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L7 - Perception Mechanism Inner Ear Hearing, Hearing loss. deafness E flows into
Structure & Function ampulla which
Audition Semicircular canals Detects position n 1. Conductive or middle dear deafness have hair cells,
Sound as a stimulus movement of head Diseases, infection, or tumorous bone the sensory
Saccule growth, prevent middle ear form
Physical stimulus involving movement Utricle Maintains balance receptor of V.S
transmitting sound nerves
Sets off waves of vibration: collisions Normal cochlea n auditory nerve
bet neighboring/nearby molecules Cochlea
Three tunnels Processes sound Can hear themselves clearly.
Medium: air typically carries sound,
sense sound travel through liquids, n Tunnels are Sends signals to 2. Nerve deafness, or inner-ear deafness At top each hair cell is collection of small
solids filled with fluid nerve cells (to the Damage to the cochlea, hair cells, or “hairs” = stereocilia.
Interacts with environment as it travels Hair cells brain) auditory nerve the movement of E causes movement of
(receptor) Nerve cells
to the perceiver Tinnitus -Frequent/ constant ringing in ear stereocilia = release neurotransmitter to
Received through the ears and Pitch Perception Hearing loss send info abt the plane of mvmt to brain
perceived as sound perception Place Theory Various situation that results with
Ex: fabric absorbs sound n surface Each area along the basilar membrane hearing loss V.S uses 2 other organ
reflect sound has hair cells sensitive to only one Old age (otolith organ) to detect
Variation in sound waves determined by specific frequency of sound wave Trouble suppressing irrelevant sounds forward n backward
mvmt n gravitational
Amplitude (intensity) is the height of Frequency Theory Loss if inhibitory neurotransmitters
force
the wave n perceived as loudness. Basilar membrane vibrates in synchrony Attention
High wave as loud n low wave as soft with the sound n causes auditory nerve 2 otolith in V.L: utricle
Attending to name (detect mvmt in
Frequency is the no. of wave cycles axons to produce action potentials at Attending to one person only
per unit of time (Hertz; Hz) n perceived the same frequency. horizontal plane) &
as pitch. low F as low-pitched Individual differences saccule (detect mvmt in
Timbre (complexity) is the distant
The current pitch theory combined modified versions
of both the place theory n frequency theory: Amusia vertical plane)
quality or uniqueness of sound. It is Low F sound best explained by the F theory
“tone deafness”
perceived as the “color”/”quality” of High F sounds best explained by P theory Normal auditory cortex, fewer Within the utricle and saccule, hair cells
tones having = pitch n loudness. Pure connection to the frontal cortex detect movement when crystals of
tones = single F, complex tones made Sound Localization Absolute pitch or perfect pitch calcium carbonate called otoconia shift
up of several frequencies. Compare responses of the 2 ears Genetic predisposition, n early musical in response to it, leading to movement in
Cues for sound localization: training the layers below the otoconia and
Structure of the Ear Sound shadow displacement of hair cells.
Common among individuals speaking
Time of arrival tonal language
Phase difference Somatosensation
Mechanical Senses Sensation and movement.
The Auditory Cortex
Destination where auditory information Vestibular Sensation Discriminative touch, deep pressure,
arrive in the temporal lobe of the brain Detects position and movement of head cold, warmth, pain, itch, tickle, and joints’
Results with compensatory eye position+movement
movement
Whose axons Vestibular Organs Receptor Location Respond to
represent 95% of the
cochlear nerve In the ear, adjacent to cochlear
free nerve pain &
Vestibular System any skin area
ending temperature
V. L
continuous hair-follicle
Ascending - info to brain with hair covered skin Mvmt of hairs
Descending - from brain to
elsewhere cochlea. receptor
Outer Ear V. L contain
Structure Ipsilateral = same side
Contralateral = opposite side semicircular Meissner’s Mvmt across
Pinna hairless area
Most auditory info crosses over.
how, each cerebral hemisphere
canals (tube) corpuscles the skin
Ear canal (auditory canal) processes stimuli from both the I
&C
Functions Advantages: Pacinian vibration /
Brain damage in one any skin are
Protection hemisphere has little effect on
sense of hearing 3 tubes each situated in a plane (head corpuscles sudden touch
Locate sound More processing can rotate) - detect head movement;
Direct sound to middle ear Stops in ascending auditory path nodding, shaking and tilting right n left Merkel’s disk any skin area Static touch
Organ of Corti - Cochlear
Middle Ear nerve - Cochlear nucleus S. C filled with endolymph (when head
Structure and function (cross over C) - primary
second path - some stay at I rotate, causes movement of E through Ruffini endings any skin area Skin stretch
Both cases, the neurons
Tympanic membrane (ear drums) - synapse in superior olivary canal correspond to plane of
complex (brainstem) movement
Sound waves converts to vibrations by Signal continue to relay to
the ear drums lateral lemniscus to inferior Krause end mostly hairless
colliculus in midbrain Uncertain
Ossicles: Inferior colliculus, the infor
relay to medial geniculate of
bulbs areas
Malleus (hammer) Transmit waves Second
primary
thalamus
Some stay at I n move into
Incus (anvil) from middle to cortex auditory cortex
The auditory cortex tucked
Stapes (stirrups) inner ear through into lateral sulcus. Primary
auditory cortex / A1 organized
oval window tonotopically/ frequency
Oval Window
Somatosensation in the CNS Cannabinoids & Capsaicin Through the medulla (nucleus of the
tractus solitarius; NTS) branches out
L8 - Visual System
Information from
touch receptors in the
Cannabinoids-block certain types of
to various areas of the brain Structure
pain, but produce problems such as
head enters the CNS memory impairment. Somatosensory cortex: respond to Structure of the eye
through the cranial Capsaicin-produces temporary touch information
nerves. Insula is the primary taste cortex
Information from burning sensation followed by a
receptors below the longer period of decreased pain respond to taste information.
