Sensory System

Question 1

What is a sensory receptor?

Answer 1

Specialised peripheral endings of afferent neurons.

Each receptor responds to a different type of stimulus whereby it translates the energy from the stimulus into electrical stimulus.

This is termed signal transduction.

Question 2

What are the two different types of sensory receptors?

Answer 2

specialised afferent endings and 2 cell receptors

Question 3

What is the difference between 1 and 2 cell sensory receptors?

Answer 3

specialised afferent endings are continuous with the nerve fibre whereas 2 cell receptors are separate (i.e. receptor cell + nerve ending)

Question 4

How does signal transduction compare between 1 and 2 cell sensory receptors?

Answer 4

a specific stimulus opens stimulus-sensitive channels on both causing Na+ to enter and depolarisation resulting in an AP to propagate along the nerve

2 cell receptors go through extra steps, however:
-depolarisation opens voltage-gated Ca2+ channels
-Ca2+ triggers exocytosis of neurotransmitter
-neurotransmitter opens chemically-gated ion channels at afferent nerve, Na+ enters
-THEN an AP propagates along nerve

Question 5

Describe the difference between tonic and phasic receptors.

Answer 5

tonic= slow adapting, AP’s occur as long as the stimulus is present i.e. nociceptors

phasic= fast adapting, AP’s occur when first stimulated, stop and then again when stimulus is removed i.e. touch receptors

Question 6

What 4 types of information do sensory nerves convey to the CNS?

Answer 6

modality, location, intensity and timing

Question 7

Define ‘labelled line theory’.

Answer 7

This principle states that nerves are modality specific and so they travel to specific regions of the cortex. This is how the brain knows which modality is being perceived.

Question 8

How can our CNS detect a stimulus of greater intensity?

Answer 8

more frequent firing of AP’s or activation of more receptors

Question 9

Name the encapsulated cutaneous receptors.

Answer 9

Pacinian corpuscle, Meissner’s corpuscle, Ruffini endings.

Question 10

Name the non-encapsulated cutaneous receptors.

Answer 10

Merkel’s disc/complex, free nerve endings, hair follicle receptors

Question 11

What modalities are Pacinian corpuscle receptors sensitive to?

Are they phasic or tonic?

Answer 11

vibration & deep pressure

phasic

Question 12

What modalities are Meissner corpuscle receptors sensitive to?

Are they phasic or tonic?

Answer 12

light touch

phasic

Question 13

What modalities are hair receptors sensitive to?

Are they phasic or tonic?

Answer 13

hair movement/light touch

phasic

Question 14

What modalities are Ruffini corpuscle receptors sensitive to?

Are they phasic or tonic?

Answer 14

deep pressure

tonic

Question 15

What modalities are Merkel’s complex receptors sensitive to?

Are they phasic or tonic?

Answer 15

light sustained touch

tonic

Question 16

What modalities are free nerve endings sensitive to?

Are they phasic or tonic?

Answer 16

crude touch, pain & temperature

tonic

Question 17

Name the 4 types of nociceptors.

Answer 17

mechanoreceptors, thermoreceptors, polymodal receptors & silent nociceptors

Question 18

What are silent nociceptors?

Answer 18

nociceptors that are only activated during inflammation

Question 19

Contrast fast pain and slow pain.

(mechano- & thermoreceptors vs polymodal)

Answer 19

fast pain occurs on stimulation of mechano- or thermoreceptors, is carried by small myelinated A-delta fibres, produce a sharp prickling sensation, are easily located and occur first.

slow pain occurs on stimulation of polymodal receptors, is carried by small, unmyelinated C-fibres, produces dull, aching, burning sensation, is poorly localised and occurs second.

Question 20

What are the two neurotransmitters involved in pain production?

Answer 20

Substance P & Glutamate

Question 21

What is Substance P’s role in pain production?

Answer 21

activating ascending pathways that transmit nociceptive signals to higher levels for further processing.

Question 22

Is Glutamate an excitatory or inhibitory neurotransmitter?

Answer 22

excitatory

Question 23

What is descending inhibition?

Answer 23

is the body’s natural analgesic system and works by suppressing transmission in pain pathways as they enter the spinal cord.

Question 24

What is descending inhibition dependent on?

Answer 24

the presence of appropriate opiate receptors for endorphins, enkephalins or dynorphin.

Question 25

How do endogenous opiates work during descending inhibition?

