pupils that are different sizes are indicators of head trauma, “blown pupils”.

Question 45

Q

What factors influence pupil size?

Answer

A

With pupil size, we are concerned with levels of light, autonomic nervous system influence, and strong emotions- if you look at someone you love, your pupils will get larger (more light to see them better)

Question 46

Q

Retina

Answer

A

This layer contains all the photoreceptors of the eye. Two layers: the pigmented layer and the neural layer.

Question 47

Q

Pigmented layer of the retina

Answer

A

Lies against the choroid, most superficial. Pigment here absorbs light, phagocytes here help with photoreceptor renewal

Question 48

Q

Neural layer of the retina

Answer

A

Innermost layer of the retina, contains photoreceptor cells (rods and cones). Also contains bipolar cells and ganglion cells. Both are used to generate action potentials in response to light stimuli.

Question 49

Q

Rods

Answer

A

Used for dim light and peripheral vision. Only one visual pigment (photopigment) in rods- no color vision, and rod vision tends to be blurry. Most numerous, found mostly in retinal periphery. Several rods all synapse on a single ganglion.

Question 50

Q

Cones

Answer

A

Used for bright light and high resolution color vision- have low sensitivity to light. Found mostly in the fovea centralis and macula lutea. A single cone has 1 of 3 (red, green, or blue) visual pigments, and each cone synapses on its own ganglia.

Question 51

Q

Optic disc

Answer

A

Associated with the retina. This is the point at which the optic nerve exits the back of the eye. No photoreceptors are found here, causing a “blind spot”. The brain fills in the missing information, so we don’t notice the blind spot

Question 52

Q

Macula lutea

Answer

A

This is where retinal structures are displaced to the side. Result- light passes directly to photoreceptors- there is increased visual acuity here.

Question 53

Q

Fovea centralis

Answer

A

Associated with the retina- found at the center of the macula lutea. Contains only cones- provides extremely detailed color vision, but is only 1/1000th of the total visual field. This is why if you want to see something really clearly, you have to look directly at it

Question 54

Q

Anterior segment

Answer

A

The interior chamber located in front of the lens, contains aqueous humor

Question 55

Q

Aqueous humor

Answer

A

Watery fluid found in the anterior segment. It is continuously drained and produced. Functions- supplies nutrients and oxygen to structures in the anterior chamber and some retinal cells, removes waste.

Question 56

Q

Glaucoma

Answer

A

People with glaucoma either have too much aqueous humor or aren’t draining it enough. Eventually the fluid will push on the optic nerve and increase the pressure in the eye.

Question 57

Q

Posterior segment

Answer

A

The interior chamber located behind the lens, contains vitreous humor

Question 58

Q

Vitreous humor

Answer

A

Jelly-like fluid found in the posterior segment. Functions- transmits light, stabilizes the lens, and holds the retina place, contributes to intraocular pressure. Vitreous humor lasts a lifetime.

Question 59

Q

Lens

Answer

A

Convex, transparent, flexible structure in the eye. Function- used to bend light as it enters the eye

Question 60

Q

Lens epithelium

Answer

A

Covers the anterior portion of the lens. Functions- coordinates metabolic activity of the lens, provides more cells for lens fibers.

Question 61

Q

Lens fibers

Answer

A

Makes up the bulk of the lens. Fibers are laid down over a lifetime, old fibers are not broken down. Disadvantage- the lens becomes thicker and more dense with time- loses ability to focus light. Older individuals have to hold objects farther away to see them

Question 62

Q

Cataracts

Answer

A

Distortion of vision due to thickening of the lens. Fibers clump together unevenly and they turn white in color, changing how light can pass through the lens- like looking through fog. Can only be fixed by replacing the lens

Question 63

Q

Human eyes only respond to

Answer

A

Electromagnetic radiation in the visible light spectrum (400-700 nm).

