Biopsychology and Learning Past Paper PDF 2023

Summary

This document contains lecture notes on biopsychology and learning, specifically focusing on classical conditioning, habituation, and sensitization. It provides definitions, explanations, and examples for each concept. The document also briefly touches upon higher-order conditioning and limitations of the principles, along with variations and key elements related to classical conditioning. The lecture notes delve into the relationship between stimulus and responses, suggesting implications within research areas.

Full Transcript

PSYU2236 Biopsychology and Learning

Week 1 Lecture- Introduction to Learning and Classical
Conditioning
What is learning?
Learning is the acquisition of knowledge or skills through experience
Typically, learning is revealed by a change in behavioural, physiological, and/or neural
reactions/responses

Why is learning important?
Learning allows an animal to adapt to their environment
Notice important events and learn to ignore events that have no consequence to them
(non-associative learning)
Learn what stimuli predict events and what behaviours are associated with certain
consequences (reward or punishment) to better predict or prepare to seek or avoid
consequences (associative learning)

Not all changes are a result of learning
Behavioural/physiological and or neural changes can occur that are not a result of
learning e.g changes that occur due to:
○ Illness
○ Fatigue
○ Drugs
How can you tell if a behavioural change is not related to learning?
○ It is not a consequence of experience
○ Often temporary, learning is typically long lasting and can only be changed
through experience e.g through extinction or the learning of alternate behaviour

Associative vs non associative learning
Associative learning: any behaviour in which a new response becomes associated with a
particular stimulus
○ This can occur via the creation of associations between:
○ Two stimuli e.g a bell and a food for Pavlov’s dogs
○ A behaviour and its consequence e.g holding out it’s paw and getting a treat
Non-associative learning: learning that results in a change in the frequency or amplitude
of a behaviour/response after repeated exposures to a single stimulus
○ Increase in response (sensitisation)
○ Decrease in the response (habituation)

Non-associative learning: habituation
People and animals notice novelty from birth
When something new happens, we pay attention to it and show an orienting response
 Orienting response: move toward/attend to new event. Look in the direction of and/or
lean toward
However, after repeated exposure to the stimulus we habituate
Habituation is a progressive decrease in response amplitude or frequency as a
consequence of repeated experience with a stimulus
Habituation is typically stimulus-specific
Habituation can be short or long term, lasting days, hours or weeks
This typically occurs to a stimulus judged to be little or no importance
We engage in this type of learning so we can tune out unimportant stimuli and focus on
what matters
Long term habituation example: a novel sound initially makes an eating cat panic, but if
the sound is repeated daily, the cat habituates and then eats without the slightest
reaction
Example of habituation: people often habituate to the smell of their own dog on their
house or car, or to their own perfume
○ Stimulus specific so people would still notice the pet smell in their friends house
of someone else's perfume
Habituation is NOT sensory adaptation
○ Sensory adaptation is the tendency of sensory receptors to fatigue and stop
responding to an unchanging stimulus- they change their sensitivity to the
stimulus
○ This is a physical, bottom up process e.g a dark cinema theatre, 1015 minutes
later you can see people in their seats

How can I tell if it is habituation or sensory adaptation?
With sensory adaptation, you can’t recapture the initial stimulus
E.g if you jump into a pool of cold water, after a few minutes you start to adapt. After 15
minutes if you try to get the initial feeling of jumping into the cool water YOU CAN’T (no
matter how hard you try)
With habituation, you can recapture the stimulus
E.g if there is an annoying sound, you can eventually tune it out, but if you attend to it,
you can hear it again

Habituation and Dishabituation
Dishabituation: recovery in responsiveness to an already habituated stimulus
Habituation to fridge noise. But the addiction of a novel stimulus reorients the perceiver
to the habituated stimulus… dishabituation to fridge noise
Dishabituation- recovery in responsiveness to an already habituated stimulus

Why does the first bite always taste the best?
Habituation
Habituation is slower when there is a variety and different foods can act as
dishabituation
Habituation is stimulus specific (wanting more desert)
 Sensory specific satiety

Sensitisation
An increase in response amplitude or frequency as a consequence of repeated
experience with a stimulus
Sensitisation is typically not stimulus specific
Often occurs when we are anticipating an important stimulus so that we are prepared for
important cues
Sensitisation (and habituation) are commonly studied using the startle response and
orienting response
Example is a mosquito sleeping with you… becomes more annoying