Answer 25

by blocking the release of Substance P or Glutamate at the afferent pain fibre before it can reach the spinal cord.

Question 26

What are the two major components of the vestibular system?

Answer 26

semicircular canals & otolith organs

Question 27

What movement do the semicircular canals respond to?

Answer 27

rotational forces

Question 28

What movement do the otolith organs respond to?

Answer 28

gravitational forces

Question 29

How do semicircular canals detect rotational movement?

Answer 29

the canals are filled with endolymph which move when the head does

this causes the movement of hair cells within the cupula which either become depolarised or hyperpolarised depending on the direction

an AP is then sent via the vestibulo-ocular nerve to the brainstem and cerebellum to produce postural corrections

Question 30

What makes up a hair cell?

Answer 30

each hair cell contains 1 kinocilium & 20-50 stereocilia which are connected by tip links

Question 31

Does endolymph move in the same or opposite direction to the head?

Answer 31

opposite

Question 32

Does depolarisation occur when movement occurs towards or away from the kinocilium of a hair cell?

Answer 32

toward

Question 33

What two components make up the otolith organs?

Answer 33

the utricle and saccule

Question 34

How does the orientation of hair cells differ between the utricle and saccule?

Answer 34

utricle hair cells vertical, saccule hair cells horizontal

Question 35

Hair cells are anchored in the cupula in the SCC, where are they anchored in the otolith organ?

Answer 35

in the maculae

Question 36

What are otoliths? What is their purpose?

Answer 36

calcium carbonate crystals

they move according to where the head is in gravity and produce signals to relay to the brainstem and cerebellum

Question 37

Are signals sent from the hair cells during constant movement?

Answer 37

no- only when movement starts or stops

Question 38

Describe the pathway of AP’s from the vestibular system to the brain.

Answer 38

vestibulocochlear never > vestibular nuclei in the brainstem > cerebellum

Question 39

What does the vestibulo-ocular reflex aim to achieve?

Answer 39

maintain visual focus on something while the head is in motion (stabilise the image on the retina) through excitation of extraocular muscles on the opposite side of the face while inhibiting on the same side.

Question 40

What makes up the external ear?

Answer 40

pinna, external auditory meatus and the ear drum (tympanum)

Question 41

What is the role of the external ear in hearing?

Answer 41

transmitting & amplifying airbourne sound waves to the fluid-filled inner ear

Question 42

What is the role of the middle ear?

Answer 42

same as the external ear

Question 43

What makes up the inner ear?

Answer 43

cochlear & vestibular apparatus

Question 44

What are soundwaves?

Answer 44

the alternating compression and refraction of air molecules as heard in dB

Question 45

What is the hearing threshold for humans?

Answer 45

~1dB

normal conversation is ~60dB
jet plan is ~150dB

Question 46

Describe the path that soundwaves take through the ear.

Answer 46

soundwaves enter via the external auditory meatus

tympanic membrane (ear drum) vibrates when stuck by soundwaves

the middle ear transmits vibrations through ossicles to the oval window

waves in the cochlear fluid set the basilar membrane in motion

hair cells are bent as basilar membrane is deflected up & down

mechanical deformation of specific hair cells is transduced into neural signals that are then transmitted to the auditory complex in the temporal lobe for sound perception

Question 47

How is frequency perceived in the inner ear?

Answer 47

by the location where it is detected by the organ of Corti

high frequencies are detected earlier/closer to the oval window while low frequencies are detected later/further from the oval window

Question 48

How does the function of inner and outer hair cells differ?

Answer 48

outer hair cells are for amplifying sound whereas inner hair cells are for sending potentials

Question 49

Which type of hair cell releases prestin?

Answer 49

outer hair cells

Question 50

How does the innervation differ between IHC and OHC?

Answer 50

IHC are innervated by more afferent nerves than efferent

OHC are innervated by more efferent nerves than afferent

Question 51

Describe the process of depolarisation in hair cells of the ear.

Answer 51

1. tip links stretch and open channels when stereocilia bend towards tallest member
2. K+ enters, hair cell depolarises
3. Depolarisation opens voltage-gated Ca2+ channels
4. Ca2+ entry causes greater release of neurotransmitter
5. more neurotransmitter leads to higher rate of AP

Question 52

Describe the process of hyperpolarisation in hair cells of the ear.