Question 64

Q

The color of a particular object is caused by

Answer

A

Which wavelengths are absorbed and which are reflected. Ex- green grass reflects green wavelength and absorbs others

Answer 65

A

The object reflects all wavelengths of light

Answer 66

A

The object absorbs all wavelengths of light

Answer 67

A

Through a given medium

Answer 68

A

Occurs when light travels at an oblique angle from one medium into a medium with a different density (ex- a straw in a glass of water).

Answer 69

A

The lens refracts light that enters the eye. Light rays bend so they converge at a single point- the focal point. However, the real image is upside down and reversed

Answer 70

A

Light is bent 3 times as it enters the eye:
1. Cornea
2. Anterior surface of lens
3. Posterior surface of lens
The cornea is mostly responsible for bending light, but it can’t change shape. The lens is used to fine tune refraction- forms a clear image

Answer 71

A

Ciliary muscles and suspensory ligaments around the lens

Answer 72

A

Increased tension in suspensory ligaments. Effect- suspensory ligaments are pulled tight

Answer 73

A

Decreased tension in suspensory ligaments. Effect- suspensory ligaments go slack

Answer 74

A

A flat lens decreases refractory power because the light passes through the lens faster

Answer 75

A

The point at which the lens no longer needs to change shape to focus light. In the normal eye, this is 20 feet. More parallel rays won’t need to be refracted as much and the lens doesn’t need to work as hard to bend light

Answer 76

A

When looking at a distant object- light rays entering the eye are nearly parallel. Cornea and lens easily focus light on retina

Answer 77

A

Ciliary muscles are relaxed- the tension of the suspensory ligaments flattens the lens

Answer 78

A

The closest point to face that still allows clear vision. In the normal eye, this is 4 inches. Anything closer than that would be blurry.

Answer 79

A

The closer an object is, the more divergent the light rays. Result- lens must work harder to refract and focus light

Answer 80

A

Accommodation of the lens
Constriction of pupils
Convergence of the eyes

Answer 81

A

Contraction of ciliary muscles. Effects- suspensory ligaments go slack- the lens bulges

Answer 82

A

It prevents divergent rays from entering the eye- would cause blurred vision

Answer 83

A

Keeps object focused on foveae. The closer the object, the more the eyes must converge

Answer 84

A

This is the “normal” eyeball shape- people whose eyes have this shape have 20/20 vision because the cornea and lens can focus light without help. The focal point is easily and efficiently focused on the retina

Answer 85

A

Elongated eyeball shape (past the focal point of the retina). Effect- objects are focused in front of the retina. More pronounced in distant objects. This results in nearsightedness- difficulty seeing far way.

Answer 86

A

Concave shaped corrective lenses

Answer 87

A

Shortened eyeball shape. Effect- objects are focused behind the retina. More pronounced in close objects. This results in farsightedness- difficulty seeing close objects

Answer 88

A

Convex shaped corrective lenses

Answer 89

A

The outer segment of the rod/cone is embedded in pigmented layer of retina. It contains photopigments (visual pigments) folded into discs. The inner segment is embedded in the neural layer of the retina

Answer 90

A

Part of the photoreceptor that responds to light- no other part will respond (looks like stacked coins)

Answer 91

A

Provides more photopigments to respond to light (for a higher sensitivity to light).

Answer 92

A

Bipolar cells

Answer 93

A

Process of converting light energy into a graded receptor potential that begins when a photoreceptor catches light

Answer 94

A

Normal rules for neurons don’t technically apply here- photoreceptors are very highly specialized neurons. Photoreceptors never create action potentials.