Desensitisation
A decrease in response amplitude or frequency back down to baseline as a
consequence of repeated experience with a stimulus

Habituation vs Sensitisation
When will one occur versus the other? The outcome of the stimulus
Results show that the attention elicited by a novel stimulus changes with familiarity
○ Elicited behaviours change over exposures
The nature of the change depends on the nature of stimulus
Simple stimulus → progressive habituation
Complex stimulus → sensitisation → habituation
Infant study: after a tone was presented as a dishabituating stimuli along with the
chequerboard pattern causing recovery of visual fixation to the pattern

When does it occur?
Intensity of stimulus
○ Low = habituation
○ High = sensitisation
○ Intermediate = sensitisation then habituation
The evolutionary significance of the stimulus can override intensity
E.g mother not habituate to childs cru
Mozzies carrying diseases etc

Dual process theory
The underlying processes of habituation and sensitisation can co occur
The observable behaviour is the sum of these two processes
The habituation effect is observed when the habituation process is greater than the
sensitisation process and vice versa
Key assumption
○ Response to repeated presentations of a stimulus ref;ect the operation of two
separate processes, habituation and sensitisation.
Habituation
 ○ Produces a stimulus specific decline in responding to repeated stimulation and
grows stronger as the number of repetitions increases
Sensitisation
○ Process produces increases in responsiveness on early trials, which decay
spontaneously over time
These two processes are thought to sum to determine overt responding
SUMMARY AT THE END OF PART 1

Classical Conditioning 1: Introduction
What is classical conditioning? The procedure of repeatedly pairing an initially neutral stimulus
(NS) and an unconditioned stimulus (US) - a stimulus that reliably elicits an Unconditioned
response (UR)
After conditioning the neutral stimulus becomes established as a conditioned stimulus with the
capacity to elicit a conditioned response that usually resembles the unconditioned response

Key elements
NS
US
UR
CS
CR
Types of US
1. Appetitive US automatically elicits approach responses such as eating, drinking,
caressing etc. these responses give satisfaction and pleasure
2. Aversive US such as noise, bitter taste, eclectic shock, painful injections, etc are painful,
harmful and elicit avoidance and escape responses
Appetitive classical conditioning is slower and requires greater number of acquisition trials, but
aversive classical conditioning is established in one, two, or three trials depending on the
intensity of the aversive US

Stimulus substitution theory
Pavlov thought that the CS became a substitute for the US
 Innate US-UR reflex pathway
CS substitutes for the US in evoking the same response
CR and UR produced by same neural region
Food → salivation
CS → salivation
If so, the CR should always be the same as the UR

Evidence for stimulus substitution hypothesis
Signs tracking (AKA Autoshaping) in pigeons
Shows that the nature of the US determines the form of the CR

Sign tracking and individual differences
Both sign and goal trackers are learning that the CS predicts the food outcome, but only
sign trackers ascribe incentive to the cue (CS)
Rats who display sign tracking towards a CS predictive of food are more likely to develop
compulsive cocaine self administration
Research from animals on sign tracking is frequently applied to looking at whether
people who overeat or who are susceptible to addiction are overly associated with food,
alcohol or drugs
Conditioned stimuli that signal reward can become motivational magnets that capture
attention, even when individuals are motivated to ignore them
Sissgn tracking offers an account of how impulsive and involuntary behaviour begins and
is triggered by cues
It offers a theory of how addiction gets started, while at the same time, explaining why
the erosion of self control induced by sign tracking goes largely unnoticed

Evidence against stimulus substitution hypothesis
Any study in which the elicited CR is different from the UR
This is often the case with aversive US
○ E.g when a tone is paired with a shock, rats will jump to the US (shock) but the
CR is typically freezing
○ Freezing is a preparatory defense response

Alternative Accounts
Preparatory response theory
○ Kimble’s theory proposed that the CR is a response that serves to prepare the
organism for the upcoming US
Compensatory Response theory
○ One version of the preparatory response theory
○ The compensatory after effects to a US are what come to be elicited by the CS
○ Based on the opponent-process theory of emotion/motivation
○ Central goal is to maintain a state of homeostasis

Generalisation: a tendency to respond to stimuli that are similar, but not identical to a CS
Stimulus discrimination: the ability to respond differently to similar stimuli- to pick the real deal
from the look alikes

SUMMARY

Week 2- Tutorial
Like me hypothesis, bias towards humanness and things like us
Mirror neuron system, the same neurons are fired when a monkey picks something up, and
when a monkey watches someone pick it up, the same result is found in humans with pain. We
physically map the neurons and then the neural pattern activates. Does human animacy matter?

