Neurophysiology: Special Senses (Fall 2024) PDF

Summary

These lecture notes cover neurophysiology, focusing on the special senses, including olfaction (smell), gustation (taste), and audition (hearing). The document details the anatomy and physiology of these systems in a veterinary context, using illustrations and diagrams.

Full Transcript

Andre Azevedo, DVM, MSc
Assistant Professor of Veterinary Physiology
[email protected]
 At the end of the lecture, students should be able to:
Describe the function of the taste and smell
Describe olfactory cells and their location
Describe the basic stimulation of olfactory cells
Describe taste buds and their location
Describe the basic stimulation of taste cells
Understand the relationship between taste/smell and the limbic system
Describe the location and structure of the auditory sensory receptors
Describe how sound waves are transduced to action potentials
Summarize the events involved in hearing
 smell

The olfactory system is essential for:
Localization of food/prey
Reflex-stimulated secretion of digestive enzymes
Detection of danger
 The olfactory system consists of the
following:
info
OLFACTORY BULB receive olfactory

OLFACTORY TRACT send info

LATERAL OLFACTORY GYRUS
PIRIFORM LOBE receive info
 The olfactory cells are part of the specialized epithelium found
on the ethmo-turbinate bones of the nasal cavity
Olfactory mucosa of dogs have 220 million olfactory receptors
Humans = 5 million

The olfactory cells give rise to the olfactory nerve fibers that terminate in the
olfactory bulb
 The olfactory cells are the receptor cells for smell
sensation
They are bipolar neurons derived originally from the central nervous
system
They are located in the olfactory epithelium interspersed among
supporting cells
Have cilia projecting into the mucus that coats the inner surface of the nasal
É
cavity notvisible hairs
nose
The cilia reacts to odors in the air and stimulate the olfactory cells

Spaced among the olfactory cells are many olfactory glands
Secrete mucus onto the surface of the nasal cavity
Supporting
only neurons that can regenerate over time cells
receives
 Bindtolevels
a coupled
receptors
open catinatchannels openchloridechannel depot
cAMP ion
The OLFACTORY CILIA responds to olfactory chemical stimuli
ODORANT MOLECULES THAT EPSP TRAVELS FROM THE CILIA
ENTER THE NASAL CAVITY TO THE TRIGGER ZONE OF THE
DIFUSES INTO THE MUCUS OLFACTORY CELL TO GENERATE
AN ACTION POTENTIAL
BIND TO GPCR IN THE
MEMBRANE OF EACH CILIUM
MEMBRANE DEPOLARIZES AND
THE ALFA SUBUNIT ACTIVATES GENERATE AN EXCITATORY POST
ADENYLYL CYCLASE, WHICH SYNAPTIC POTENTIAL (EPSP) IN
PRODUCES cAMP THE CILIA

cAMP ACTIVATES A GATED
Na/Ca ION CHANNEL AND INFLUX OF Ca ACTIVATES
ALLOW INFLUX OF CATIONS CLORIDE CHANNELS TO OPEN
(MOSTLY CALCIUM) AND Cl LEAVES THE CELL

specificcells
 The olfactory nerve fibers terminate
and synapse in the olfactory bulb to
form the olfactory tract (CN I)
Specific cells are present in the
olfactory bulb
TUFTED CELLS into
MITRAL CELLS
Dendrites from these cells synapse with E
terminal ends of olfactory cells forming the
glomeruli of the olfactory bulb
 education
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The olfactory tract reaches:
1. the ipsilateral piriform lobe (olfactory area)
2. non-olfactory portions of the brain (part of the
limbic system)
Amygdala, entorhinal cortex, hippocampal formation,
septal nuclei
These areas also send olfactory signals to the hippocampus
and frontal cortex
OLFACTORY SIGNALS DO NOT DIRECTLY PROJECT
TO THE THALAMUS
Eistitiesor
The limbic system is responsible for forming olfactory
memories
Olfaction can evoke emotional and autonomic responses
 FYI