Answer 95

A

Photoreceptor cells
Bipolar cells
3, Ganglion cells

Answer 96

A

Create graded potential in response to incoming light stimuli

Answer 97

A

Create either IPSP or EPSP- has an effect on the ganglion cell. Bipolar cells and ganglion cells do not respond to light

Answer 98

A

Generate action potential that is propagated along the optic nerve toward the visual cortex. Bipolar cells and ganglion cells will not react to light

Answer 99

A

In the dark, photoreceptor ion channels are open. Result- receptor is depolarized to -40 mV. Allows positively charged ions to enter the photoreceptor and depolarizes it (in the absence of light- different from what we have seen)

Answer 100

A

In the light, photoreceptor ion channels close
Result- receptor is hyperpolarized to -70 mV
This process uses a G protein signaling system

Answer 101

A

Ca +2 channels open in the terminal of the photoreceptor- neurotransmitter released between the photoreceptor and bipolar cells. Next, the neurotransmitter causes IPSP at bipolar cells.

Answer 102

A

Hyperpolarization of bipolar cell prevents neurotransmitter release between bipolar cell and ganglion cell- no action potential generated. No AP generated because no neurotransmitter was released

Answer 103

A

Ca +2 ion channels close, neurotransmitter not released. Bipolar cell depolarizes in absence of IPSP, cell depolarizes (generates EPSP). Ca +2 channels open, neurotransmitter released between bipolar cell and ganglion cell

Answer 104

A

Action potential generated on the ganglion cell

Answer 105

A

Occurs when moving from dark to light conditions- the retina is the part of the eye that must adapt. Adaptation to bright light takes about 60 seconds, highest visual acuity and color vision is reached in about 5 minutes

Answer 106

A

In the dark, rod vision dominates, retinal sensitivity is high

Answer 107

A

Photoreceptors bombarded with stimuli- “white light” occurs. Rods “turned off” and cones “turned on”- retinal sensitivity decreases. Rods stop responding when light increases

Answer 108

A

Occurs when we move from light to dark conditions. Adaptation to dark takes up to 30 minutes

Answer 109

A

In the light, cone vision dominates, retinal sensitivity is low

Answer 110

A

Sudden lack of light causes a temporary loss of vision. Cones “turn off”, rods “turn on”- retinal sensitivity increases

Answer 111

A

The optic nerve exits the back of the eye. Medial fibers from each optic nerve cross over at the optic chiasm, and the optic tracts continue to the visual cortex

Answer 112

A

Carries fibers from the lateral portion of the eye on the same side
Carries fibers from the medial portion of the eye of the opposite side
Contains all information from the same half of the visual field

Answer 113

A

The lens flips/reverses the image, so the medial portion of the eye receives input from the temporal part of the visual field and the lateral portion of the eye receives input from the medial part of the visual field

Answer 114

A

This is an area in the thalamus where most fibers in the optic tract synapse with neurons. These fibers then project to the primary visual cortex

Answer 115

A

Superior colliculi- visual reflex center that controls extrinsic eye muscles
Pretectal nuclei- mediates pupillary response to light
Suprachiasmatic nucleus- sets biorhythms

Answer 116

A

The complete visual fields of left and right eye overlap. The visual cortex combines two images to create depth perception. Importance- depth perception allows us to locate objects in space

Answer 117

A

If a person loses an eye or loses vision in one eye.

Answer 118

A

Stimuli dissolved in solution

Answer 119

A

Serves as a warning system for our surroundings- can cause us to move away from bad smells

Answer 120

A

The olfactory epithelium in the roof of the nasal cavity

Answer 121

A

Olfactory sensory neurons
Supporting cells
Olfactory stem cells

Answer 122

A

Hair like projections found in epithelium, part of the structure of olfactory sensory neurons.
Function- increase receptive surface area of neuron. Mucus surrounding cilia dissolves airborne odorants

Answer 123

A

Contain olfactory cilia. Axons of multiple sensory neurons form small fascicles- filaments of the olfactory nerve. They travel through the cribriform foramen of the cribriform plate and synapse with olfactory mitral cells in olfactory bulb

Answer 124

A

The human nose can identify 10,000-1 trillion odorants. A single smell is due to combination of hundreds of different odorants

Answer 125

A

Olfactory epithelia has about 350 different odorant receptors. Each receptor responds to 1 or more odorants, and each odorant can bind 1 or more receptors