head enters the spinal Placebos Variation in Taste Sensitivity
cord and passes In medical research, the control group Genetic factors and hormone may
toward the brain contribute to differences in taste
through the spinal receives a placebo: drug/procedure
nerves. with no pharmacological effects. sensitivity.
Each spinal nerve is Shown to relieve pain, depression, and Related number of fungiform papillae
connected to an area anxiety. near the tip of the tongue.
of the body called a Taste Supertasters: higher sensitivity to all
dermatome. tastes and mouth sensations.
Touch experience is Has one function: decide to swallow or
processed in the not. Tend to dislike strongly flavored
primary Taste: stimulation of taste buds; food especially bitter
somatosensory cortex. receptors on the tongue. Pregnant women have higher
Flavor is a perception resulting from sensitivity Fibrous Tunic - superficial coat of the eyeball:
combination of taste and smell. avascular
Information from taste and smell Olfaction
receptors are processed in the same Sense of smell Cornea
area: endopiriform cortex. Response to chemicals that contact the transparent coat covers the colored iris
membranes inside the nose. curved, helps focus light on the retina
Pain Taste Receptors For most mammals:
Taste receptors are modified skin cells. Finding food Sclera
Pain sensation begins with bare nerve Taste receptors are replaced every 10-14 The “white” of the eye, layer of dense
ending. Finding mates connective tissue
days. Avoiding danger
Pain sensitive cells in the spinal cord Papillae: structures on the surface of Covers the entire eyeball except cornea
relay information to several sites in the the tongue Olfactory Receptors Gives shape to the eyeball makes it more
brain. Each papillae may contain up to 10 or Olfactory cells: neurons responsible for rigid, protects its inner parts.
The pain pathway crosses immediately more taste buds, and each taste bud smell, line the olfactory epithelium in the
from receptors on one side of the body rear of the nasal air passages. Vascular tunic - middle layer of the eyeball
contains about 50 receptors. Choroid - Provides nutrients to the posterior
to a tract ascending the contralateral Traditional, there are four types of Olfactory cells has cilia, which has
side of the spinal cord. (Touch olfactory receptors. surface of the retina
receptors known: sweet, sour, salty, and
information travels up the ipsilateral side bitter. Humans have several hundreds of Ciliary body
of the spinal cord to the medulla, and Evidence for 5th type of taste receptor, olfactory receptors. Each receptor Ciliary process
then crosses to the contralateral side.) umami. This receptor responds to responds to only a few stimuli.
Pathway 1: receptor- spinal cord Contain blood capillaries that secrete
glutamate. Olfactory Mechanism aqueous humor
thalamus somatosensory cortex Suggested 6th type is oleogustus, taste Receptors activated by chemicals, will
[Localization] Zonular Fibers:
of fat. trigger changes in G protein, and G Extending from ciliary processes;
Pathway 2: receptor spinal cord protein triggers chemical activities that
thalamus hypothalamus, amygdala, Taste Mechanism lead to action potentials.
Attached to lens
hippocampus, prefrontal cortex and Salty: Saltiness receptor allows sodium Information from olfactory receptors Ciliary muscle
anterior cingulate cortex. [emotion] ions to cross the membrane producing delivered to olfactory bulb. Circular band of smooth muscle that
Pain relief action potential Olfactory bulb sends information to the alters the shape of the lens, adapting
Sour: Sour receptors detect the cerebral cortex. it for near or far vision.
Opioid mechanisms: presence of acid Olfactory Damage Iris - regulate the amount of light entering vitreous
Opiate receptors in the spinal cord Sweet, bitter, umami: Molecule binds to Olfactory receptors are vulnerable chamber of the eyeball through the pupil (hole in
and midbrain. receptor. Activation G protein that because they are exposed to the air the center of the iris)
Endorphins are endogenous release a second messenger in the cell
morphine. Bitter: Bitter taste; wide range of
Average survival of over a month. Retina
Stem cell matures into a new olfactory
Brain produces several types of substance that are toxic. There are a cell in the same location as first and
endorphins, and relieve different number of bitter receptors (30 or more) expresses the same receptor protein.
types of pain. that are sensitive to various toxic If the entire olfactory surface is
Gate theory: chemicals damaged: subject to permanent
Spinal cords neurons receiving Taste Coding in the Brain impairment.
messages from pain receptors also Taste information is sent to the brain via New receptors may fail to make the
receive messages from touch receptors cranial nerves correct connections.
and from axons descending from the
brain. From anterior two-thirds of the Individual Differences
These other inputs “close the gates” for tongue 7th cranial nerve Genetic differences.
the pain messages, which is done partly From posterior tongue and throat Odor sensitivity declines with age.
by releasing endorphins. Example: 9th & 10th cranial nerves
rubbing can reduce sensation of pain Women detect odor more readily than
men.