OOT – Olfactory-occipital tract (orange)
OCST – Olfactory-corticospinal tract (turquoise)
OPT – Olfactory-piriform tract (green)
OLT – Olfactory-limbic tract (blue)
OET – Olfactory-entorhinal tract (pink)
 THE CONNECTION BETWEEN
TASTE, SMELL, AND MEMORY

Both senses are strongly tied to primitive emotional and behavioral functions of the nervous system

There are many connections between the olfactory and gustatory systems
and the regions responsible for emotion and memory
 Taste is mainly a function of TASTE BUDS which contains
a taste receptor cell
In dogs, they are located in various types of PAPILLAE
Protrusions on the dorsal and lateral surface of the tongue
1. FUNGIFORM PAPILLAE
Throughout the dorsal surface of the rostral two-thirds of the tongue
Especially on the lateral margins and the tip
2. VALLATE PAPILLAE
Occupy the caudal portion of the dorsal tongue
FOL VAL FOL
3. FOLIATE PAPILLAE
Dorsolateral part of the caudal part of the tongue

FUNGI
 Dogs have about 1700 taste buds, while humans have 9000
CATS ONLY 470!
Dogs seem to have a sense of taste for sweet, salt, sour, and bitter

not in one area all over
 y

Taste buds are composed of
groups of columnar taste receptor
cells microvini

Bundled together like a bunch of bananas
Taste receptors are arranged such that their tips
form a small taste pore
Through this pore extends microvilli

Each taste cell has receptors for only one type of
flavor
I tastecellreceptor 1typeofflavor
 Chemical molecules that trigger the sense of taste
are dissolved by the saliva
They enter the taste bud through a pore
Bind to the receptors located in the membrane of the microvilli
The binding of molecules with receptors depolarizes the membrane of the
taste cells
The mechanism depends on the taste molecule that binds to their specific receptors
FEE
 The taste cells are into
innervated by bipolar
to
send g
neurons that contribute
to brain
axons to 2 cranial nerves: Thalamus

Emittae
FACIAL (CN VII)
GLOSSOPHARYNGEAL (CN IX)
Afferent fibers send the
message to the ipsilateral
cerebral cortex (insular area)
sensoryareafortaste
Also projects to the amygdala of
the limbic system!

Brainstem
 FYI

Can minimize sometimes
 FYI

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 The auditory system is designed to detect and analyze
sounds in the environment
Much of animal communication relies on this system
Hearing requires at least 1 ear, but localization of sound requires 2 ears
Auditory system must detect the difference in time arrival or intensity of sounds in 2 ears

Animal’s sense of hearing is enhanced by their ability to move their ears around
Scan the environment for different sounds
Localize the sounds
 Hearing involves the external ear, middle ear, and
inner ear
The sensory receptor is located in the inner ear

Outer ear
Middle ear
Inner ear
 The external ear directs the sound waves into the ear
canal
Is composed by:
The fleshy part – Pinna

8 The ear canal (L shaped)

Is separated from the middle ear
o
by the tympanic membrane or eardrum
o
 The middle ear is an air-filled cavity in the temporal
bone
Connected to the nasopharynx by the auditory tube
EUSTACHIAN TUBE
Drains the middle ear cavity

Contain the OSSICLES
3 tiny bones

Mostly
Air
father
Eustachian
tube
 cut a bulb

The OSSICLES are 3 tiny bones connected to each other
MALLEUS
connected to the eardrum

INCUS
Between malleus and stapes

STAPES
connected to the oval/round window
membrane separation between the middle and the inner ear

Transmit vibrations via tympanic
 we

The OSSICLES transfer vibration of the eardrum to the
oval window
Avoids significant loss of vibration as the sound wave is transferred
from the air-filled outer ear to the fluid-filled inner ear
Where the sensory receptor is located

Decrease the amplitude of sound waves protecting the sensitive sensory cells
 The inner ear (LABYRINTH) contains the sensory
organs for both the auditory system and vestibular
system
Vestibular system detects acceleration and static tilt of the head