Answer 126

A

Olfactory sensory neurons have a superficial location, so they are prone to destruction. The life span of olfactory sensory neurons is 30-60 days, but olfactory stem cells replace damaged/destroyed neurons

Answer 127

A

Activation of sensory neurons

2. Transduction of smell

Answer 128

A

The odorant in a gaseous state dissolves in epithelium. Odorant binds receptor proteins in olfactory cilium membrane

Answer 129

A

Transduction involves G protein. Na+ influx depolarizes olfactory sensory neuron- creates receptor potential. A Ca 2+ influx causes adaptation- decreased response to sustained odorant stimulus

Answer 130

A

Site of synapse of olfactory sensory neurons with mitral cells

Answer 131

A

In the olfactory bulb, olfactory sensory neurons synapse with mitral cells, and impulses flow from the olfactory bulb via the olfactory tract. From the olfactory tract, information can be sent to the olfactory cortex or to the limbic system.

Answer 132

A

Smell is consciously interpreted and identified

Answer 133

A

Smell elicits an emotional response. This can result in activation of the sympathetic or parasympathetic system or in activation of protective reflexes- coughing, sneezing

Answer 134

A

Most taste buds are located on the papillae of the tongue, but some are located on the soft palate of the mouth, inside of the cheeks, and the pharynx.

Answer 135

A

Where taste buds are located, papillae are small peg like projections you can see on the tongue.

Answer 136

A

Fungiform papillae
Vallate papillae
Foliate papillae

Answer 137

A

Found all over tongue, contain 1-5 taste buds each. Named for their shape- shaped like a mushroom

Answer 138

A

Found at back of tongue (form an inverted V), have many taste buds each

Answer 139

A

Found on side of tongue, taste bud number varies with age. Young children have a lot of these taste buds, but we lose them as we get older

Answer 140

A

Gustatory epithelial cells

2. Basal epithelial cells

Answer 141

A

Receptor cells for taste- sensory dendrites wrap around gustatory cells and form the first part of the pathway to the brain. Contain gustatory hairs.

Answer 142

A

Microvilli projecting from tips of gustatory epithelial cells. Function- receptor membrane of gustatory epithelial cells. Hairs respond to taste stimuli- this is the taste sensitive portion

Answer 143

A

Stem cells- replace lost/damaged gustatory epithelial cells. Without these cells, we would lose our sense of taste within days.

Answer 144

A

Taste buds are replaced every 7-10 days. We lose taste buds from eating, and hot or spicy foods can burn or destroy the taste buds

Answer 145

A

Sweet
Sour
Salty
Bitter
Umami

Answer 146

A

Produced by most sugars, alcohols, some amino acids, lead salts

Answer 147

A

Produced by acids- anything with a high concentration of hydrogen ions, like lemons

Answer 148

A

Produced by metal ions (inorganic salts)

Answer 149

A

Produced mostly by alkaloids, some nonalkaloids. Caffeine is a consumable alkaloid

Answer 150

A

Produced by amino acids glutamate and aspartate- causes the beef taste of steak and the tang of ageing cheese

Answer 151

A

The conscious perception of taste. Most substances produce a combination of the taste modalities, but a single taste cell responds to only one modality

Answer 152

A

Long chain fatty acids. These are found in lipids- might explain why people like eating fatty foods

Answer 153

A

Activation of taste receptors

2. Transduction of taste- different mechanisms affect how we taste

Answer 154

A

All areas of the tongue can detect all taste modalities. It isn’t true that different parts of the tongue are responsible for different tastes

Answer 155

A

Chemical tastant must dissolve in saliva and diffuse into taste pore associated with the taste bud. Tastant binds gustatory epithelial cell- graded potential occurs and will depolarize gustatory epithelial cell- releases neurotransmitter. Neurotransmitter release to sensory dendrite elicits action potential