 In humans, half of the axons from each
Peripheral eye cross to the other side of the brain
Characteristic Foveal vision
vision Most ganglion cell axons go to the lateral
geniculate nucleus, a smaller amount to
Proportion of the superior colliculus, and fewer to
rods increase other areas
Receptors Cones only
toward Primary Visual Cortex
periphery aka area V1, located in the occipital
cortex
Each ganglion Each ganglion The primary visual cortex (area V1)
Convergence of receives information from the lateral
cell excited by a cell excited by
input geniculate nucleus and is the area
single cone many receptors responsible for the first stage of visual
Optic Disc: site where optic nerve exits
the eyeball; Responds well processing
Pigmented layer damage: blindsight= ability to respond
Distinguishes to dim light;
Neural layer: Opponent-Process Theory in limited ways to visual information
Brightness among bright poor for without perceiving it consciously.
3 layers of retinal neurons Suggests that we perceive color in terms
sensitivity lights; responds distinguishing of paired opposites Unaware of visual input
Photoreceptor layer: transduce
light rays into receptor potentials: poorly to di light among bright The brain has a mechanism that Two possible explanation:
lights perceives color on a continuum from red Presence of small area of healthy
Photoreceptor layer: transduce to green and another from yellow to blue
light rays into receptor tissue but not enough to provide
potentials: Good details A possible mechanism for the theory conscious perceptions.
vision because Poor detail is that bipolar cells are excited by one Thalamus sends visual input to other
Rods: each retina has about set of wavelengths and inhibited by areas of the brain
120 mil each cone’s own visions because another
Sensitivity to Ventral and Dorsal Paths
Cones: each retina has about ganglion cell many receptors Limitations of Color Vision Theories
6 mil detail The secondary visual cortex (area V2)
sends a converge their Both - Color constancy, the ability to receives information from area V1,
Bipolar cell layer
Ganglion cell layer message to the input onto recognize color despite changes in processes information further, and
brain lighting, is not easily explained by these sends it to other areas
Fovea / central fovea theories Information is transferred between area
Contains only cones Good (many Poor (few Retinex Theory V1 and V2 in a reciprocal nature
Area of highest visual acuity or Color vision The ventral stream refers to the path
cones) cones) Retinex theory suggests the cortex
resolution compares information from various that goes through temporal cortex
Visual Coding Theories parts of the retina to determine the The “what” path
Visual Coding: Color Vision brightness and color for each area Specialized for identifying and
Fovea
Area of highest visual acuity or The perception of color is dependent Color Vision Deficiency recognizing objects
resolution upon the wavelength of the light An impairment in perceiving color The dorsal stream refers to the visual
Each receptor in the fovea connects to a “Visible” wavelengths are dependent differences path in the parietal cortex
single bipolar cell, which in turn upon the species’ receptors Gene responsible is contained on the X The “how” path
connects to a single ganglion cell that Humans perceive wavelengths between chromosome Important for visually guided
has an axon to the brain 400 and 700 nanometers (nm) Caused by either the lack of a type of movements
The ganglions cells in the fovea are Depends on specific receptors within the cone or a cone that has abnormal
called midget ganglion cells because eye properties Normal behavior makes use of both
each is small and responses to just a Two major interpretations of color vision Most common form is difficulty pathways in collaboration
single cone distinguishing between red and green Damaging either stream will produce
Trichromatic theory/Young- different deficits
Periphery of Retina Helmholtz theory Results from the long- and
Ventral stream damage: can see
More receptors converge onto bipolar Opponent-process theory medium-wavelength cones having
where objects are but cannot identify
and ganglion cells Trichromatic theory (Young Helmholtz theory) the same photopigment
them
Brain cannot detect the exact location or Color perception occurs through the Processing Visual Information Dorsal stream damage: can identify
shape of a peripheral light source relative rates of response by three kinds Rods and cones of the retina make objects but not know where they are
Summation enables perception of fainter of cones synaptic contact with horizontal cells
lights Short-wavelength and bipolar cells
Has better sensitivity to dim light Medium-wavelength Horizontal cells are cells in the eye that
Ability to detect detail is limited by Long-wavelength make inhibitory contact onto bipolar
interference from other nearby objects. Each cone responds to a broad range of cells
wavelengths, but some more than others Bipolar cells make synapses onto
The ratio of activity across the three amacrine cells and ganglion cells
types of cones determines the color Different cells are specialized for
More intense light increases the different visual functions
brightness of the color but does not Ganglion cell axons form the optic nerve
change the ratio The optic chiasm is the place where the
Three kinds of cones are unevenly two optic nerves leaving the eye meet
distributed
Ventral and Dorsal Paths L9 - Motor System Muscle control by Proprioceptors Brain Mechanisms of Movement