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 The auditory portion of the inner ear complex is called COCHLEA
Spiral shaped
Comes from the Greek word for snail
Filled with fluid (perilymph) eqti.ie
Contains
COCHLEAR DUCT
Filled with fluid (endolymph)
ORGAN OF CORTI interfild
Hair cell receptors
 fluid

detect
vibration
The sensory hair cells are mechanoreceptors
Have 50-100 stereocilia in their apical surface more
Eisen
Connected by tip links at their tips
a
Tip links seem to be attached to K channels
Open when bending of the stereocilia pulls the tip links apart

Sterocilia do not regenerate and can cause hearing loss
Excessively loud sounds can destroy them
by moving them excessively
 of K
plots
surrounded by endolymph
The TECTORIAL MEMBRANE overlies the sensory cells
An anchored gel-coated ridge

The BASILAR MEMBRANE is the floor of the Organ of Corti
More elastic
Both are very important for sound transmission
 9
pratfa
s

vibYEtgmpn TL

waves w particular
frequency can cross
to get shortcut sounds
differenciate diff
through
organofcortiis beingpassed
 Sound waves are transmitted to the
inner ear and cause vibration to the
Organ of Corti

The base of the hair cells sits on the
basilar membrane, and the cilia are
embedded in the tectorial membrane

Vibration of the Organ of Corti causes
bending of cilia on the hair cells by a
shearing force as the cilia push against
the tectorial membrane
 more kt insid cel
theathporatite
Bending of the cilia produces a change in the K +
conductance of the hair cell membrane
Bending in one direction causes DEPOLARIZATION lotsof
Triggers potassium influx from endolymph (High concentration)
K+
Leads to Ca channel opening and release of neurotransmitter i
Glutamate
Function as an excitatory neurotransmitter
Cause action potentials in the cochlear afferent nerve fibers

Bending in the other direction causes HYPERPOLARIZATION
Stops potassium influx
Glutamate is not released
Action potential is not formed
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sweet
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 This oscillatory pattern is called COCHLEAR MICROPHONIC POTENTIAL
Intermittent release of glutamate – intermittent firing of afferent nerves
Mirrors the waveform of the acoustic stimulus

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 Apex

Different auditory hair cells are
activated by different frequencies
Base
Hair cells located at the base of the basilar
membrane respond best to high frequencies

0
Hair cells located at the apex respond best to
low frequencies

base
apex
 The basilar membrane act as a sound frequency analyzer
The spatial mapping of frequencies is also present in the brain: TONOTOPIC MAP
Map that tells where sounds of different frequencies are processed in the brain
 Information is transmitted from the hair cells along the cochlear nerve
Relays auditory impulses to the cochlear nuclei in the medulla oblongata
Axons ascend the brainstem (making several synapses) and reach the thalamus
The information is processed in the auditory cerebral cortex

synapse

Cindrosses
 3ilat bothauditory
toterfe

https://www.youtube.com/watch?v=PeTriGTENoc
FYI
generort white
FYI
bad hearing
 FYI

can be
deaf
 FYI

Congenital sensorineural deafness
Dogs carrying the piebald or merle genes and breeds of cats
carrying the white gene (pure white)

The vascular bed, stria vascularis, is responsible for secretion
of endocochlear fluid and maintenance of its high K+
concentration

Absence of strial melanocytes, whose presence or postnatal
development is suppressed by the piebald or merle genes,
leads to degeneration of the stria vascularis

The hair cell loss is secondary to degeneration of the
cochlear blood supply

Hair cell loss starts 1-3 weeks old, and is irreversible, leading
to deafness
 FYI

Congenital sensorineural deafness
More info:

https://www.lsu.edu/deafness/VetClinNA.htm

https://www.lsu.edu/deafness/deaf.htm

https://www.merckvetmanual.com/ear-disorders/deafness/deafness-in-animals

https://www.researchgate.net/publication/24421886_Brainstem_auditory_evoked_resp
onse_BAER_testing_in_animals

https://www.vin.com/apputil/content/defaultadv1.aspx?pId=11165&meta=generic&id=3
848661

https://www.cliniciansbrief.com/article/white-cat-genetic-deaf