Answer 156

A

Na+ influx through Na+ channels directly depolarizes gustatory epithelial cell

Answer 157

A

H+ acts intracellularly to open ion channels

Answer 158

A

G protein gustducin activation leads to opening of cation channels to depolarize the membrane

Answer 159

A

Facial nerve

Answer 160

A

Glossopharyngeal nerve

Answer 161

A

Information travels from the facial or glossopharyngeal nerve. Most fibers synapse at the solitary nucleus in the medulla, and travel to the primary gustatory cortex, others travel to limbic system and hypothalamus, others travel to the limbic system and hypothalamus

Answer 162

A

Gives an appreciation/emotional response to food you like or dislike

Answer 163

A

Taste likes and dislikes have homeostatic value. Cravings usually mean that we are short on a macronutrient, ion, etc. (craving salt supplies the body with minerals, craving sweets supplies the body with carbohydrates). Some tastes indicate spoiled food (extreme sour) or poison (extreme bitter). Function- protects us from consuming something that can harm us

Answer 164

A

External ear
Middle ear
Inner ear

Answer 165

A

Pinna
External acoustic meatus
Tympanic membrane

Answer 166

A

Outermost cartilaginous (elastic cartilage and skin) part of the ear. Function- funnels sound into inner part of the ear

Answer 167

A

Tube extending from auricle to tympanum. Has sebaceous glands, some hairs, and ceruminous glands

Answer 168

A

Eardrum- translucent membrane that divides outer ear from middle ear. Function- vibrates in response to sound waves- transmits vibrations to the bones in the middle ear

Answer 169

A

The middle ear is an air filled cavity. Contains:

Auditory ossicles and associated muscles
Oval window and round window
Pharyngotympanic tube

Answer 170

A

Malleus, incus, and stapes. 3 smallest bones in the body. The malleus is most lateral and connected directly to the tympanic membrane. The incus is in the middle and the stapes is the most medial and connects to the oval window in the inner ear.

Answer 171

A

Ossicles vibrate in response to incoming sound waves- transmit sound to inner ear. The ossicles are all joined by small ligaments- they can move in relation to each other. When the malleus moves, the incus and the stapes will move as well. When the stapes vibrates, it sends vibrations to the inner ear.

Answer 172

A

Tensor tympani and stapedius. The tensor tympani connects to the malleus. The stapedius connects to the stapes and is the smallest muscle in the human body

Answer 173

A

The tensor tympani and stapedius contract in response to extreme sound vibrations. The muscles contracting in response to loud sounds hold the bones in place so extreme vibration will be prevented and damage is less likely to occur.

Answer 174

A

When we listen to very loud sounds, the tympanic membrane will vibrate very hard, which will also vibrate the ossicles really hard. This extreme vibration could damage the ossicles, which could prevent hearing from occurring at all

Answer 175

A

Small openings in middle ear, stapes attaches to oval window

Answer 176

A

Tube that runs from the middle ear to the nasopharynx. Function- opening of tube balances air pressure in the middle ear cavity

Answer 177

A

“Popping” ears on an airplane is the pharyngotympanic tube opening to balance air pressure in the inner ear. The tympanic membrane will not vibrate if pressure is not equal on both sides of the ear. This means that the ossicles also will not vibrate and hearing won’t occur.

Answer 178

A

Otitis media (ear infection) is an infection that starts in the pharyngotympanic tube. The tube is usually collapsed and is a warm area, so it’s a bacteria breeding ground. Can cause inflammation once it gets to the middle ear cavity.