Proprioceptors: receptors that detect Cerebral Cortex
Early lack of stimulation of one eye: Control of Movement the position or movement of a part of
leads to synapses in the visual cortex Muscles and their movement the body
becoming gradually unresponsive to
input from that eye All animal movement depends on muscle Muscle spindles are proprioceptors
Early lack of stimulation of both eyes: contractions parallel to the muscle that respond to
cortical responses become sluggish but Smooth muscles: control the digestive a stretch: cause a contraction of the
do not cause blindness system and other organs muscle
CRITICAL PERIODS IN DEVELOPMENT Skeletal/striated muscles: control
movement of the body in relation to the A stretch reflex occurs when
Sensitive/critical periods are periods of muscle proprioceptors detect the
time during the lifespan when environment
Cardiac muscles: heart muscles that stretch and tension of a muscle
experiences have a particularly and send messages to the spinal
strong/enduring effect have properties of skeletal and smooth
muscles cord to contract it
Ends with the onset of chemicals that The Golgi tendon organ is another Primary Motor Cortex
inhibit axonal sprouting Muscle Fibers type of proprioceptor that responds Specific areas of the primary motor
Changes that occur during critical Muscles are composed of many to increases in muscle tension cortex are responsible for control of
period require both excitation and individual fibers Located in the tendons at the specific areas of the opposite side of the
inhibition of some neurons Each muscle fiber receives opposite ends of the muscle body
Cortical plasticity is greatest in early life, information from only one axon but a Acts as a “brake” against Some overlap does exist
but never ends single axon may innervate many excessively vigorous contraction
by sending an impulse to the The primary motor cortex is active when
Long-term consequences of impaired infant muscle fibers people intend a movement
A neuromuscular junction is a synapse spinal cord where motor neurons
vision are inhibited The primary motor cortex “orders” an
Study of people born with cataracts but between a motor neuron axon and a outcome
had them removed indicate that vision muscle fiber Units of Movement
Release of acetylcholine causes the Voluntary & Involuntary Movements Planning a Movement
can be restored gradually, but problems
muscle to contract Reflexes are involuntary, consistent, and Posterior Parietal Cortex
persist Monitors position of the body relative to
Difficulty in recognizing objects Antagonistic Muscle automatic responses to stimuli
the world
Unable to tell that components are Movement requires the alternating Most movements are a combination of
voluntary and involuntary; reflexive and Damage to this area causes:
part of a whole contraction of opposing sets of muscles Difficulty in coordinating visual stimuli
Best prognosis is for children whose called antagonistic muscles nonreflexive
Movements vary with respect to with movement
vision problems are corrected early in Acetylcholine always excites skeletal Trouble finding objects in space
life muscles to contract feedback
Some are ballistic and cannot be When walking they frequently bump
A flexor muscle is one that flexes or
Others raises an appendage changed once initiated into obstacles
Visual Agnosia: The inability to recognize Others are guided by feedback Important for planning movement
An extensor muscle is one that extends
objects despite satisfactory vision Stimulation: results in intention to
Prosopagnosia: The impaired ability to
an appendage or straightens it Sequences of Behaviors move.
recognize faces Fast & Slow Muscles Many behaviors consist of rapid Intense stimulation: results in
Motion Blindness: The inability to Skeletal muscle types range from: sequences of individual movements. believing that they made the move
determine the direction, speed & Fast-twitch: fibers produce fast Central pattern generators are neural Supplementary Motor Cortex
whether objects are moving contractions but fatigue rapidly mechanisms in the spinal cord or
elsewhere that generate rhythmic Plan and organize rapid sequence of
Saccades: Several mechanisms prevent Slow-twitch: fibers produce less movements in a specific order; inhibitory
confusion or blurring of images during vigorous contraction without fatigue patterns of motor output
if necessary.
eye movements People have varying percentages of Example: wing flapping in birds or Active seconds before the movement.
fast-twitch and slow-twitch muscles “wet dog shake” Active following an error in movement so
Slow-twitch fibers are aerobic and A motor program refers to a fixed you can inhibit the incorrect movement
require oxygen during movement and sequence of movements that is either the next time.
therefore do not fatigue learned or built into the nervous system Inhibit incorrect (possibly habitual)
Nonstrenuous activities utilize slow- Once begun, the sequence is fixed movement.
twitch and intermediate fibers from beginning to end Premotor Cortex
Fast-twitch fibers are anaerobic and use Automatic in the sense that thinking Active immediately before a movement.
reactions that do not require oxygen, or talking about it interferes with the Receives information about a target
resulting in fatigue action Integrates information about position
Behaviors requiring quick movements Examples: mouse grooming itself; and posture of the body.
utilize fast-twitch fibers yawning Receives information necessary to direct
a movement toward a target.
