Behaviour Notes PDF

Summary

This document provides notes on behaviour, covering topics such as the neuron doctrine, direct and indirect measures of brain activity, brain structure measures, functional measures, and sleep, among other related areas.

Full Transcript

The Single Neuron Doctrine (Horace Barlow)
Barlow: “the best way to study the brain is by single units (neurons)”

Direct measures: directly relate to neurons activity
eg. EEG, MEG and single unit (spike every time neuron fires)

Indirect measures: use a conduit to access neural activity
eg. fMRI measures use of oxygen

Direct Measures

Single unit recordings (extracellular)
Functional
extracellular (space between the neurons)
spiking activity of a neuron

Electroencephalography (EEG)

Measures electrical field
o Right-hand rule
o electrical field vertical spinning
Pyramid cells lined up and become like magnets when stimulated (with a
positive and a negative side)
Advantages:
o excellent temporal resolution (ms)
o better for deep sources than MEG
o lower cost
Disadvantages:
o poor temporal resolution
o skull and tissue not transparent

Magnetoencephalography (MEG)
Direct
Measures magnetic field
o the right-hand rule
o magnetic field horizontal spinning
Advantages:
o excellent temporal resolution (ms)
o skull and tissue transparent
Disadvantages:
o poor spatial resolution
o higher cost

MEG vs EEG
both use the right-hand rule
both have poor spatial resolution and good temporal resolution
 both are direct measures
MEG and EEG source localisation challenge
o done at the scalp (2D surface), but coming from a 3D brain

Do single unit recordings, MEG and EEG measure the same thing?
all direct methods
all seem to produce similar results

Electrocorticography (ECoG) and intracranial electroencephalography (iEEG)
Direct recordings in humans (in severe epilepsy)
Figure out where seizures are coming from using electrode directly on the brain

Brain Damage
Structural-functional method
Changes to behaviour and action
o Then assess brain once deceased
Phineas Gage
o damage: frontal lobe
o problems: inhibitions and HOC
HM
o damage: hippocampus
o problem: memory formation
Tan
o damage: Broca’s area
o problem: speech

Brain Structure Measures

CT
slices of the brain to reconstruct 3D model

MRI
Water molecules are lined up by magnetic field. Radio pulse knocks the
molecules and the rate at which they go back to lined up indicates tissue type.
measures cortical thickness

DiWusion tensor imaging
measures white matter tracts
how areas connect
movement of water in response to magnetic field
o in white matter, water molecules move in a sort of string
Functional Measures
PET
Inject radioactive material (safe)
Determine where radioactive material pooling is in the brain
Don’t need to stay in the scanner, allows for naturalist behaviours
Good spatial resolution
But invasive and radiation exposure

Optical imaging
video taken of the monkey brain
oxygenated blood is red, non-oxygenated is blue
measure red to blue ratio
bluer then red in active area because neurons are consuming more oxygen

fMRI
consumption of oxygen
overcompensation
o rush lots of blood to area of the brain working
o more than what is needed by the brain area

Neural Disruption/Causal

TMS
can get some degree of causation because disrupting brain activity
strong, short, electrical current
magnetic field anticlockwise
magnetic field goes into the brain and creates a mirror electrical loop in the brain

Optogenetics
introduce a virus into neurons and make them susceptible to light to be able to
turn them on or oW
Sleep
Properties of Waveform
Amplitude
Frequency
Phase

Bio Rhythms
Controlled by the brain (eg. heart rate, eating, sleeping)
Complex waves can be broken down into sinusoids (individual waves)
o power spectrum: power of each frequency (ie. power of each wave)

Brain Rhythms: Sleeping vs Awake
Awake: high frequencies and low amplitude
Asleep: low frequencies only, but magnified to higher amplitude

Common Brain Rhythms
High to low wave frequency: gamma, beta, alpha, theta, delta
Alpha
o wakeful relaxation
o the boundary between sleep and awake
o approx. 8Hz
Theta
o transition between sleep and awake
o approx. 5Hz

Functions of Brain Rhythms
The binding problem
o how does the brain connect red ball moving in front of us?
o how does the brain put all this information together when they are from
diWerent parts of the brain
potentially use brain rhythms —> frequency tagging
o signature which tags information
o neurons firing for individual objects
IT neuron RF encompasses smaller V4 neuron RFs
o Direct attention two activate 1 of the smaller V4 neurons, IT neuron is
more active à potentially activating other V4 neurons

Bad rhythms: epilepsy and seizures
Seizure: out of control rhythm spreading across the brain (ie. eWect across the
body)
Symptom of something else going on, not a disease itself
Bio Rhythms
circannual ~ 365
infradian > 24 hours
circadian ~ 24 hours
ultradian < 24 hours

Core functions: breathing and heart rate
controlled by medulla oblongata
monitoring radio of oxygen to CO2 in the body

Sleep wake cycle
regulated by 2 systems:
o homeostatic sleep drive
o circadian rhythm
mutual inhibition of sleep and wake
o once one is activated, the other is inhibited

Sleep homeostasis neural mechanism
Regulated by hormones
Sleep promoting chemical increases (eg. adenosine) and/or wakefulness
chemical is depleted
CaWeine blocks adenosine receptors

Circadian rhythms
controlled by superchiasmatic nucleus
24 hour cycle
the clock is reset by the sun
o cell in the eye is light sensitive and recalibrates the clock everyday

SLEEP PART 2
Why do animals sleep for diWerent periods of time?
- anticipate diWicult periods (eg. extreme environmental conditions)
- reduce metabolism to save energy
- avoid risk (eg. injury, predators)
- vulnerable species appear to sleep less
- predators sleep more

Human Sleep Patterns

REM sleep: memory consolidation, cognitive revitalization? (more REM in childhood)
Non-REM sleep: muscle growth, hormones...
Sleep Cycle Stages

- Stage 1 lasts about 5 mins
- Stage 2:
- sleep spindles: memory consolidation
- k-complexes: reawakening (sleeping with one eye open)
- able to hear a noise in the room
- make sure that your safe
- stage 3:
- growth hormone released during this stage for repair
- less important for older people
- people over 65 rarely enter deep sleep
- after sleep deprivation people spend a greater proportion of time in deep sleep
- REM sleep
- consolidation of memory and assists in problem-solving
- occurs in 90-120 minutes
- rapid eye movement, vivid dreams, muscle paralysis

Why sleep is important

Psychomotor vigilance task (PVT)
- click the screen when the dot blinks
- when people are sleep deprived, perform worse at this task (miss the blinking light)
- sleep deprivation is additive

Hormonal Function

- glucose to be cleared out of our system
- glucose clearance is less for those with restricted sleep

Immune Function

- development of antibodies to the hepatitis vaccine
- those which were denied 1 night of sleep after the injection
- roughly half the antibodies compared to the normal sleep control

Cleaning your brain

- beta amyloid - plaques in the brain linked to alzheimers
- greater clearance of AB plaques during sleep

Emotional Balance
- sleep group had greater ability to remember pos/neg images compared to the sleep
deprived group
- positive images recognition significantly decreases compared to the negative images
in the sleep deprivation group

Mental Health
- apnea: throat relaxes and closes, resulting in the body waking them up
- does depression cause apnea or does apnea cause depression
- depression given sleep apnea (apnea causing depression)
- CPAP: small pressure in airway to prevent collapse
- depression scores go down after CPAP

INFORMATION PROCESSING SYSTEM

Claude Shannon: Information Theory and EWicient Coding
Low information
o receiver knows what will be sent
High information
o receiver unsure what will be sent
Some signals can be eWiciently encoded as there are elements that can be
compressed

Encoding sensory information
rod photoreceptors
o grey scale
cone receptors
o colour
o blue, red and green
extremely sensitive to the diWerence between red and green
o adaptive function to distinguish between red and green
o take in information to have maximum utility (eg. Apple on tree)

EWicient Encoding: Receptor Density
higher cone density in the fovea
o high definition is restricted to gaze
undergoes compression before entering the optic nerve (125 million inputs, 1.1
million axons in the optic nerve)
simple retinal circuit (1:1, receptor to neuron)
convergent retinal circuit (7:1, receptor to neruon)

