Post on 22-Dec-2015
Sensation & Perception
Lecture 18: Chemical Senses
Andy Clark
December 1, 2004
Taste & Smell
• Chemical Senses vital for survival
• Allows for approach to appetitive stimuli / Retreat from noxious stimuli– macrosmatic: highly developed sense of
smell / reliance on olfactory system– microsmatic: weakly developed sense of
smell / less reliance on olfactory system
Olfaction
• Humans less sensitive to odorants than a # of other organisms– Individual receptors capable of reliably
signaling one molecule of a compound– Analogous to exquisite sensitive of rod
receptors in vertebrate retina
• Disparity in sensitivity due to differences in absolute # of receptors
Olfaction
• Humans capable of detecting small differences in odor intensity– Previously thought that Weber fraction for
smell was worst of any sense– Now know that previous reports of poor
sensitivity were simply artifacts of poor experimental control
Olfactory System
Central
Projections
•Pyriform Cortex
•Orbitofrontal Cortex
•Amygdala
Olfactory
Mucosa
Olfactory
Bulb
Olfactory System
Olfactory Mucosa
Olfactory Receptor Neurons (ORN)
• Signal Transducers– 1000 different types– 10,000 of each type– Each type found in only 1 zone of mucosa
– Vision:– 3 cone types, 1 type of rod– 6 million cones, 120 million rods
Olfactory Receptors
• Membrane bound proteins– Located in cilia on tips of ORN’s
• Cause change in membrane potential of ORN when bound by ligand
• 1000 different types of receptor– Only 1 type per ORN
Olfactory Mucosa-Organization
1
2
3
4
4
Zones
…
ORN’s
Olfactory Bulb
• Organized into 4 zones
• Glomerulus– Primary structure w/in
bulb-receives input from 5,000-10,000 ORN (input predominately from 1 type of ORN)
– 1000-2000 glomeruli
Neural Coding
• Currently know little about how odor perception relates to physical & chemical properties of molecules (I.e. structure, electrical charge, etc.)
• Similar molecular structure different smells
• Disparate molecular structure similar smells
Neural Coding-Specificity
• Most Olfactory Receptor Neurons exhibit significant response to a wide range of odorants
• Little regard to molecular structure
Neural Coding-Distributed
• Dispute as to the sparseness of odorant tuning w/in individual ORN and glomeruli
• Accepted that different odorants produce different patterns of activation across the population
• Odorants producing similar patterns produce similar perceptions
Central Processing
• Many neurons w/in cortical areas in the olfactory system respond to a variety of odorants
• Many multi-modal (respond to pairing of taste with smell)
• Responses affected by behavioral/emotional context
Accessory Olfactory System
• Many organisms possess an accessory olfactory system
• Involved in the processing of chemosignals from conspecifics (pheromones)– Vomeronasal organ
• Influence mating, paternal, group behavior in insects, rodents, elephants, etc.
Pheromones-Humans
• McClintock (’71)– Synchronization of menstrual cycles amongst
women living together
• Russel et al (’80)– Sweat from donor periodically applied to upper
lip of subjects increased correlation between donor and subject’s menstrual cycle
Pheromones-Humans
• Major Histocompatibility Complex (MHC)– Influences immune recognition, susceptibility
to infectious disease, mating preference etc.
• Found that human females prefer odors from males with allelic matches to paternally inherited MHC genes
Taste
• Distinction made between taste & flavor
• Taste signaled by action of gustatory system
• Flavor signaled by joint action of olfactory and gustatory systems
Tongue
• Organ-tongue
• Covered with structures termed papillae
• 4 types1. Filiform (conical, entire surface)
2. Fungiform (mushroom, tip & sides)
3. Foliate (folds along sides)
4. Circumvallate (flat mounds, back)
Tongue
Taste Buds
• Only Filiform papillae don’t contain taste buds
• 10,000 total• Outer taste pore contains 4
types of receptor sites• When bound with ligand
cause change in ion flux (either directly or indirectly) which lead to change in membrane potential of nerve cell
Taste Receptors
• 4 basic receptor types on taste cells
• Each associated with a particular taste quality
1. Salty
2. Sweet
3. Sour
4. Bitter
Gustatory System
Mouth & Larynx
Tongue
Chorda Tympani Nerve
Vagus Nerve
Glossopharyngeal Nerve
Nucleus Solitary Tract (NST)
Thalamus
Frontal Operculum
Insular Cortex
Gustatory System
Taste-Genetics
• Genetic differences affect individual’s taste experience– Phenlythiocarbamide (PTC)
• ‘Tasters & Non-tasters’
– 6-n-propylthiouracil (PROP)• Tasters have higher density of taste buds than non-
tasters
Neural Coding-Specificity
• Neurons w/in cranial nerves and NST show significant response to a number of substances
• Some tuned sharply for a particular class– Application of receptor
antagonist blocks inhibits subsequent responses
Neural Coding-Distributed
• Different substances produce different patterns of firing in the cranial nerves carrying signals from taste receptors
• Substances producing similar activity patterns judged more similar (psychophysically)
Flavor Perception
• Requires combination of oral and nasal stimulation
• Subjects have a hard time identifying flavor if nostrils are clamped shut
• Strength of taste qualities also perturbed when nasal stimulation is limited
Flavor-Central Basis
• Physiological processes operating outside the sensory pathways also have an influence on perceived flavor– alliesthesia: decrease in pleasantness as
consumption increases• Central time to develop / doesn’t need to be
ingested
Flavor-Sensory Adaptation
• Sensory specific adaptation can also influence an individual’s perception of flavor– Subject’s ratings of the pleasantness of an odor
decrease after consuming that substance (specific)
– Similar effect occurs regardless of whether food is: swallowed or just chewed
Flavor-Encoding
• Neuron’s within the Orbitofrontal Cortex receive input from both olfactory and gustatory cortices (as well as visual and somatosensory)
• Respond to similar qualities across modalities (I.e. smell and taste of similar substances, etc.)
Flavor-Encoding
• Hunger also influences responses of primate Orbitofrontal cortex neurons
• With additional consumption neurons fire less in response to stimulus
• Animal’s behavior correlates well with observed firing pattern