Prefrontal Cortex
Active during a delay before movement
Stores sensory information relevant to
the movement
Necessary to consider the probable
outcomes of a movement
Inhibition of Movement Often associated with balance & Substantia nigra usually sends
L10 - Learning & Memory
How do we stop from following our coordination dopamine-releasing axons to the
impulse? More neurons in the cerebellum than caudate nucleus and putamen Learning
Two brain areas are sending competing in all other brain areas combined Behaviors:
Damage to the cerebellum causes Loss of dopamine leads to less
messages; the outcome depends on stimulation of the motor cortex and Reflexes
whether the stop message arrives in trouble with rapid movements requiring
aim/timing slower onset of movements Instincts
time to cancel the action message. Examples: clapping hands, pointing at Genetic factors: especially with early- Learned behavior
Ability to inhibit improves as prefrontal moving object, speaking, writing, onset Parkinson’s Non-associative learning:
cortex matures; peak levels in young typing, playing musical instrument, Exposure to toxins; Insecticides, Habituation
adulthood. sports activity. herbicides, and fungicides Sensitization
Performance deteriorates in old age, the Functions other than movement: Traumatic head injury
prefrontal cortex is highly vulnerable to Associative learning:
Treatment to increase dopamine level
damage. Responds to sensory stimuli even in since dopamine cant’s cross BBB but L- Classical Conditioning
absence of movement. Instrumental/Operant Conditioning
Mirror Neurons Responds to violations of sensory
Dopa can (increase dopamine levels in
Mirror neurons, active during expectations.
basal ganglia - to improve movement Non-associative learning
preparation for a movement and while can cause mvmt-related prob) Habituation: Organism reduces its
Behaviors that depends on precise
watching someone else perform the timing of short intervals; ex. tapping a Huntington’s Diease response to unchanging, harmless
same or similar movement. rhythm with a finger. Begin with arm jerks and facial twitches. stimuli
Active when people smile or see Also important for certain aspects of Tremors spread to other parts of the Sensitization: when repeated exposure
someone else smile. attention, such as the ability to shift body to a strong stimulus increases responses
to other environmental stimuli
Connection from the brain to the spinal cord attention and attend to visual stimuli Genetic cause: autosomal dominant
Mechanism of Synaptic Plasticity
Messages from the brain must reach the Basal Ganglia gene.
A group of large Symptom emerge during middle age: Plasticity: to modifiability of synapses
medulla and spinal cord to control the Strength of connections bet neurons
muscles subcortical Chorea (involuntary, spasmodic mvmt)
structures in the Impaired coordination & balance can increase or decrease as a
Corticospinal tracts are paths from the function of xperience
cerebral cortex to the spinal cord forebrain Muscle rigidity
Two tracts: Caudate Difficulty speaking n/or swallowing Habituation:
Lateral corticospinal tract nucleus Cognitive symptoms (dementia) Repeated stimulation reduce the size
Medial corticospinal tract Putamen Psychiatric symptoms (depression) of excitatory postsynaptic potential.
Globus pallidus Associated with neurodegeneration, or Smaller amount of input from sensory
Lateral Corticospinal Tract the deterioration n death of neurons neurons to the motor neurons.
A set of axons from the primary motor Mutation in a single gene - huntingtin Repeated stimulation depletes the
cortex, surrounding areas, and red Caudate nucleus and putamen receive Dominant mutation - 3 three nucleotides amount of available neurotransmitter
nucleus to the spinal cord input from the cerebral cortex and send (cytosine, adenine, guanine) in repetition in the presynaptic sensory neuron.
Controls movement in peripheral output to the globus pallidus kwn as Trinucleotide repeat. Diminished activity between motor
areas (hands and feet) Globus pallidus connects to the Huntingtin protein gp together n not neurons and muscles.
Red nucleus: a midbrain area with thalamus, which relays information to easily removed by brain enzymes Sensitization:
output mainly to the arm muscles the motor areas and the prefrontal Additional stimulus + single stimulus
Axons extend from one side of the brain cortex Stimulus gains the ability to influence
to the opposite side of the spinal cord, Responsible for spontaneous, self- more than one neural pathway
and control opposite side of the body initiated behaviors. Additional stimulus sensory
Not for stimulus-elicited actions neurons interneurons
Medial Corticospinal Tract Changing lanes when driving, raising
A set of axons from many parts of the hand for question Learning: Synaptic Plasticity
cortex Synaptic plasticity: Control
The medial tract controls the muscles of Movement Disorders Single stimulus Sensory neurons release
the neck, shoulders, and trunk Parkinson’s Disorder neurodegenerative normal amounts of NT
Responsible for bilateral movements Characteristics: muscle tremors,
like walking, turning, bending, rigidity, slow movements, and difficulty Motor neuron releases
Normal response normal amounts of NT
standing up, and sitting down initiating physical and mental activity
Axons of the medial tract go to both Impairment in initiating spontaneous
sides of the spinal cord. movement in the absence of stimuli Synaptic plasticity: Habituation
Cerebellum to guide the action Repeated stimulus Sensory neurons release less NT
Difficulty activating a movement and
difficulty inhibiting inappropriate
movements. Weaken response Motor neurons release less NT
Lack of motivation and pleasure,
depression.