Bayesian Framework for Understanding Perception
Thomas Bayes
what we see = input and HOC
evidence + knowledge about the world —> what is being perceived
Example: knowledge that light comes from above
 Fovea is reliable, but the peripheral is not as much
o uses priors to clean up representations

Marr’s Levels of Explanation
Computational theory: what is the goal of the system
Representation and algorithm: what are the steps to reach this goal
Hardware implementation: how to physically accomplish this task biologically
and mechanically

Representations and Processes
Eg. Mental rotation
o people were mentally rotating the object it in their head (ie. the process)
Representation: stored information in a particular format
o not all representations are the same (eg. array of number for computer vs
light intensity for humans)
o good ones make information explicit:
Process: an algorithm that changes the form of the representation
Reconstructing brain representation from behaviour
o eg. similarity between girl, boy and man varies
§ representational space: construction of a map about
closeness/distance
o can measure representational structure in the brain using fMRI
o time varying representational structure with MEG
§ how change as a function of time

MAPS AND MODULES

Receptive Field and Features
Features = what the brain is encoding
Physical features
o orientation
o spatial frequency and contrast
o speed and motion direction
Higher order features
o face identifies
o emotions
o biological motion

Retina à LGN à V1 à V2 à V3 à V4 à IT
Receptive field larger as you go up the visual hierarchy
More high-level features as moving up visual hierarchy
Wiring of Receptors

Convergent circuit
More neurons stimulated à greater firing rate

Centre surround circuit à SPOT DETECTORS
Some neurons are inhibitory à reduce firing rate when stimulated
Centre surround organisation in LGN and retina

Building features (edge detectors) from features (dot detectors)
Many spot detectors (using centre surround organisation) to build edge feature
(edge detectors)
Spot detectors (in LGN) to edge detectors (V1)
o V1 neurons create image of + detecting area and - detecting area at a
particular orientation (eg. 45 degrees)

Orientation coding eWect (tilt after eWect)
When you stare at one orientation, neurons sensitive to that tilt get tired, you see
the other image tilt the other way are they don’t have the energy

Maps
Various types of maps
o eg. visual, somatosensory, auditory
Organisation of information in the brain (ie. what is encoded in which location)
tells us what information is important
Vision gets a lot of real estate in the brain à important
o 17-22 retinotopic maps in the visual cortex

V1 Map
Right or left eye
Orientation

Beyond V1
Complexity and size of visual field increases as moving to more higher order
representations
Modular areas become more prevalent in higher order areas
o maps more prevalent in lower levels
Map = cluster of neurons with similar functional properties
o gradual progression of stimulus across the cortical sheet???
Module = cluster of neurons with similar functional properties
o discrete regions with clear boundaries
o eg. modules relating to faces, scenes, food
o still can contain maps of the visual field
§ retinotopically organised but more aligned with function
Visual Processing of Objects
fMRI Adaption
Normal fMRI
o area will activate whether shown big or little car because neurons for big
and little cars coded in the area
§ does it care about the size of the car? = size invariance
o how do you determine whether size is considered by a subsection of the
area when spatial resolution is bad in fMRIs? —> fMRI adaption
fMRI adaptation
o repeated exposure to stimulus will result in neural adaptation
o little car —> little ca: area will show less activity as “small car” neurons
are tired
o small car —> big car: area will show same activity if neurons are diWerent
to “small car”
fMRI adaptation allows us to determine whether neurons within areas have
multiple functions despite limited spatial resolution of fMRIs

Object Representation in LOC
Do diWerent areas of the brain care about diWerent (aka invariant) features?
o location in visual field
o size
o image format
o visual or tactile input
Lateral occipital complex (LOC) processes high level object shape
representation
o LO (lateral occipital) subdivision: sensitive to changes in location and size
§ more sensitive to 2D shape features
o VOT (ventral occipital temporal area) subdivision: sensitive to changes in
location
§ more invariant to location and size than LO
§ bigger receptive fields and more abstract concepts
§ sensitive to perceived 3D shape
§ VOT closely linked to recognition/perception
§ eg. activity in V1 not related to ability to recognise a cat, but
VOT is
§ ie. category labels of cat, boat, dog, house etc.
o VOTV (ventral occipital tactile visual area) subdivision: activated by both
visual and haptic input
§ multimodal
Experiment
Trained people to use auditory cortex to identify things in images
Recognise visual images by soundscapes (OIC objects)
o can identify novel images
LOTv activated by vOICe objects (haptic and visual convergence)
Disorders of Object Processing
Visual agnosia = a failure to make sense of visual information (to know what it
represents)
Elementary visual function intact
Can’t recognise objects

Apperceptive agnosia (construction issue)
Damage to perceptual processing system
o can physically see shapes but can’t make sense of the input
Bilateral damage in occipital lobes
o can’t:
§ copy drawings
§ match objects
§ read
§ recognise faces
§ judge size or orientation
Case of DF
o Lesions above LOC
o Can: change hand shape and orientation to correctly grab an object
§ Indicates dissociation between perception and vision for action
(eg. can’t “tilt envelope to fit the slot” but can “post the envelope”)

Associative Agnosia (labelling issue)
Damage to recognition system
o can physically see shapes and make sense of input but cant
label/recognise (eg. dog)
Can copy drawings, discriminate shapes
Cannot identify objects
Cause?
o disconnection between intact perceptual input and memory (peripheral)
o loss of stored object representations (central)?
Types
o visual object agnosia: inability to recognise objects
o prosopagnosia: inability to recognise faces
o alexia: inability to recognise words
o topographical agnosia: inability to recognise familiar environments
Lesions tend to be bilaterally in VOT
o objects and words more in the left hemisphere
o faces more in the right hemisphere

The Logic of Dissociations in Neuroscience
Simple dissociations
o patients can do A but not B
o could conclude that A and B tap into diWerent (and independent
processes)
o BUT this could be due to diWerence in task diWiculty
Double dissociations
 o one patient can do A but not B
o one patient can do B but not A
o much more powerful evidence that A and B are independent

Cognitive Neuroscience vs Cognitive Neuropsychology
Cognitive neuroscience = aims to understand the relationship between brain and
mind
o what are the neural substances of cognitive processes?
Cognitive neuropsychology = aims to understand the architecture of the normal
cognitive system
o functional systems in the brain
Language
Studying Language
Phonemes: individual smallest meaningful sounds/letters
o eg. fox/socks/box
Phonology: patterns of speech and language sounds
Syntax: combining words into sentences
o eg. subject + verb + object
Semantics: meaning of words
Pragmatics: social aspect of language interaction
o eg. do you know what time it is?
§ yes OR it is 10am
Comprehension
Acquisition
Production

Theories of Language
Nativism: Noam Chomsky
Humans are born with an innate ability to learn language through language
acquisition devices (LAD)
Universal grammar: certain grammatical structures and rules are innate in all
human language
Example of Nativism
Fake/impossible language
Broca’s area activation for the real language condition higher than for the fake
language conditions when accuracy was high

Linguistic Relativity: Sapir-Whorf
Structure of a language aWects its speakers’ cognition and worldview
Two main versions
o strong: language determines thought and cognitive processes
o weak: language influences thought
Examples of Linguistic Relativity
Colour perception: Russian speakers, who have separate terms for light and dark
blue (goluboy and siniy), are faster at distinguishing between these shades
compared to English speakers, who use a single term for blue.
Spatial orientation: In some cultures, languages rely on absolute directions
(north, south, east, west) rather than relative terms (left, right). For example,
speakers of the Guugu Yimithirr language in Australia use cardinal directions for
all spatial references, which influences their navigation and spatial cognition.
Embodied Cognition
The mind is influenced by the physical and sensory experience of the body
o cognitions, including language, are activated in the brain as if they were
occurring
§ eg. thinking about running activates these areas in the brain (motor
neurons)
§ eg. feel diWerent when thinking about relaxing compared to
thinking about climbing or running
Understanding language involves simulating the sensory and motor experiences
associates with the words and phrases we hear
Examples of Embodied Cognition
Action Words: When people hear or read words related to physical actions (e.g.,
"kick," "grasp"), there is activation in the motor areas of the brain associated with
performing those actions.
Spatial Metaphors: Language often uses spatial metaphors to describe abstract
concepts (e.g., "up" for happy, "down" for sad). Understanding these metaphors
can involve bodily simulations, such as physically leaning forward when thinking
about the future.

