Lecture 16, Sensory Physiology

Question 1

Sensory Physiology - Introduction

Answer 1

sensory physiology refers to the study of sensation and sensory systems
a sensory system has three primary components:
- one or more sensory receptors (1)
◦ can be responsive to stimuli in either the external
or internal environment
- regions of the CNS responsible for processing the information from the sensory receptors (2)
◦ information from one receptor can be sent to
more than one region
◦ may or may not be sent to regions of the brain
that allow for the conscious awareness of the
stimuli
◦ sensation (when the sensory information has
reached conscious awareness) vs sensory
information vs perception (ex. being aware that
something is painful)
- neural pathways that connect the receptors to the aforementioned regions (3)

Question 2

Sensory Receptors

Answer 2

the first step of sensory processing occurs at the level of the sensory receptors
- transduction of the stimulus into a receptor (graded) potential (specific to sensory receptors) of an afferent neuron
- the receptor potential may turn into an action potential if the stimulus is significant enough to reach threshold potential

the stimulus opens ion channels, causing a change in the receptor potential
- if the receptors potential reaches threshold potential, an action potential will be initiated
- the first node of ranvier is usually the site of action potential initiation, due to the presence of voltage-gated ion channels (it matters that the action potential be at the first node of ranvier to reach threshold)

Question 3

Sensory Transduction

Answer 3

stimulus detection
- if the stimulus acting on a sensory receptor is sufficient, it will cause a change in the permeability of the membrane
◦ opening of ion channels on the receptor
membrane
- change in the receptor potential
if the stimulus is strong enough, summation of the receptor potentials will lead to the initiation of an action potential
transduction: the process of translating a stimulus into an action potential
- not all stimulus received by the sensory receptor will result in an action potential

Question 4

Sensory Transduction (magnitude of rp)

Answer 4

the magnitude of the receptor potential determines the frequency of action potentials in the afferent neuron, but does not determine the amplitude of the action potentials
- frequency = action potential firing rate
- the rate which is +30 mV will not change, but the rate at which we fire can be altered

factors that control the magnitude of the receptor potential include:
- stimulus strength
◦ example: amount of pressure felt by a
mechanoreceptor
- rate if change on stimulus strength
◦ example: a gradual vs sudden increase in
pressure
- temporal summation of successive receptor potentials
◦ more successive receptor potentials -> greater
cumulative receptor potential
- adaptation
◦ adaptation refers to a decrease in receptor
sensitivity to the same stimulus
◦ over time, action potential firing rate will decrease
despite the continuing presence of the stimulus
◦ receptors can be slow or fast adapting

Question 5

Sensory Receptor Adaptation (phasic and tonic)

Answer 5

phasic receptors are rapidly adapting
* generate a high frequency burst of action potentials right at the onset of the stimulus
* the receptor quickly stops responding to the stimulus, despite is still being present
* these receptors are not always active; only active when stimulated

tonic receptors are slowly adapting
* are also quite responsive immediately at the onset of the stimulus
* maintain a persistent (or slowly decaying) action potential output while the stimulus is present
◦ background level of stimulation
* the receptor stops action potential output when the stimulus is removed

Question 6

Sensory Receptor Adaptation (2)

Answer 6

tonic receptors will fire for the duration of the stimulus; often are tonically active
- for example: nociceptors are often tonic receptors, and will fire if a painful stimulus is present. if that stimulus is less severe, frequency of AP firing will be lower but still constant. the stimulus needs to be completely removed to stop AP firing

meanwhile, phasic receptors adapt very rapidly and are generally only fire APs in response to a change in the stimulus

Question 7

Peripheral vs Central Adaptation

Answer 7

differences in adaptation at the level of the sensory receptors is peripheral adaptation
- adaptation can also occur at the level of the central nervous system = central adaptation

adaptation: reduction in the sensitivity of the nervous system to a constant stimulus

peripheral adaptation: phasic sensory receptors become less responsive to a stimulus
examples: becoming used to background noise, room temperature, the feeling of clothing

central adaptation: sensory receptors are still responsive to the stimulus, but adaptation occurs at the CNS due to inhibition of various nuclei
- sensory information is still present and may evoke reflex responses, but there is no sensation or conscious perception of that sensory information
- example: getting used to the odor of a place you visit frequently

Question 8

Sensory Receptors (directly and indirectly activate)

Answer 8

sensory receptors monitor changes in specific variables, in either the external or internal environment
- usually are present at the peripheral (dendritic) end of an afferent neuron
◦ stimulus directly activates the afferent neuron
- can also be a separate receptor cell that sends a signal to the afferent neuron via a chemical messenger (neurotransmitter)
◦ stimulus indirectly activates the afferent neuron
◦ a separate receptor cell is a specialized neuron
sensory receptors exhibit specificity; they are only
responsive to a specific type of stimuli
- within one tissue, we may have several different types of receptors, each of which are sensitive to different stimuli
- this is called receptor specificity
sensory receptors (at the cell level) vs receptor proteins (at protein level) - know distinction