Cognitive deficits: attention, language,
memory.
Caused by gradual and progressive
death of neurons, especially inthe
substantia nigra
Synaptic plasticity: Sensitization Memory Nondeclarative Memory Implicit / unconscious 4. Severe impairment of episodic memory
Additional stimulus
Learning & Memory: as a continuum Procedural Motors skills & procedures He could describe facts (semantic
that includes: Classical Conditioning Association memory) that he learned before the
Stimulus Attention operation.
Sensory neuron release NT Sensation Priming He could describe clear memories for
Perception Exposure to one stimulus changes only two personal experiences.
Sensory neuron subsequent responding to another
Interneurons release NT releases increased NT Steps along pathway of memory Other case of scattered damage in the
processing: Working Memory hippocampus: complete loss of episodic
Memory encoding Working memory (short-term memory) memory.
Motor neuron releases * Brain treats episodic memories
Interneurons increased NT Transformation of input into a (Baddeley & Hitch, 1994).
form the brain can process The way we store information while differently from other memories.
further we are working with it Episodic memories allows for imagining
Stronger than normal the future.
response Memory consolidation The case of H.M 5. Better implicit than explicit memory
Organization of memory The Hippocampus: H.M Explicit memory @ declarative memory
information into more long-term The case of H.M. (Henry Molaison) Deliberate recall of information that
storage Surgeon: William Scoville one recognizes as memory
H.M. suffered epileptic seizures (10
Associative Learning Memory Retrieval
minor seizures/day, 1 major
i.e. state it in words, draw a picture,
Classical Conditioning Recovery of the stored demonstrate that you remember it.
seizure/week)
information. Removal of the hippocampus and Implicit memory
Once retrieved, they become strucutres ner the medial temporal Influence of experience on behavior,
vulnerable to modification cortex. even if you do not recognize that
Needs stabilization through the Reduced epilepsy to no more than 2 influence.
process of reconsolidation. major seizure/year. H.M. became comfortable and
familiar with certain people.
Information Processing Models But resulted with severe memory
6. Intact procedural memory
Sensory Memory impairment.
Leading to discovery of hippocampus Procedural memory
role during formation of memories and Implicit memory: development of
Short-term memory motor skills and habit.
later recall.
H.M.’s memory function Summary
Long-term memory
1. Anterograde & retrograde amnesia Intact working memory, unless
Anterograde amnesia distracted.
Declarative Nondeclerative Inability to form memories for events Severe anterograde amnesia for
that happened after brain damage declarative memory.
Retrograde amnesia Severe loss of episodic memories.
Semantic Procedural
Loss of memory for events that Better implicit than explicit memory
occurred before the brain damage Intact procedural memory.
Episodic Classical conditioning
H.M. is representative of other people The hippocampus
Priming
who suffered amnesia after damage to Theories of Function of the Hippocampus
the hippocampus and surround 1. Critical for declarative memory,
structures of the medial temporal lobe. especially episodic memory (Larry
Sensory Memory
Information sensed enters the sensory 2. Intact working memory Squire, 1992).
Short-term or working memory 2. Hippocampus as a coordination center;
memory brings together representations from
Holds large amounts of data for a brief remained intact, unless he was
distracted various locations of the brain, in the
period of time correct order; allows for recall (episodic
Short-Term Memory 3. Impaired storage of Long-Term Memory
Severely impaired in forming new long- memories include: sights, sounds,
Selected information is further location, series of events).
processed. term memories.
Underestimated his age. 3. Memories with much contextual detail
Operant Conditioning Contains data that we are currently depend on the hippocampus, but older,
Results with an organisms’ naturally thinking. Read the same magazine repeatedly or
work the same jigsaw puzzle less detailed memories depend on
occurring behavior becomes more or Has limited capacity and is temporary. cerebral cortex with less contribution
repeatedly, without losing interest.
less frequency in response to its Long-Term Memory Couldn’t remember his favorite uncle from the hippocampus
consequence. Final destination for information. had died. Hippocampus & Navigation
Reinforcements increase the Few limitations on capacity or duration. Hippocampus is important for spatial
likelihood of the behavior to occur Told his childhood incident and then
retell the story to the same person orientation
again. Declarative memory Explicit / conscious again. Place cells: respond when in particular
Positive & negative reinforcement Semantic Memory Moved to a nursing home in 1980, 4 place, looking in a particular direction
Punishments decrease the likelihood Basic knowledge of facts & language years later, couldn’t not say where he Time cells: respond at a particular point
of the behavior to occur again lived or who cared for him. in a sequence of time
Episodic Memory Failed to learn meanings of new words. Relates to episodic memory
Positive & negative punishment Relates to your own personal Formed few weak semantic memories.
experience.