History of Language in the Brain
Paul Broca
Patient could only speak a single word (”tan”) but could understand language
perfectly
o lesion in the left frontal lobe (Broca’s area)
Non-fluent, expressive Broca’s aphasia (video)
o major disruption is speech production
§ problems with syntax (not able to produce a correctly structure
sentence)
o comprehension intact
o main retain some use of nouns and verbs
o loss of pronouns
Carl Wernicke
Patients could speak fluently but the speech was nonsensical and could not
comprehend/understand language
o lesion in posterior part of the super temporal gyrus (Wernicke’s area)
Wernicke’s Aphasia
o major disruption in auditory comprehension
o comprehension NOT intact
§ not answering questions asked
o fluent speech, normal rate, rhythm and intonation
o disturbances of sounds, structures of words
o semantic substitutions or paraphasia
§ eg. television to velitision
o poor repetition and naming
Electrophysiology
N400: The Neural Marker of Semantic Processing
What is N400?
o event-related potential (ERP): brain activity at time of semantically
non/sensical word
§ compared with one another
o reflects the brain’s response to semantic abnormalities
§ eg. she spread the bread with socks
When does N400 occur?
o ~400 ms after the presentation of the non/sensical word or stimulus —>
ERP
Features:
o latency: ~400 ms after stimulus onset
o location: usually left centro-parietal electrodes
P600: The Neural Marker of Syntactic Processing
What is the P600?
o event-related potential (ERP): brain activity at time of synaptically
non/sensical word
§ compared with one another
o reflects brain’s response to syntactic abnormalities and garden path
sentences
§ eg. the cat will eating the food
§ eg. the horse ran past the barn fell
When does the P600 occur?
o ~600 ms after the presentation of the non/sensical syntactic or
grammatical structure violation —> ERP
Features
o latency: ~600 ms after stimulus onset
o location: usually centro-parietal electrodes

Current Models of Language in the Brain
Left hemisphere is dominant for language in 90% of people
o small % of left handed people have right hemisphere dominant

Cortical Regions
Occipital cortices (visuospatial): handle attention and recognition language and
speech input
Parietal regions: angular and supra-marginal gyrus work in concert with auditory,
visual and motor inputs
Frontal and temporal regions: provide linking of words to form sentences and
coordinate motor functions such as moving the arms, legs and mouth

Subcortical Regions
 Basal ganglia: role in phonological processing
Putamen: rhythm with speech and sounds and semantic access facilitation
Globus pallidus: conscious movements working in concert with other
corticostriatal loops (IMPORTANT)
Caudate: syntax and working memory
Thalamus: phonetical and morphology or words
o e.g. the core root of a word

Language Process Control
Bottom-up processing
o response to external environment
o updated response to environment once information is interpreted
o occipital and parietal brain regions involved
§ eg. reading text or listening to words
Top-down processing
o internal response, perception and understanding
o feedback to bottom-up areas for response
o temporal and frontal brain regions involved
§ eg. comprehension of words, test and subsequent reactions

Duel Stream Model: Frederici
Two streams (dorsal and ventral) each with two pathways
Dorsal pathway 1: connects temporal cortex with premotor cortex
o function: map sound to motor action (for speech repetition) and
phenological processing
Ventral pathway 1: connects temporal cortex to the anterior inferior frontal gyrus
o function: semantic processing
Ventral pathway 2: links the anterior superior temporal gyrus (STG) to the frontal
operculum
o function: local structure building
Dorsal pathway 2: connects the posterior of Broca’s area with the posterior STG
o function: complex hierarchical sentences
Computational Brains
Reductionism
= the practice of analysing and describing a complex phenomenon in terms of its
constituents (ie. smaller parts), especially when this is said to provide a
suWicient explanation
o Barlow’s neuron doctrine: best to study brain in terms of single neurons
and what they do
Explanation
Explanation often requires an account of how the parts work together
o reductionism does not do this
To understand behaviour or experience we do need to know something about
what the brain is doing, but do we need to know what every ion is doing?
o consider what scale should be assessed depending on the question
o neuroscience vs psychology level questions
§ psychology —> explaining behaviour and conscious experience
(eg. how can you recognise a smell)
§ neuroscience —> (eg. how to strop hyperactivity in seizures)
Emergence
= what the parts are made of is not very important, rather, it is the
relations/interactions among parts that is important
o eg. what the cogs on a bike are made of doesn’t matter, it is the relative
size of the cogs that does
Computational neuroscience is based on the idea that behaviour and experience
are emergent
Unpredicted emergence = when the interactions among may parts yield
behaviours that are hard to anticipate
o eg. cyclone would be hard to predict as a possibility based one what is
known about air molecules
o eg. large language models
§ initially programmed to determine which word i most likely to
come next
§ researchers realised it can be asked questions —> unpredicted
emergence

Computational Modelling
Assumes behaviour and experience are emergent
We should be able to build something that accomplished the target behaviour
Seeks simple explanations of behaviour and experience
o as simple as possible whist still satisfying #2
Copies aspects of the brain as its building blocks
o typically uses a simplified neuron as its basic building block
Modelling and Simulation
Build something which mimics the thing we are trying to understand
Strips away irrelevant detail
o eg. rather than focus on how long the wires are on a computer board,
focus on connections
o eg. rather than making model of plane from actual material, using a scale
model of an airplane made of plastic in a wind tunnel

Metaphors to Model the Mind
1st Century: wax tablet —> memory
o impressionability
17 Century: Coo-coo clock
o how parts interact to produce an action
20th Century: Computer
o Programmed with a series of steps and diWerent functions done by
diWerent modules
§ eg. attention
§ enhance
§ inhibit
§ engage
§ disengage
§ move
o Problem: neurons have multiple functions, thus, does not represent the
brain function
21st Century: Connectionist Networks
o Invented to mimic aspects of the brain
§ eg. large language models like chat GPT

Level of Simplicity
Modelling how brains complete tasks not how they can be completed
o example: alphabetising a word list can be done in various ways, but we
want to explain how we do it

Explaining Behaviour
One or two neurons can allow reflex or Pavlovian learning
Several neurons can form connectionist (PDP) networks for word or concept
recognition

Simple Neuron Connections
Synapses between neurons are modelled by “weights” or “connections”
Important for information processing
o Excitation or inhibition at synapse
o Threshold activation rule (whether the neuron becomes active and send a
signal to another neuron)
Linear activation rule: simply pass on the overall votes/stimulation
Linear is not enough for decisions

Threshold activation rule: stimulation > threshold —> activation
a function emerges from activity of many units interacting

Parallel Distributed Processing (PDP) Network
There is no “bird” category in the brain, rather it emerges from the overlap of all
bird type instances
Strengthening of connections
o by learning statistical relationships
o birds strongly associated with having feathers but less strongly with
running
Brain vs PDP
o brain has interference (eg. previous grocery lists eWecting current grocery
list) and generalisation (eg. generalise to new grocery list based on
regularities previously)
o PDP computer has no interference (eg. only works with input) and no
generalisation

Connectionist vs Computer Models
Connectionist Model
o memory stored in connections
o computing occurs in connections
o prone to interference
o generalises
o flexible capacity limit (interference as memories accumulate)
§ you don’t realise the neuron memories/connections that weaken
as you absorb new ones. You maintain the key ideas from older
knowledge/memories and add them to new ideas
o more units (ie. neurons)
o continually adaptive
o graceful degradation
Computer Model
o memory stored in one area
o computing occurs in one area
o no interference
o no generalisation
o once its full, its full
o speed or messages and computation is faster
o catastrophic failure from minor injury
Example: computer must consider all 200 million chess positions per second to
beat grand master at chess
o brain works smarter not harder
o computer now wins, but does task in diWerent way than humans
Why do our brains never seem to be full?
Individual memory distributed across thousands or millions of synapses
You don’t realise the neuron memories/connections that weaken as you absorb
new ones
o you maintain the key ideas from older knowledge/memories and add
them to new ideas
Thus, you never have a limit, rather your constantly degrading/losing old while
making new
We also make new synapses and neurons