Answer 52

1. tip links slacken and close channels when stereocilia bend away from tallest member
2. No K+ enters, hair cells hyperpolarise
3. Ca2+ channels close
4. No neurotransmitter is released
5. No AP occurs

Question 53

What is so interesting about AP’s produced by hair cells in the auditory system?

Answer 53

they use potassium channels to depolarise as opposed to sodium channels like much of the rest of the nervous system

Question 54

What are the 2 different types of hearing loss?

Answer 54

conductive & sensorineural

Question 55

What is the difference between conductive & sensorineural hearing loss?

Answer 55

conductive refers to issues that occur prior to the cochlear i.e. glue ear, foreign material, ostitis media (middle ear infection)

sensorineural refers to issues that occur after the cochlear i.e. presbycusis (age related hearing loss), noise damage, ototoxic drugs

Question 56

What does a Rinne test do?

Answer 56

determines the presence of conductive hearing loss

Question 57

What is the procedure of a Rinne test?

Answer 57

place a struck tuning fork on the mastoid bone behind the ear and have the patient indicate when sound is no longer heard

Move the fork to beside the ear and ask if it is now audible

Question 58

What would indicate conductive hearing loss in a Rinne test?

Answer 58

the patient cannot hear the tuning fork at the ear (bone conduction is stronger than air conduction)

normally, air conduction will be stronger and the patient can still hear the fork at the ear

Question 59

What does a Weber test do?

Answer 59

determines the presence of either unilateral conductive or unilateral sensorineural hearing loss

Question 60

What is the procedure of a Weber test?

Answer 60

place a struck tuning fork on the forehead, looking for lateralisation of sound

Question 61

What would be normal in a Weber test? What would be abnormal?

Answer 61

normal would be no lateralisation of sound

if the issue is unilateral conductive loss the sound will move towards the affected ear

if the issue is unilateral sensorineual loss the sound will move towards the unaffected ear

Question 62

What is accommodation in the visual system?

Answer 62

our way of focusing by contracting/relaxing the lens and changing its shape

Question 63

What muscles and ligaments are involved in accommodation?

Answer 63

ciliary muscle & suspensory ligaments

Question 64

What is the name given to age-related stiffening of the lens?

Answer 64

presbyopia

Question 65

What is happening to the ciliary muscle & suspensory ligaments during sympathetic stimulation? What effect does this have on the lens?

Answer 65

the ciliary muscle is relaxed and the suspensory ligaments are taut

the lens is flat

Question 66

What is happening to the ciliary muscle & suspensory ligaments during parasympathetic stimulation? What effect does this have on the lens?

Answer 66

the ciliary muscle is contracted and the suspensory ligaments are loose

the lens is rounded

Question 67

What is the cause of myopic vision (near-sighted)?

Answer 67

eyeball too long or lens too strong

Question 68

What is the cause of hyperopic vision (far-sighted)?

Answer 68

eyeball too short or lens too weak

Question 69

How do you correct myopic vision?

Answer 69

with a concave lens

Question 70

How do you correct hyperopic vision?

Answer 70

with a convex lens

Question 71

Name the 2 different kinds of photoreceptors in the retina.

Answer 71

rods and cones

Question 72

Compare and contrast rods & cones.

Answer 72

~120 million rods vs ~6 million cones

rods do black & white while cones do colour vision

rods are located peripherally, cones centrally at fovea

rods have high sensitivity, cones have low

rods have low acuity, cones have high

much convergence with rods, little with cones

Question 73

Where is the fovea located and what is its significance in vision?

Answer 73

centre of the retina

it is the point of most distinct vision because it only contains cones (which has high visual acuity)

also, bipolar and ganglion cells are ‘pulled aside’ which means light can strike cones directly

Question 74

Where is the macula lutea located?

Does it have high or low visual acuity?

Answer 74

around the fovea

fairly high acuity

Question 75

What kind of vison does macular degeneration cause?

Answer 75

‘donut’ vision

Question 76

What is the purpose of the pupillary light reflex?

Answer 76

to restrict the amount of light entering the eye in case of damage, and to maintain vision in different levels of lighting.

Question 77

Which nerve supplies afferent information from the retina?

Answer 77

optic nerve

Question 78

Which nerve supplies efferent information from the brainstem to the ciliary muscles?

Answer 78

oculomotor nerve

Question 79

What is the clinical significance of the pupillary light reflex?

Answer 79

It is possible to determine the level of lesion/dysfunction by triggering the pupillary light reflex and watching for the pupils to constrict/dilate.