Episodes of your life.
The Striatum L11 - Motivation & Emotion Maslow’s Hierarchy of Needs Distention of duodenum hormone
Depends on parts of the basal ganglia; Motivation cholecystokinin (CCK) : limits meal size
Biological
the striatum (caudate nucleus and the Google dictionary: motivation: 1. CCK constricts the sphincter
putamen) a reason or reasons for acting or hunger, thirst, muscle between stomach and
Involved in mechanisms for gradually behaving in a particular way. temperature duodenum; stomach hold its
learning habits or learning what Desire or willingness to do maintenance, contents.
probably will or will not happen under something; enthusiasm sex, seek of 2. CCK stimulates vagus nerve to
certain circumstance. “an internal process that modifies the pleasure, avoid send signals to hypothalamus
Long-Term Potentiation (LTP) way an organism responds to a certain pain, etc. produce shorter version of CCK
LTP: one or more axons connected to a class of external stimuli” (Numan & Short -term regulation: limits size of the
dendrite bombard it with a rapid series Woodside, 2010) meal.
of stimuli
Burst of intense stimulation leaves some
Activates and directs behavior toward a 4. Gluucose
goal. Pancreatic hormones: Insulin dan
of the synapses potentiated; making Motivating factors can be:
them more responsive to new input of glucagon
the same time for minutes/days/weeks. Intrinsic Insulin : before, during, after meal,
Properties of LTP Extrinsic enable glucose enter the cells (except:
Both brain cells; enter w/o insulin.
Specificity
Theories on Motivation Hunger Excess glucose, enters liver, converts to
If some of the synapses onto a cell Instinct theory of motivation (William glycogen for storage.
have been highly active and others James): Behavior: eating
Digestion and food selection Glucagon : convert glycogen to
have not, only the actives ones A mother’s protection of her baby. glucose.
become strengthened. Urge to lick sugar Function of digestive system?
Cooperative Mouth esophagus stomach 5. Leptin
Hunting prey
Nearly simultaneous stimulation by Role of associative learning? small intestine large intestine Long-term mechanisms to compensate
two or more axons produces LTP Select food that can be digested. day -today mistakes.
Drive theory of motivation Food selection and behavior Leptin; signals brain about fat reserves.
more strongly than does repeated Deviations from homeostasis create
stimulation by just one axon. Belief that eating sugar makes Fat reserves leptin levels
physiological needs. children hyperactive? T/F Decline leptin eat more, less active
Associativity Results in psychological drive that Eating turkey causes sleepiness? Brain Mechanism
Pairing weak input with a strong direct behavior to meet the need T/F Arcuate Nucleus
input enhance later response to the Fish is brain food? T/F Part of the hypothalamus
weak input. hunger seek out and consume
food Regulation of Feeding There are two sets of neurons
Improving memory Habits: pattern of behavior in brain gets messages from mouth, Sensitive to hunger signals
Drugs to improve memory through LTP? which we regularly engage stomach, intestines, fat cells, etc. to Sensitive to satiety signals
Drugs study in animals: but with Optimal level of arousal (Berlyne, 1960) regulate eating behavior. Input: hormones, insulin, leptin, cells in
unacceptable side effects when applied
to humans. Underaroused: bored and seek out 1. Oral Factor amygdala, basal forebrain, thalamus,
stimulation People taste and chew even when they Hunger signals: Ghrelin
Use of stimulant drugs. Input to hunger sensitive cells.
Overaroused: engage in behaviors to are not hungry.
Increased energy slightly improves reduce arousal Feeding without tasting can lead to Stomach releases ghrelin during
memory and cognition for average or Optimal level of arousal depends on satiety; but with desire to taste or chew food deprivation stomach
below average students, but complexity and difficulty of task something. contractions.
provides little or no benefit and Yerkes-Dodson law Sham -feeding experiment: animals eat Ghrelin signal hypothalamus to
maybe even harm for best students. and swallow almost continually without increase appetite.
Simple task is performed best High production of ghrelin
Supplements: Gingko biloba, Bacopa when arousal levels are relatively becoming satiated
monnieri 2. Stomach response strongly to sight of food,
high. twice likely to become obese
Limited study to support Complex tasks are best performed Signal to end a meal: distension of the Satiety signals from various input
Best recommendations: behavioral when arousal levels are lower stomach Distention of the intestines
methods Self-efficacy Why sham feeding does not satisfy cholecystokinin (CCK)
Study it now, rehearse, periodically Individual’s belief in own capability hunger Blood glucose insulin
test yourself. to complete a task. Why eating satisfies your hunger Body fat leptin
Physical exercise Impacted by previous successful before nutrition reaches any of the Nicotine – decrease appetite
Good nutrition completion of the exact task or a cells
Adequate sleep similar task. Vagus nerve: sends signal to the brain Paraventricular Hypothalamus
Stress managament about distension of stomach Output from arcuate nucleus
Social motives paraventricular hypothalamus (PVN)
Achievement: drives accomplishment 3. Duodenum Certain cells in PVN inhibit lateral
and performance Major site for absorbing nutrients hypothalamus
Affiliation: positive interactions Nerves from duodenum signals about (hunger signals) Arcuate nucleus
Intimacy: seek deep, meaningful distension and type/amount of nutrition (inhibit) PVN (inhibit) lateral
relationships (taste receptors) hypothalamus
Taste receptors: do not provide Inhibition of inhibitor excitation:
conscious experience, but alter brain hunger stimuli increased eating
activity to influence sense of satiety. and arousal
 (satiety signals) Arcuate nucleus Weight Loss Technique Schachter-Singer Two-Factor Theory What is emotion?