Moravec and Polanyi’s Paradox
Moravec’s paradox
o Perception, movement: Easy to us, Hard for computers
§ sensorimotor skills require enormous computational resources
o Reasoning: Hard for us, easy for computers
Polanyi’s paradox
o Our brains know a lot about perception and locomotion, but “we” don’t.
Result: We’ve been slow to be able to make robots that can perceive the world
and walk around.
Rodney Brooks: we must start with sensing and action and leave out the
“intelligence” part
Representing Space
Coordinate Frames
Hippocampus important for memory of large scale areas
Allocentric: things are relative to an external reference
o eg. north pole
Egocentric: things are relative to you
Need diWerent coordinating frames for diWerent actions
o Eye-centred
o Body-centred
o Head-centred
o Hand-centred
Constantly need to update coordinated as map changes often
o various parietal areas which are not retinotopic are involved
Looking: Move eyes 15 degrees to left
object relative to eyes (15 degree diWerence)
o retinotopic map
o angle specified by which neurons stimulated by cube

Walking: Rotate body 30 degrees to right
object relative to eyes (15 degree diWerence)
eyes relative to head (0 degree diWerence)
head relative to body (45 degree diWerence)
= 30 degrees to right

Reaching: Move hand 22 degrees to right
object relative to eyes (15 degree diWerence)
eyes relative to head (0 degree diWerence)
head relative to body (45 degree diWerence)
hand relative to body (8 degree diWerence)
= 22 degrees to right

Calculating Eye Angle Relative to Head

Gaze Angle
Needed for direction of pointing, walking etc.
When retinal motion detected, did eyes or object move?
o direct sensing of eye position (via proprioception)
o remember where you told your eyes to move (eWerence copy)
§ most evidence suggests this is how we know this

Eye Movement Commands
Eye movement command (eWerence copy) gets sent to parietal cortex to:
o Update representations of where things are
o Compensate for retinal motion, so you don’t perceive world to move when
your eyes move
Space and Body
Location calculated on-the-fly each time object is attended?
Using cues in visual field (eg. hand location) may reduce need to calculate
orientation of eyes relative to head

Parietal Lobe Function
Uses sensory signals for
o Calculating position of body parts relative to objects
o Representing space for consciousness
Uses location information for
o Calculating position of body parts relative to objects
o Location information for awareness
o Location information for action (dyspraxia)
§ Ocular apraxia = does not scan visually
§ Optic ataxia = deficit of reaching under visual guidance
Brain Injury
Injury to left lobe —> right side eWects
Stroke —> Hemiparesis
o weakness of one entire side of body
o neurons unable to tell side of body what to do
Stroke —> Hemispatial neglect
o can see visual field but unable to process it
o deficit in attention
o patient does well on standard vision tests (not hemianopia)
Stroke —> Hemianopia
o blindness of one visual field in both eyes
Bilateral parietal injury
o Simultanagnosia
§ only one object perceived at a time
o Motion creates stronger visual signal
§ able to reach more accurately
Dyspraxia = disorder of movement
o Due to perceptual problem
§ reduced ability to coordinate movement
§ ie. plan for how to get hand to a visual location
o Not due to weakness, inability to move, abnormal muscle tone, motor
deficits
Spatial Memory

Dorsal Stream: egocentric (where/how)
Uses parietal and visual areas

Ventral Stream: allocentric (what)
Uses allocentric memory

Memory stored in allocentric coordinates but is projected into ego-centric coordinates.
When allocentric, all information is intact (eg. can remember shops on both sides) but
when projected to ego-centric, hemispatial neglect can continue (eg. can only name
shops on left side but when standing opposite direction can name shops of right side)

Visual Processing Without Parietal Function
eg. house on fire
o but is smoke recognised as smoke? Or do they just prefer the more
symmetric house?
Stroop Experiment (Berti, Frassinetti, & Umilta, 1994)
o normal people
§ slower for incongruent
o Hemispatial neglect
§ report nothing on the left
§ still slower for incongruent —> processing words
Brain imaging of processing of unperceived stimuli
o unseen faces activated right visual cortex (V1) and inferior temporal areas
§ weaker than seen faces

Coordinate Systems for Cognition and Recognition
“What” requires spatial information
o object recognition sometimes requires translation of retinotopic sensory
signals into a stimulus-centred or object-centred representations
§ eg. recognise feet event when person upside down
o processing shapes
§ stimulus-centred: direction of arrowhead relative to centre to
determine which direction pointing
o processing words
§ object-centred: which letter is first
§ unconsciously process left side of mirrored word even
when cant process left side of normal word
§ eg. words: need to know which letter is first, second ect.
even for unusual orientations
Synaptic Plasticity: Mechanisms of Learning

Hebbian synapse
models how connections between a conditioned stimulus and a unconditioned
response are strengthened when there is co-occurrence of the US and the CS
resulting in the UR. This is the basis of which LTP is modelled oW.

Synaptic plasticity in the hippocampus
hippocampal formation = hippocampus proper (CA1, CA2 and CA3) and the
dentate gyrus
o critical for learning and memory
neural circuitry in hippocampus segregates inputs and throughputs
o easy to measure stimulation of single neuron from a single synapse
o ie. if measuring output in perforant path and input in dentate, you can
know it is monosynaptic

Entorhinal cortex à perforant path à dentate gyrus à hippocampus proper

Long term potentiation (LTP)
LTP is a physiological example of synaptic plasticity
o potential as a model for neural mechanism of learning

Step 1:
weak stimulation of presynaptic input (in performant path) which causes little to
no activity in post-synaptic neurons (in dentate)
Step 2:
strong high-frequency stimulation of pre-synaptic input causes long lasting
increase in sensitivity of post-synaptic neurons
Step 3:
weak stimulation of the pre-synaptic input now produces action potentials in the
post-synaptic cells

LTP is “dose dependent”
weak HFS in step 2 —> short-lived potentiation (10 mins)
strong HFS in step 2 —> long-lasting potentiation (hours)
HFS is usually continuous but can also get result using patterns of short bursts
(ie. theta burst stimulation, TBS)
o duration of LTP depends on number of TBSs

Long term depression (LTD)
plasticity is bi-direction
low frequency stimulation can reduce synaptic eWicacy
may be mechanism of inhibition?
but can contribute to excitatory behaviour
Properties of LTP suggesting it as a model for learning and memory
1. persistence
o long lasting and enduring
2. synaptic specificity
o only stimulated pre-synaptic inputs show potentiation
o ie. no increased sensitivity to other pre-synaptic input
o —> learning is specific
3. associativity
Associativity of LTP
can get LTP when weakly stimulate one pre-synaptic input at the same time as
strong stimulation to a seperate but converging neurons
resembles Hebb’s model for how associations are acquired by the NS