Answer 179

A

Bony labyrinth

2. Membranous labyrinth

Answer 180

A

A system of channels that weave through the temporal bone- the bony labyrinth is the cavity inside the bone, not the bone itself. Channels are filled with perilymph- fluid similar to CSF. Perilymph surrounds the membranous labyrinth

Answer 181

A

Membranous sacs and ducts found in the bony labyrinth (run through the bony labyrinth). Filled with endolymph- fluid similar to ICF

Answer 182

A

The spiral bony chamber of the inner ear involved with sound perception. The cochlear duct runs through center and is membranous (membranous labyrinth of the cochlea). Contains the spiral organ- actual receptor organ for hearing . The cochlea ends blindly at the helicotrema- a dead end

Answer 183

A

Scala vestibuli
Scala tympani
Scala media

Answer 184

A

Part of bony labyrinth that begins at the oval window of the middle ear. Filled with perilymph.

Answer 185

A

Part of bony labyrinth that ends at round window of the middle ear. Vestibuli and tympani are continuous- meet at the helicotrema. Both are filled with perilymph as they are part of the bony labyrinth

Answer 186

A

Cochlear duct- part of membranous labyrinth. The spiral organ is found in the scala media. The stria vascularis secretes endolymph and forms a lateral wall in the scala media

Answer 187

A

Divides scala media from scala vestibuli- forms a “roof”

Answer 188

A

Forms floor of scala media

Answer 189

A

The receptor region for hearing, contains 2 cell types: cochlear hair cells and supporting cells

Answer 190

A

Have one row of inner hair cells and three rows of outer hair cells. Cochlear nerve fibers wrap around hair cells (hair cells are innervated by the cochlear nerve).

Answer 191

A

Support hair cells and prevent damage to receptor cells

Answer 192

A

Compressions and rarefaction. Compression is when air molecules are pushed together and rarefaction is when air molecules spread apart. Air molecules bump against one another and travel outward from source-sound waves travel in one direction

Answer 193

A

A given medium. Sound travels the slowest in less dense mediums (air) and travels the fastest in dense mediums (solid objects)

Answer 194

A

Number of sound waves that pass a point in a given time- “pitch of a sound”. The human hearing frequency range is 20-20,000 Hz, but older individuals don’t hear higher pitched sounds as well as children

Answer 195

A

Distance between crests of a given sound wave. Shorter wavelength= higher frequency and higher pitch

Answer 196

A

Sound consisting of a single frequency. Most sounds we hear are mixtures of different tones

Answer 197

A

Height of crests for a given sound wave, denotes loudness of sound. Human hearing is from 0 dB-120 dB. Above 120 dB sound is painful, but hearing loss occurs from prolonged exposure to 90+ dB

Answer 198

A

The outer ear funnels the sound waves into the ear, and the sound waves vibrate the tympanic membrane. The malleus vibrates in response to tympanum, and the incus and stapes also vibrate. The stapes transmits vibrations to the oval window in the middle ear, where the scala vestibuli begins. The movement of the oval window causes the perilymph of scala vestibuli to move. Perilymph moves in pressure waves toward helicotrema. The round window acts as a pressure valve to allow perilymph movement

Answer 199

A

The round window is flexible and bulges toward the middle ear with each wave of perilymph so the waves aren’t compressed- pressure must go somewhere.

Answer 200

A

The helicotrema path or the basilar membrane path

Answer 201

A

If sound is low frequency (less than 20 hZ), the wave passes completely around helicotrema to the round window. Sound does not stimulate the spiral organ and sound perception will not occur

Answer 202

A

The sound is 20-20,000 hz. The sound waves are transmitted through the cochlear duct. Pressure waves vibrate the basilar membrane- stimulates hair cells in the spiral organ. The spiral organ is on top of the basilar membrane. Stimulation of hair cells generates action potential

Answer 203

A

The fibers in the basilar membrane differ in length and elasticity from the oval window to the helicotrema, so they will respond to specific frequencies.

Answer 204

A

Near oval window, fibers are short and stiff, respond to high frequency waves

Answer 205

A

Near the helicotrema, fibers are long and loose, respond to low frequency waves. Don’t need a lot of stimulation- basilar membrane responds better to low frequency.