Question 9

Sensory Receptor Specificity

Answer 9

there are many types of sensory receptors, with each one being responsive to a specific type of stimuli
* adequate stimulus: the stimulus that a sensory receptor is responsive to in normal functioning

some of the types of sensory receptors: nociceptors, mechanoreceptors, chemoreceptors, thermoreceptors and photoreceptors

*while sensory receptors are generally only activated by specific stimuli, secondary stimuli can sensitize or desensitize the sensory receptors

Question 10

nociceptors

Answer 10

responsive to pain; responsive to tissue damage or potential tissue damage
◦ extreme temperature, chemicals, mechanical
damage

Question 11

mechanoreceptors

Answer 11

responsive to mechanical stimuli
◦ pressure, touch, vibration

Question 12

chemoreceptors

Answer 12

responsive to specific chemicals
◦ metaboreceptors = responsive to metabolites

Question 13

thermoreceptors

Answer 13

responsive to cold or warmth; phasic receptors

Question 14

photoreceptors

Answer 14

responsive to light stimuli (particular ranges of the electromagnetic spectrum)

Question 15

Types of Sensory Receptors (classified by what two things?)

Answer 15

sensory receptors can be classified based on what they monitor:
- exteroreceptors – monitor the external environment
- interoreceptors – monitor visceral organs
- proprioreceptors – monitor position of skeletal muscles and joints

sensory receptors can also be classified based on the senses they contribute to:
general senses: (are usually the dendritic ends of the afferent neuron)
- pain, touch, temperature and proprioception
special senses: (tend to be more complex, and are located in specific sense organs)
- smell, sight, hearing, taste and balance

Question 16

The Sensory Unit

Answer 16

a sensory unit includes a single afferent neuron and all its sensory receptors or afferent receptor endings
- most of the time, one single afferent neuron has several sensory receptors associated with it

receptive field: the area of the body that, when stimulated, results in a change in the receptor potential of the afferent neuron
- the area of the body that is monitored by one afferent neuron and all its receptors
- multiple receptive fields can overlap a specific area of the body

Question 17

Sensory Coding - Frequency Coding

Answer 17

sensory coding refers to how different types of stimuli or stimulus energies are converted into distinguishable signals at the level of the sensory receptor
- each signal includes information of the input it represents, the intensity of the stimulus, and its location on/in the body; information such as:
◦ stimulus modality (cold/warm/hot)
◦ stimulus intensity (strong/weak)
◦ stimulus location (% of receptive field)
changes in intensity, location, and modality will alter the frequency of APs relayed by the afferent neuron
* frequency coding = stronger stimuli results in a greater frequency in AP firing rate

Question 18

Sensory Coding - Location (acuity)

Answer 18

acuity: the precision that we can discern one stimulus from an adjacent one; depends on:
- the amount of convergence or neural input (greater convergence = less acuity)
- the size of the receptive field (greater size = less acuity)
- density of the sensory units and the amount of overlap between receptive fields (more receptive field overlap = less acuity)
- at a certain point when they are placed very close together it seems like one, so it would be less acuity

Question 19

Two-Point Discrimination

Answer 19

two-point discrimination is an acuity test that determines the acuity of sensory units in a specific area of the body
more sensitive areas of the body have greater acuity
- example: the lips are quite sensitive; they have smaller receptive fields and a higher density of sensory units
◦ better able to discriminate between two points
close together
- example: the back is much less sensitive; it has larger receptive fields and less density of sensory units
◦ more likely to code two stimuli as one

Question 20

Receptive Field Overlap

Answer 20

the center of a receptive field has the highest density of sensory receptors; is the most sensitive area of the receptive field
* a decreased AP firing rate could mean either a weak stimulus or a stimulus located farther from the center of the receptive field
-> to more precisely determine stimulus intensity and location, there is some receptive field overlap

• a decreased AP firing rate from multiple afferent neurons indicates that the stimulus is farther from the center of the receptive fields, in the areas of overlap
• a decreased AP firing rate from only one afferent neuron indicates that the stimulus is weak, and likely closer to the center of the receptive field
  -> overlapping receptive fields enhances localization of the stimulus
• receptive field overlap provides information on the precise location of a stimulus

Question 21

Sensory Coding - Population Coding

Answer 21

increasing stimulus intensity also usually activates a larger area, so also have an increase in the number of sensory neurons that will be activated
- the number of sensory neurons that are recruited (activated) by a stimulus = population coding
- lower threshold (more sensitive) sensory units will be activated first
- increasing stimuli intensity results in the activation of more receptors
* population coding = stronger stimuli results in the activation of more afferent neurons