Do LTP and learning share a common mechanism?
1. Correlations between LTP and learning
o Age-related decline in learning correlates with age-related decline in
induction of LTP in hippocampus.
o Similar correlations between LTP and learning in mouse model of
Alzheimer’s Disease.
2. Saturation of LTP
o Evidence of saturation of LTP in hippocampus impairs learning
3. Learning and LTP share common neurochemistry
o Pharmacological interventions that prevent LTP (block NMDA receptors)
also disrupt learning.
§ Conditioned Taste Aversion;
§ Conditioned Fear;
§ Conditioned Eyeblink;
§ Maze learning.
Neurochemical Basis of LTP
LTP and Glutamate
1. Glutamate binding to AMPA receptors
o glutamate released from pre-synaptic terminal
o binds to AMPA on post-synaptic neuron
o causes excitation (depolarisation)
§ fast excitatory post-synaptic potentials (EPSPs)
2. Glutamate binding to NMDA receptors
o receptors are both ligand gated (glutamate) and voltage gated
(depolarised) - dual gated
§ allows for SYNAPSE SPECIFICITY
o release Ca2+ into the neuron which increased AMPA activity and number
of AMPA receptors
§ more likely to produce an AP
Intracellular Changes Triggered during LTP
Initial Learning into Long-term Memory Process
1. Generating synaptic change
2. Stabilising synaptic change
3. Consolidating synaptic change
 4. Maintaining synaptic change
Generating synaptic change (~1 min)
Post-translational changes underlying LTP
Post-translational = rapid changes
Use existing proteins to create association but unless other processes are
activated, association will be lost (ie. it is transient)
May explain why recent memory traces can be disrupted by head trauma
o eg. concussion causes amnesia for events that occurred a few minutes
before an accident
Constitutive tra^icking and recycling of receptors
Constitutive traWicking = receptors (AMPA and NMDA) on dendritic spine are
recycled constantly and form new receptors
Calcium ions (released from NDMA receptors when glutamate binds) activate
protein kinase enzymes which increase rate of constitutive traWicking
o enzymes are also activated which break down existing protein structure
(the cytoskeleton made of actin filaments) and then rebuild it - help to
maintain elevated traWicking
o eventually return to normal rate
Stabilising synaptic change (~10-15 mins)
Cell Adhesion Molecules
Cadherin monomers (weak adhesion form) align pre- and post- synaptic
terminals
Calcium ions (released from NDMA receptors when glutamate binds) cause
change into cadherin dimers (stronger adhesion form)
o aka calcium dependent adhesion molecules
Consolidating synaptic change (2-4 hours)
Translational and Transcription Processes (Protein Synthesis)
Need to generate new AMPA proteins to maintain constitutive traWicking???
Strong HFS (or theta burst frequency) produces LTP
LTP requires translational processes (protein synthesis)
o drug that blocks protein synthesis can prevent LTP
§ no eWect on STP
Local translation of mRNA: synthesis of AMPA receptors occurs in the dendritic
spine (in ribosomes)
o if disconnect soma from dendritic spine, can still get some LTP
o thus, translation does not need to come from ribosomes in soma, rather
can come from ones in dendritic spine
o but most mRNA does come from ribosomes in the nucleus
Transcription of mRNA in nucleus:
o mRNA from nucleus to supplement mRNA in dendrites
o calcium ions (entering voltage-gated ion channels) activate transcription
of mRNA in nucleus
Spine Growth
Sustained synaptic activity leads to enlarged dendritic spine
o larger surface area
o more receptors
o more eWective and spable
 Triggered by brain-derived neurotrophic factor (BDNF) and transcription of
mRNA.
New cytoskeleton created supports traWicking of extra AMPA receptors
Small spines learn; large ones remember
Maintaining synaptic change (4+ hours)
Self-Perpetuation
AMPA receptor contains GluA1 subunit
sustained synaptic activity results in GluA1 being replaced by GluA2
o GluA2 is more stable but doesn’t support further potentiation
o GluA2 uses a type of protein kinase which is self-activating to increase
constitutive traWicking

Where might we find changes in strength of synaptic connections underlying leanring?
are these changes local or global?
in keeping with localisation of function in the brain, diWerent types of leaning.
appear to be localised in diWerent parts of the brain
Hippocampus and cerebellum
Hippocampus and spatial navigation

morris maze
o using extra maze cues
o form representaiton of spatial lay out
brain imagind studies in spatial navifation in humans
o activation of hippocampus while people nastivagate virtual town on
computer
Hippocampal Place cells
neurons that become active (fire) when rat is in a specific location in
environment
allocentric reception field: organisational structure of space defined by relations
among objects rather than with reference to observer (eg. receptive field in visual
cortex)
o receptive field based on external relations
o doesnt care which way rat is headed, speed, ie. NOT egocentric
place cells in CA1-CA3 region and dentate gyrus
INPUT: sensitive to visual input
o but place cells continue to show spatial firing in dark, and congenitally
blind rats have place cells
o olfactory and tactile (whisker) inputs also influence spatial pattern
Location specificity
 a single place cell is stable and spefic within a particular environment but can be
active in >1 environment
individuals cells do not uniquely code for a location, patter of activity across
multiple cells does
place cells tend to be non-directions (active in location regardless of rats
direction)
place cells form a cognitive map of environment
o activity of cells can predict animals navigation through maze and even
predict its errors
o allows to take novel path on familiar paths
Learning about Place
place cells establish spatial pattern within few minutes of being introduces to
novel environment and can maintain this pattern for dags or even several months
place rats into 2 similar enclosures. place cell patters were initally very similar,
but after many exposures overl several weeks, the patterns began to diverge
o learn discrimination between places
Grid cells in medial entorhinal cortex (MEC)
inputs to hippocampus come from entorhinal cortex
grid cells in MEC: provide building blocks for allocentric representation
many neurons in MEC respond to rats position but follow a lattice or grid
the grid pattern of a single cell can cover a large area and the cell will show same
grid across diWerent environments
grid cells keep exact grid layout despite changes in speed or direction of rat
therefore, not about encoding particular places, but rather provide coordinate
frame for any space
pattern arises from in
diWerent spacial frequency
o small patches —> big patches
pattern arises from the ways that the cells are connected in the MEC
o eg. short-range excitation between cells and long range inhibition
o phasic activity
o range determined spatial frequency of the field
§ large —> large

compared to a place cell, grid cells provide ambiguous information about
location
o ie. rat could be at any one of the many locations where activation strength
is repeated
o ie. wouldn’t be in empty patches but unsure where on grid
ambiguity solved if take into account multiple grid cells and how they are firing
o due to diWerent spatial frequency and phase
o eg. able to tell diWerence between diWerent coloured stars

MEC (grid cells) —> hippocampus (place cells)
So what does the hippocampus do?
creates allocentric maps of space and time
episodic memories
o spacial and temporal context is fundamentally important for many other
types of learning and memory (especially episodic)
o allocentric representations in episodic memory
Cerebellar Contributions to Learning
cerebellum (Cb) has clear role in learning motor skills
complex and intricate structure of cerebellum allows integration of sensory
inputs for precise timing and sequencing of motor functions
organisation of cerebellum
cell types
o granule cells (input)
o climbing fibres (input)
o purkinje cells (output from cerebellum)
climbing fibre smothers purkinje cell (1:1 connectivity)
granule cells and purkinje cells (1: many and many:1)
o thousands

Cerebellar Learning
Eyeblink conditioning in rabbits
o noise (CS) followed by airpuW (US)
o US normally causes eyeblink
o eventually CS —> UR/CR
o timing of eyeblink is very precise to milliseconds before airpuW
§ hard to do consciously
o 30-40 trials to learn
eyeblink (UR) mediated by trigeminal nucleus (sensory input) and cranial motor
nucleus (motor output)
eyeblink (CR) includes same nuclei as UR +
o red nucleus in brainstem (output)
§ not involved in learning itself
§ rather lesion causes inability to demonstrate learning by blinking
o pontine nuclei in brainstem (input info from CS and US)
o inferior olive in brainstem (input info from CS and US)
o cerebellum (output)
damage to any of these structures eliminates CR but not UR
Potine Nuclei
receives input from auditory nucleus in brainstem
o responds to noise
sends signals to cerebellum
electrical stimulation of pontine nuclei can serve as eWective CS (instead of CS)
when paired with airpuW US
 pontine nuclei part of pathway conveying CS input
Inferior Olive
receives input from trigeminal nucleus
o output to cerebellum
o responds to airpuW (noxious stimuli)
lesion prior to conditioning —> no conditioning
lesion post conditioning —> eventual extinction of response to airpuW
electrical stimulation elicits eye-blink an can serve as eWective US (instead of
airpuW) if paired with noise
inferior olive part of pathway conveying US input
Cerebellum
receives converging input from pontine nuclei and inferior olive
o output to red nucleus
can get conditioning with combination of pontine nuclei and olive
lesion prior —> prevents learning
lesion post —> blocks expression of previously learned CR
CS and US converge in cerebellum
mossy fibres from pons synapse on granule cells (carrying CS info)
parallel fibres from granule cells form synapses with many purkinje cells
o one receives synapses from 100,000+ parallel fibres
climbing fibres from inferior olive (carrying US info)
strong exclusive communication between climbing fibres and purkinje cell: each
receives 500+ synapses from one and only one climbing fibre
potential for many CSs (or many diWerent time signatures of CS) to be associated
with US
allows for precise timing mechanism
What type of plastic changes occur in the cerebellar cortex?
LTD between parallel fibres and PC
PC send inhibitory signals to interpositus nucleus in cerebellum
o interpositus nucleus is what has output to red nucleus
o interpositus nucleus are inhibited by PC, stopping it from sending a signal
to the red nucleus
o ie. LTD of purkinje cell releases interpositus nucleus from inhibition,
allowing it to send excitatory signal to red nucleus