(excitation) PVN melanocortins & Obesity considered a disease? Physiological arousal?
glutamate Pros and cons “cognition, feeling, action &
Melanocortin receptors in PVN limit Diet plan? physiological changes”
food intake Consider:
Damages to receptors lead to How long they kept the weight off
overeating How many other people tried the Nervous feel but you don’t know why
Additional pathway: orexin increases plan and failed (no cognition), do nothing about it (no
Lazarus’s Cognitive-mediation Theory action).
persistence in seeking food, increases Techniques:
Arousal appraisal Emotional feelings correlate strongly
activity and motivation. Small changes biological/physical response
Promote good health: with arousal of ANS, no particular
Lateral Hypothalamus Must there be physiological arousal to emotion is consistently association
Output from paraventricular nutrition+exercise
Reduce/eliminate soft drinks. experience emotional feelings? with distinct pattern of autonomic
hypothalamus (PVN) lateral activity
hypothalamus Weight-loss drugs wt S/E Based on James-Lange theory,
Control insulin secretion, alters taste Gastric bypass surgery suggests: Functions of emotion
responsiveness, facilitates feeding in ?!?!: microorganisms in digestive People with weak autonomic 0r Obvious functions:
other ways system skeletal response feel less emotion. Fear alerts for escape from danger
Damage to the area refuse food and Bulimia Nervosa Increasing one’s response enhance Anger directs us to attack an
water Condition which people alternate an emotion. intruder
Stimulation of the lateral hypothalamus between binges of overeating and Research findings: Disgust tells us to avoid something
increases drive to eat periods of strict dieting Damaged spinal cord: no sensations that might cause illness.
Input from taste pathway: alter taste Anorexia Nervosa or voluntary movement: report Less obvious functions: happiness,
sensation and salivation response to Characterized by refusal to each experiencing emotions the same as sadness, embarrassment, others
taste enough to maintain a healthy body before injury. Emotional expressions help us
Sends signals to cortex increase weight. Pure autonomic failure: communicate our needs to others
response to taste smell, sight of food. Emotion Does not react to stressful Understand other people’s needs
Increase pituitary gland’s secretion Google Definition: a strong feeling experience with changes in heart and probable actions
of hormones that increase insulin deriving from one’s circumstances, rate, blood pressure, or sweating. Provide useful guide when we need
secretion mood, or relationship with others. They report having the same to make a quick decision.
Sends signals to spinal cord control “cognitive evaluations, subjective emotions, no difficulty identifying Brain Mechanism
autonomic responses for digestive changes, autonomic and neural arousal, emotion.
secretions. Limbic system: considered critical for
and impulses to action” (Plutchik, 1982) BOTOX: experience weaker than emotion processing.
Medial Areas of the Hypothalamus Motivation? = “an internal process that usual emotional response. Cerebral cortex also reacts to emotional
Output from ventromedial modifies the way an organism responds People with certain brain damage: situations.
hypothalamus inhibit feeding. to a certain class of external stimuli” experience normal emotional Locations of brain activity for each
Damage leads to overeating and weight (Numan & Woodside, 2010) responses emotion varies.
gain Motivation ≈ Emotion ? Physiological arousal Emotions Neurons in amygdala active when
Normal sized meals but more Generally includes components of According to James-Lange theory: perceiving a particular emotion in
frequently: due to increased stomach cognition, feeling, action & physiological emotional feelings result from the someone’s expression.
motility and secretions. changes body’s action: No brain area appears to be specific for
Damage increase insulin production Emotion & Autonomic Arousal Heart racing, sweating, breathing experiencing any particular emotion.
stored as fat. Autonomic nervous system rapidly fear? Do we have few basic emotions? No
Gain weight not necessarily from Sympathetic: “fight-or-flight” Vigorous exercise heart racing, brain area is specific for each emotion.
overeating, but because increased Parasympathetic: increases digestion sweating, breathing rapidly. Basic emotions are studied based on
storage of fat. and processes that save energy and Physiological response alone not facial expression.
Eating Disorders prepare for later events. sufficient for emotional feelings, but Amygdala:
Genetics and Body Weight can impact the feelings.
How do we process emotion? Important for enhancing the startle
Syndromal obesity: reflex and for learned fears
Feel & emotion that changes your Increased heart rate intensify
Gene causes a medical problem that ratings for emotions, for people