Answer 206

A

Movement of basilar membrane stimulates inner hair cells. Inner hair cells have stereocilia embedded in the tectorial membrane. The stereocilia form the hair like structures of the hair cells. They get shorter as you move from one side of the hair cell to the other.

Answer 207

A

Tip links connect to mechanically gated ion channels- pulling tip links open ion channels and ions can move into/out of the hair cell. They are like trap doors on top of the stereocilia

Answer 208

A

Some tip links open, there is a small amount of ion flow. Inner hair cell is slightly depolarized- a small amount of neurotransmitter is released to the cochlear nerve

Answer 209

A

There is increased tension between the tip links. When tip links open, all ion channels open. K+ and Ca 2+ flood into inner hair cell, and the inner hair cell depolarizes- creates receptor potential. Neurotransmitter is released to cochlear nerve- action potential

Answer 210

A

Tip link tension decreases, so the tip links close. K+ and Ca 2+ no longer enter inner hair cell, so the inner hair cell hyperpolarizes. Neurotransmitter no longer released- prevents generation of an action potential

Answer 211

A

Fibers that wrap around outer hair cells are efferent. Therefore, the function of the outer hair cells is determined by the brain.

Answer 212

A

Increases responsiveness of inner hair cells- this amplifies the motion of basilar membrane and lets the basilar membrane distinguish between different sounds
Protection- outer hair cells stiffen in response to loud sound. Effect- basilar membrane becomes stiffer. This serves a protective function

Answer 213

A

The auditory cortex

Answer 214

A

Action potentials generated in cochlea pass through spiral ganglion to cochlear nuclei of the medulla. From there, fibers project to superior olivary nuclei. As they travel from the cochlear nuclei to the superior olivary nucleus, the fibers cross to opposite sides of the brain. The fibers pass through thalamus, project to primary auditory cortex.

Answer 215

A

After passing through the thalamus, some fibers are contralateral, others are ipsilateral (crossed over again) before they get to the auditory cortex.

Answer 216

A

Impulses from specific hair cells at specific regions of the basilar membrane are interpreted as specific pitch. Multiple frequencies stimulate multiple parts of the basilar membrane

Answer 217

A

Louder sounds= more movement of fluid in cochlea. Larger waves of fluid/larger amplitude= more movement of basilar membrane, more deflection of inner hair cells. More neurotransmitter is released by more deflection of hair cells, which results in stronger graded potentials and more frequent action potentials at the cochlear nerve.

Answer 218

A

Intensity and timing localize sound source

Answer 219

A

If intensity and timing are identical, the source of sound is above, below, in front, or behind. These locations are more central and the tympanum on both sides vibrate at the same frequency.

Answer 220

A

If intensity and timing are different, the sound is localized on your left or right side. For a sound on your right side, the tympanum on your right side will vibrate harder and at a different frequency than the tympanum in the left ear. Action potentials arrive at different rates.

Answer 221

A

Sense of our own location in space, involves structures found in the inner ear

Answer 222

A

Vestibule

2. Semicircular canals

Answer 223

A

Most central portion of bony labyrinth, posterior to the cochlea. Contains 2 membranous sacs with endolymph: the
saccule- continuous with the cochlea, smaller of the two, and the utricle- continuous with semicircular canals

Answer 224

A

Saccule and utricle contain maculae receptors- respond to linear acceleration and head position. Therefore, the saccule and utricle do not respond to a sensation of spinning or turning.

Answer 225

A

Moving straight forward, straight back, or to one side or the other.

Answer 226

A

System of 3 fluid filled canals- each canal lies in different plane of space (anterior, posterior, lateral). The semicircular duct passes through each canal.

Answer 227

A

Swelling at the end of each semicircular duct with receptor crista ampullaris

Answer 228

A

Respond to rotational movement

Answer 229

A

Flat patch with supporting cells and hair cells (stereocilia, kinocilia). Base of hair cells are supplied by the vestibular nerve- branch of the vestibulocochlear nerve. Tips of stereocilia and kinocilia embedded in the otolith membrane

Answer 230

A

Jelly like base with small otolith stones embedded in membrane. Otoliths are dense and heavy, they cause membrane to move in response to linear head movement

Answer 231

A

Movement of otolith membrane and jelly like base bends hair cells.