How does the brain control our movements?
Muscles
skeletal (striate) muscles —> voluntary movement
o myosin (thick protein) and actin (thin protein) (together called
sarcomeres) —> myofibril —> muscle fibres —> fascicles
o relaxed: myosin and actin separated
o contracted: slide into each other to be interconnected
§ myosin cross-bridges “row” along actin filament to slide in
o ~250,000 muscle fibres in biceps and ~100,000 sarcomeres per fibre
Neuromuscular Junction
motor neurons release acetylcholine into neuromuscular junction
acetylcholine binds to nicotinic receptors on motor endplate (ie. muscle part of
neuromuscular junction)
triggers influx of Ca++ that causes contraction
motor unit = number of muscle fibres receiving input from one motor axon
o less —> more precise movement
o eg. thigh muscle motor unit ~1000 fibres
o eg. extra-ocular muscle motor unit ~10 fibres
Myasthenia gravis: autoimmune attack on acetylcholine receptors
o weakness
o less able to active muscle fibres
Botox:
o irreversible
o binds to acetylcholine in axon terminal, prevents release into
neuromuscular junction
Motor Output
motor signals via spinal cord or medulla, relaying from the brain
spinal cord also controls spinal reflexes
o eg. pain withdrawal response or stretch reflex
breathing and walking driven by central pattern generators in spinal cord
Spinal reflex: knee jerk
aWerent input from muscle spindle (detects muscle stretch)
monosynaptic connection in ventral horn to spinal motor neuron
eWerent output to thigh muscles (to contract)
regulates tension in muscle as a response to load

Spinal reflex: golgi tendon reflex
protects tendon from excess force
aWerent input form golgi tendon organ (detects tendon stretch)
o synapse on neuron which inhibits spinal motor neuron
aWerent input from muscle spindle (detecting muscle stretch)
o synapse on spinal motor neuron
eWerent output to thigh muscle (to contract)

Descending control
brainstem
o controls muscles of trunk, neck and proximal limbs
o posture and correcting balance
rubrospinal tract: red nucleus
o controls arms and legs
o limb movements independent of trunk (eg. reaching)
corticospinal tract: motor cortex
o controls muscles in arms, hands and fingers
 o fine manual movements (eg. writing, picking up an object)
Internal capsule
fibres from cortex to thalamus, basal ganglia, brainstem and spinal cord
stroke can cause hemiparesis and hemianesthesia
o usually due to stroke eWecting internal capsule
o eg. right motor cotex
§ weakness in left hand and face
§ but left side of face not paralysed
§ told joke —> able to smile
§ told to smile —> cant
Neocortex
Primary motor cortex (M1)
o central sulcus
o topographic map of body
o electrical stimulation evokes movements in corresponding limb or
muscle group
o output to spinal cord via pyramidal tracts and red nucleus
§ ie. final execution of movement
Supplementary motor area (SMA) and Pre-motor area (PMA)
o involved in planning of movements
§ anticipate direction and destination of movement
§ eg. monkey moving joy stick: neuron activity code for
direction monkey will move
§ perform “mental rotation”
o neurons active..
§ before movement
§ before aborted movement
§ imagining movement
o output to primary motor cortex
Cerebellum
10% of brain weight but >50% of neurons
Sensory input
o vestibular
o somatosensory
o proprioceptive
o visual and auditory
§ involved in eyeblink response
o
§ cortex input via pons
Output cerebellum —> thalamus —> red nucleus —> cortex
Not direct control of motor output
o rather fine tuning of other motor centres
Movement
o smooth execution of sequences of coordinated movements
o damage —> jerky, poorly controlled movements
o short-term adaptation to visuomotor distortion
§ eg. glasses that turn everything upside down
 Cognition
o connections with association cortex
o damage —> deficits in executive function
o imaging studies
§ right cerebellum more active when generating a verb for a noun
rather than just reading the noun
§ more active when attending to semantic rather than rhyming
relationships between words
§ left cerebellum more active during lying than telling the truth

Basal Gagnlia
important for control of movement
a group of structures
o basal ganglia proper: Caudate, putamen and GP
§ work with cortex in loops (particularly motor cortex) and thalamus
and substania nigra in midbrain
History to determine Function of BG
extrapyramidal diseases
o eWects motor system but not motor tracts descending the spinal cord
Huntington’s disease and Parkinson’s disease
both characterised by motor dysfunction and BG degeneration
o suggested BG involved in movement which led researchers to study it in
this context
Function of BG
BG has no direct projection to motor output structures
electrophysiology (electrical activity in brain) —>
o neurons in BG active before and after movement
o neural activity in BG does not code for particular movements
§ ie. cant predict movement animal is making based on neural
activity in BG
Connectivity of the BG
BG form closed feedback loops with cortex and thalamus
o ie. feedback to same point of origin/same neurons
cortex —> striatum —> GP —> thalamus —> cortex
o striatum = caudate and putamen
inhibitory connections = GABA
excitatory connections = glutamate
convergence of inputs and divergence of outputs —> amplified
excitation/inhibition
Direct Path: excitatory feedback
cortex —> striatum —> GPi —> thalamus —> cortex
cortex excites striatum, striatum inhibits GPi which usually inhibits thalamus,
thus thalamus can signal back to cortex
Indirect Path 1: dampen feedback
cortex —> striatum —> GPe —> GPi —> thalamus
cortex excites striatum, striatum inhibits GPe which usually inhibits GPi from
inhibiting thalamus, thus, GPi inhibits thalamus
Indirect Path 2: dampen feedback
cortex —> striatum —> GPe —> STN —> GPi —> thalamus
cortex excites striatum, striatum inhibits GPe which usually inhibits STN from
exciting GPi which inhibits thalamus, thus, GPi inhibits thalamus
Models of BG function
These models are not mutually exclusive and can co-occur
Model 1: BG helps with initiation and termination of movement (aka scaling of
movement)
o PD: diWiculty in initiating movement
Model 2: BG filters input, amplifies/boosts signal (boost) and reduced noise
(indirect) to produce clear movement
Model 3: 10% of striatal neurons respond to signals for reward
o maybe allow motivation control of activity selection based on
consequences
Model 4: BG provides error correction
o predicts feedback from movement allowing faster correction than
permitted by slower peripheral feedback
Multiple parallel loops
multiple loops originating from diWerent cortical areas (not just M1) remain
seregated through BG, returning to their origins
diversity of function
can contribute to variety of cogntive processes
Dopamine input from SN
dopaminergic projections into striatum
o dopamine regulates balance of activity in direct and indirect pathways
D1 receptors
o excitatory
o neurons part of direct pathway
D2 receptors
o inhibitory
o neurons part of indirect pathway
eWect of DA (dopamine) in BG explains psychomotor stimulant eWects of DA
agonists
o eg. drug enhances +ve feedback and reduce -ve feedback to cortex
Huntington’s Disease
genetic disease
progressive loss of GABA neurons in striatum (especially caudate nucleus)
initially twitches in face and hands
o progressive tremors through body
o tremors can resemble voluntary movements
movement disorder accompanied by dementia
o BG eWects other cognitive processes —> dementia
 loss of GABA neurons in striatum leads to decreased inhibition of GPe, resulting
in increased inhibition of GPi, resulting in decreased inhibition of thalamus —>
movement
o indirect loops are failing to work
o unable to filter out inappropriate movements

Parkinson’s Disease
age related disease
greater diWiculty in initiating movement
o abnormal gait (shuWling) and unable to swing arms
o resting tremor
degeneration of DA containing neurons in SN that project to caudate and
putemen (nigro-striatal pathway)
o lack of DA input —> loss of up regulation in direct pathway and loss of
down regulation in indirect pathways —> net shift towards indirect
pathways —> GPi massively suppresses thalamus —> diWiculty initiating
movement
Treatments of PD
1. dopamine agonist drugs (L-dopa)
1. but can result in similar symptoms to HD
2. cell transplant techniques currently being developed
3. brain lesions to GPi or STN
4. deep brain stimulation of STN

All progressive deterioration of brain tissue and accompanying decline in functioning.
Fatal.
Creutzfeld-Jacob Disease
progressive degenerative disease (months, sometime > 1 year)
about 1 in 1 million
post-mortem brain tissue full of small holes
o sponge-like
o spongiform encephalopathy
caused by prions
o causes are genetic, sporadic and also by infection
§ Kuru: consuming brains of diseased elders
§ iatrogenic cases: infection from other patient during surgery
§ not aWected by procedure that destroy nuclei acids
§ agent doesn't have DNA or RNA (ie. not a living
pathogen)
§ only aWected by procedure that destroy proteins
§ prion = protein infection
Prions
= proteins infection

Origin
all animals carry genes that codes for prion protein (PrP)
 o slightly vary in diWerent species, thus, hard to transfer between species
Two forms of PrP
normal form (degraded by appropriate enzymes)
aberrant form (resistant to usual enzymes)
o form that causes disease
o misfolded form of protein (ie. misfolded amino acid)
diWerent genetic codes by same amino acid sequence
infectiousness
o misfolded shape is what makes it infectious
o eg. healthy mice with PrP gene will develop disease if injected with
misfolded protein
§ healthy mice without PrP gene will not develop the disease if
injected
o thus misfolded protein eWects normal protein making them misshapen
Mad Cows and CJD in Britain
due to change in dietary supplements for cows which may have had sheep
products in it
crossed species into humans
o PrP diWer in 30 places cows to humans
mostly absent in skeletal muscle, just brain tissue

Huntingtons Disease
HTT gene of chromosome-4 codes for Huntingtin protein expressed in all cells
but particularly high in neurons
HD patients have longer DNA sequence on HTT which creates mutant Huntingtin
protein
breakdown of mutant protein produces short fragments that get misfolded and
form aggregates that are toxic
Parkinson's Disease
lewy bodies
o contains aggregation of protein alpha-synuclein
production of misfolded alpha-synuclein protein
loss of function og parkin (which tags misfolded proteins for destruction)
Alzheimers Disease
about 50% of all dementia cases
o risk increases with age
widespread loss of brain tissue
o entorhinal cortex and hippocampus
o association cortex
o specific subcortical nuclei: nucleus basalis (cholinergic), locus coeruleus
(noradrenergic), raphe nuclei (serotonergic)
Pharmacological treatment for loss of cholinergic —> mostly AChE inhibitors
Causes
o amyloid plaques
§ beta-amyloid
§ more short in healthy brain
§ more long in AD brain
 § —> misfolded and toxic
§ located mostly in temporal lobe and prefrontal areas
o neurofibrillary tangles
§ tau protein
Distribution
o amyloid-beta located mostly in temporal lobe and prefrontal areas
o same areas active when doing nothing
§ thus, AD aWects areas of constant activity
o
Treatment for AD
AChE inhibitors
o inhibit loss of chloinergic activity
o eg. donazepil
o produces some improvements in cognitive function in early stages
Memantine
o NMDA antagonist
§ reduced activity of NMDA receptors
o more cogntive function in early stages
Monoclonal antibodies
o eliminate β-amyloid and hyperphosphorylated tau, but evidence for
cognitive/therapeutic benefit unclear and side eWects

Why is neuropharmacology relevant to the study and practice of psychology?
approx. 20% of adults receiving psychotherapy also use a prescription
medication for their MHC
integrated pharmacological and psychosocial therapy leads to better outcomes
complex comorbid cases often require treatment with one or more medications,
influencing diagnosis and treatment decisions
Most medications are old and limited
emerging therapies on the horizon which may require specialist training and
education to integrate with psychosocial therapies
How can neuropharmacology help us understand the brain, behaviour and cognition?
the majority of drugs have been developed without prior research
o ie. right place, right time (serendipity)
morphine —> helped us to identify and understand endorphins
LSD —> helped us to understand psychosis and serotonin
SSRIs —> heart medication but increased mood —> leading theory of depression
now we have the techniques and ability to create drugs purposefully and
selectively
Pharmacological ‘modes of action’ common to psychiatric medications
Pharmacodynamics and Pharmacokinetics
Dynamics = what the drug does to the body (to achieve eWicacy or toxicity)
Kinetics = what the body does to the drug (metabolism, transportation of brain,
onset of action, duration of action, peak activity)
What do drugs target in the brain to change function
tri-partitite synapse
o pre, post and astrocyte
drugs manipulated these receptors eWecting the release and uptake of NTs
mimicking endogenous NT release
o binding to post-synaptic receptors
o agonist
inhibit enzymes which breakdown NTs or prevent reuptake
o greater post-synaptic activity

Receptors
G-Protein coupled receptors (GPCRs)
40% of brain acting drugs target GPCRs
role in signalling pathways of NTs (eg. serotonin, DA and norepinephrine)
Gs and Gq are excitatory
Gi is inhibitory
DA1 receptor is excitatory (Gs) and DA2 is inhibitory (Gi)
o related to basal ganglia
complex signalling
o may take longer than rapid onset for ligand-gated ion channels
Ligand-gated ion channels
30% of brain acting drugs target these
eg. benzodiapeines, nicotine, ethanol, ketamine, anaesthetics and some
antipsychotics
open in response to binding of NT
o allows ion flow across the membrane and alters electrical potential of the
cell
simple signalling (fast and potent, fast action)
o rapid onset of action
o however also have high risk of dependence, withdrawal, overdose and
addiction
Orthostery and Allostery
Types of binding
orthosteric = drug binds to receptor site where natural NT (ligand) would bind
o mimic (agonist): dopamine to D2
o block (antagonist): anti-psychotic to D2
allosteric = drug binds to diWerent site on receptor than the natural NT (ligand)\
o potentially safer
o does not block or activate
o rather modifies response to orthosteric binding
§ positive allosteric modulator (PAM): increases sensitivity in GABA
receptor
§ negative allosteric modulator (NAM): more activity to turn on
receptor
Increasing receptor activity
 agonists
o maximally increase activity of receptor
partial agonists
o sub-maximally increase activity of receptor
o potentially safer
o doesn't work for acute episodes
positive allosteric modulations
o increase activity of orthosteric ligand at the receptor
biased agonists
o functional selectivity
Decreasing receptor activity
antagonists
o block binding (eg. caWeine blocks adenosine receptors)
negative allosteric modulations
o decrease activity of orthosteric ligand at the receptor
o rarer
low eWicacy partial agonists
Enzymes
Enzyme Inhibitors
monoamine oxidase (MAO)
o MAO-A: metabolises serotonin, noradrenaline, dopamine
o MAO-B: metabolises dopamine
MAO regulates synaptic NT levels
MAO inhibitors prevent metabolisation resulting in higher NT levels
risks: interact toxically with may other drugs, diets, and other diseases
Acetylcholinesterase inhibitors
reduced in AD
drugs prevents metabolism and increase synaptic acetylcholine levels
can help improve cognitive function
risks: can interfere with many other critical pathways and result in health risks
Transporters
Modulating reuptake transporter function to alter synaptic NT levels
reuptake inhibitors (eg. SSRIs) block the transporting resulting in greater
neurotransmitter levels in the synapse
reversal transporters (eg. MDMA): some drugs with cause the transporter to eject
intracellular NT stores into the synapse
Case Studies
Benzodiazepine Anxiolytics
positive allosteric modulators (PAM) of inhibitory GABA-A receptors
o bind to site diWerent from natural NT
eg. Xanax, Valium, Ativan
make other ligands (eg. alcohol) more potent and eWicacious
increases eWects of GABA (inhibitory), increasing inhibitory activity throughout
the brain, reducing anxiety
o not selective
produce tolerance, withdrawal, overdose and addiction
accidental discovery, taught us about the function of GABA
 o phenotypic drug discovery process (ie. by describing the eWect of
something)
new and best anxiolytics are often discovered using animals models that
naturally avoid light and open areas
o good face validity (innate anxiety of rodents)
o good predictive validity (from rodents to humans)
o assists in development of construct validity