Answer 232

A

Bending toward kinocilium (tallest hair cell)- hair cells depolarize- more neurotransmitters are released and more action potentials are generated.

Answer 233

A

Bending away from kinocilium (bending head backwards)- hair cells hyperpolarize. Action potentials are still generated, just not as many. Brain interprets many more action potentials than usual as head movement.

Answer 234

A

Maculae are horizontal, hair cells are vertical, responds to forward and backward movement.

Answer 235

A

Maculae are vertical, hair cells are horizontal. Responds to upward/downward movement

Answer 236

A

Maculae only respond to CHANGES in head position- it’s not important if your head is in the same position for a longer amount of time

Answer 237

A

Contains hair cells and supporting cells that project into the ampullary cupula. No otoliths in the semicircular canals. Vestibular nerve fibers supply hair cells

Answer 238

A

Gel that surrounds hair cells in the cristae ampullares

Answer 239

A

Endolymph flows through canals in opposite direction as rotational movement- if spinning to the right, endolymph flows to the left. When hairs are deflected- depolarization occurs, increased neurotransmitter released- vestibular fibers generate action potentials

Answer 240

A

Consistent speed of rotation- endolymph travels at same speed as rotation. Hair cells are not stimulated

Answer 241

A

Endolymph flows in opposite direction. Hair cells hyperpolarize- less neurotransmitter released, less action potentials generated so the brain interprets this as a change in rotational movement

Answer 242

A

This is adaptive. We shouldn’t have to think about balance because if you lose your balance, you want to react quickly. We are consciously aware if we lose balance, but will fix our balance before we are consciously aware

Answer 243

A

Vestibular nuclei

2. Cerebellum

Answer 244

A

Major integrative area for balance, also receives visual and somatic receptors. Vestibular nuclei sends impulses to brain stem- information used to correct body position

Answer 245

A

Function- coordinates skeletal muscle activity and muscle tone to maintain head position, posture, and balance

Answer 246

A

The inner ear plays multiple roles in the special senses

Answer 247

A

Complete or partial loss of hearing. There are 2 types: conduction and sensorineural.

Answer 248

A

Anything that inhibits sound conduction through the ear (from outer ear to cochlea). Ex- ruptured tympanum, excessive cerumen, function of ossicles, otitis media. A ruptured tympanum can’t vibrate, so nothing can be transmitted to the cochlea, excessive cerumen physically blocks sound waves from getting through the external acoustic meatus

Answer 249

A

Hearing loss due to damage to neural structures. The typical cause is loss of hair cells over time. This can be due to explosive sounds, degeneration of cochlear nerve, stroke, or tumor in auditory cortex.
Explosive sounds can vibrate the basilar membrane so hard that the hair cells can be ripped apart

Answer 250

A

Cochlear implant. A cochlear implant converts sound waves to electrical energy (basically what the inner ear does). One part of the implant is implanted in the temporal bone, the other part is an electrode that is attached to the cochlea. Different electrodes respond to different frequencies of sounds that can be interpreted by the brain

Answer 251

A

Affects all parts of the inner ear (cochlea, vestibule, semicircular canals). Sensory receptors in the inner ear are very specific to the amount of endolymph in the inner ear and its consistency. If the amount of the endolymph changes, you affect the function/responsiveness of the sensory receptors. The syndrome is caused by excessive endolymph production in the inner ear.

Answer 252

A

Extreme vertigo, nausea, vomiting, tinnitus (ringing in ears if the cochlea is affected, occurs in the absence of sound), deafness

Answer 253

A

Motion sickness medication, diuretics to decrease endolymph production

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Chapter 15- Special Senses Flashcards

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