cross-species neurobiological studies implicate amygdala is a key site of action
for benzodiazepine anxiolytics
o mechanistic knowledge often comes after discovery
Methylphenidate for ADHD
methylphenidate/ritalin
dopamine activity in PFC and striatum may be under active in people with ADHD
ritalin blocks function of dopamine reuptake transport (DAT) and noradrenaline
reuptake transporter (NAT)
o more dopamine to the cortex rather than the striatum
function of drug depends on brain chemistry
o stimulant make people with ADHD feel calm
ritalin shares a mechanism with cocaine
o have similar pharmacodynamics
§ both inhibit dopamine reuptake transporter
o have distinct pharmacokinetics
§ cocaine has a rapid concentrated peak
§ ritalin has a slow peal concentration
o given methylphenidate intravenously —> similar eWects to cocaine
thus, mechanism (pharmacodynamics) isn’t everything, absorption
(pharmacokinetics) matter hugely
Drugs of Abuse
dopamine is a common mechanism for drugs of abuse
despite diverse pharmacodynamics (receptor/enzyme/transporter targets), all
drugs of abuse have common eWects on dopamine pathways from VTA to NAc
nicotine
o agonist of excitatory nicotinic acetylcholine receptors in VTA causing
dopamine release
opioid
o agonist of opioid receptors on GABA interneurons in VTA, reduced
inhibition of VTA dopaminergic neurons causing dopamine release
o disinhibition
stimulants
o enhanced release and reduced uptake
o eg. amphetamine releases dopamine from transports
o eg. cocaine: inhabitation of reuptake transporter
Alcohol
Alcohol’s dopamine-stimulating mechanism: taking the brakes oW dopamine’s tonic
inhibition
GAGA interneurons in VTA inhibit dopamine releasing cells
 alcohol binds to GABA receptors on these GABAergic interneurons and inhibits
their activity
o thus dopamine release to NAc
o leading to reward and reinforcement with causes abuse
Dopamine adaptations: a common mechanism for drugs of abuse
chronic stimulation of VTA-NAc pathway changes the basal release of dopamine
and glutamate systems
reduction in normal release
increase in how much can be released during conditioned stimuli
o create pathways that should exist
Anti-Depressants
Anti-depressants and the monoamine theory of depression
Monoamine theory of major depressive disorder
o deficiency of monoamines (eg. serotonin, noradrenaline and dopamine)
at synapse
o boosting these NTs can treat depression
SSRIs inhibit reuptake of NTs
MAOs prevent metabolising of NTs
Problems
rapid pharmacological eWect (ie. elevated NTs rapidly) but delayed therapeutic
eWect
non-response in many patients (~30%)
variability of monoamine levels
some drugs that don’t target this system directly are eWective
Emerging theories of depression
neuroplasticity/neurotrophic theory
o loss of neuroplasticity in people with MDD
o some anti-depressant drugs promote activity in these systems
neuroinflammation theory
o inflammation is involved in MDD
o lose neuroplasticity through neuroinflammation
a new class of rapid acting anti-depressants supporting these theories
o ketamine (NMDA antagonist)
§ increased neuroplasticity
o Psilocybin (5HT2A agonist)
§ increased neuroplasticity and anti-inflammatory
§ cognitive flexibility
§ really good evidence to support this
Summary
There are hundreds of potential mechanisms by which drugs can act in the brain
to change behaviour, cognition, and aWect.
Serendipitously and phenotypically discovered drugs have taught the field a lot
about the brain and behaviour.
Modern psychology practice is intertwined with neuropharmacology;
understanding the mechanism of drugs is important!
There is often a fine line between therapeutics and drugs of abuse/toxicity.
 Experimental neuropharmacology enables us to test new theories of psychiatric
disease.
The next generation of psychologists will likely lead a new era of psychiatric
medications.

Predictions: using a cognitive map to make an assessment of what is likely to happen if
you do something
our ability to navigate our environment is made possible by the models we create
through experience
within these models there is a set of predictions which allow us to foresee what
will happen next
our predictions create our cognitive models
if predictions are not accurate, our models will not be accurate
main goal of learning is to make sure our predictions match reality
Prediction error: when you are surprised by something, when something unexpected
happens in the environment. used to act more appropriately in the environment
Dopamine neurons: critical for prediction error
Error
we need to update our model by comparing what we were expecting to happen
with what actually happened
when prediction does not match reality
prediction error = reality - expectations
o prediction = λ - V
o how much learning happens on the trial
o after multiple exposures, reality with match expectations
o increasing at a decreasing
o if expectation is = 1, but reality = 0 or -1
§ extinction

Associative strength = capturing how likely you are to think about (predict an outcome)
Learning episode = every time you experience the surprising outcome
Prediction is the necessary catalyst for learning
the blocking phenomenon (aka the Kamen Blocking eWect)
dopamine neurons drive prediction error to drive learning
blocking
o you wont learn about the novel thing as the predictor is the same
o no need to update cognitive model

Example:
learn about orange but not about multicoloured, even though shocked the same
amount of time for both
 it about causality
focus attention on purple and then on orange
The blocking procedure shows that we only learn about associations when there is a
prediction error
where do we focus our attention?
Revealing the neural correlates of blocking

Example:
orange would be expected to be more likely to lead to reward than the
multicolour due to blocking
measure prediction error in the brain during the compound conditioning
Prediction errors in the midbrain (VTA) and NAc
activation on a fMRI
learned associations occurring in the orbitofrontal cortex
o activity during test is correlated with eWective blocking
contrast estimate = diWerence in activity between multicoloured and orange
correlates positively with the degree of blocking

Dopamine Prediction Error
Dopamine neurons respond to behavioural triggers
recording dopamine neurons SN and VTA
o using single unit electro physiology
dopamine neurons have a particular waveform which allow us to identify them
o = wide-waveform
o takes a while to return to baseline
wide-wave form is best method to identify dopamine neurons

55% of dopamine neurons responded to trigger stimulus
spike rate = how many times the neuron is firing per second (ie. activity at
particular points in time)
dopamine neurons fire/spike before a response is made
o ie. responding to the door release rather than grabbing the food
Experiment part 2:
location indicator top row (medial vs lateral)
trigger indicator bottom row (press the correct location)
then reward a predicted about of time after
results
o dopamine neurons only respond to reward when it is
unpredictable/unexpected
o unpredictable gap between location and trigger in last one
§ so dopamine neurons respond to both
 negative prediction error when not given reward that is expected
o decrease in dopamine neurons firing
Optogenetics
virus into the brain that allows us to express channelrhodopsin and
halorhodopsin
o C = activation of firing
o H = inhibition of firing
light activates these
can make this specific to dopamine neurons
control neuronal activity with light at very specific timepoints
considerations
o driving wide changes in neurons (eg. all DA neurons fire at the same time):
how do these neurons usually fire, try to make them fire in that way
Causal Link between Dopamine and Learning
unblocked learning about the light by using cre-stimulation (ie. forced firing using
optogenetics)