Animacy results? Like me hypothesis and mirror neural hypothesis so more likely to learn about
people from us. Human > non human. Research reports and tutorials will answer this question.
Hand is the same the difference is the belief of whether it is human or not

IV- what you manipulate
Type of training:
Human belief
Non human belief
A between group design (each participant is one of the IV groups). Within each group,
participants train on the same 12 sequences, but with different animach instructions e,g human
or non human belief
DV- sequence completion time

Week 2 Lecture- Classical Conditioning (Part 2): Variations and
Limitations
Variations on basic classical conditioning
A CR without a CS-US pairing
Higher order conditioning
○ AKA second order conditioning
Sensory preconditioning

Higher order conditioning
Conditioned responses that involve neutral stimuli
Conditioned response is established as a result of a pairing of a neutral stimulus (NS)
with a conditioned stimulus (CS)
E.g fear of highways after a person travels down one following an accident with a truck
Trucks is the first order of response
Limitations of higher order conditioning
The CR to CS is weaker than to CS1
Approx 50% as strong
Higher order conditioning is difficult to accomplish because conditioned inhibition also
arises
More pairings result in inhibition

Sensory preconditioning
In second order conditioning, one CS is capable of becoming associated with another
CS
What if this pairing occurs before they acquire associative strength by pairing one of
them with a US
A CR to an untrained stimulus can even occur when the association between the CS1 and the
second neutral stimulus NS2 is established before the first order conditioned response is
learned… this is called sensory preconditioning

Real world example sensory preconditioning
E.g neighbour (NS1) has a large dog (NS2), one day the dog bites you → dog (CS1) → bite
(US). you before afraid (CR) of the dog (CS1) and develop a dislike of your neighbour (NS2)
To get the strongest CR:
○ Timing is important- first CS must precede second CS
○ Needs to be contingency (one predicts the other)
Can only do a few CS-CS pairings to prevent learned irrelevance
○ I.e metronome → light - so what?

Limitations to classical conditioning
Overshadowing
Blocking
Latent inhibition
Bright light overshadows the metronome and metronome does not cause a reaction

The light previous association with food has blocked learning with new association, because
light signalling food, blocks new association

Overshadowing can be used to prevent the forming of maladaptive associations
E.g to prevent conditioned taste aversions during chemo and or reduce anticipatory nausea

Harnessing classical conditioning during chemotherapy to minimise taste aversions. A
salient/strong flavoured food is eaten with each chemotherapy session. An association is
formed with this taste and chemotherapy induced nausea. This food (stimuli) overshadows the
forming of taste aversions with other flavours/food that the individual eats so their enjoyment of
their favourite foods is not destroyed by an association with chemotherapy induced nausea

Latent inhibition
This new pairing is inconsistent with prior experience
Familiar stimuli are more difficult to condition a CS than are novel stimuli
Real world example of latent inhibition

Lecture summary
Conditioning of a NS, that is, the development of a CR, can occur without an US
○ Higher order conditioning or secondary conditioning
The new NS is associated with a CS and can produce the same CR
○ Sensory preconditioning
If a NS is associated with another NS, which then becomes a CS, the first
NS also becomes a CS and can produce the same response
Limitations in conditioning
○ Overshadowing- after training, the less salient stimulus in a compound NS will fail
to become a CS and will not produce the CR
○ Blocking- if a NS is conditioned to become a CS prior to being presented as a
compound stimulus, it will serve to block the conditioning of the NS it is
presenting with
 ○ Latent inhibition- if a NS is presented without the US prior to the CS→US
conditioning training, conditioning is impaired

Classical Conditioning Part 3: Timing, Extinction, and Inhibition
What factors determine whether and how much classical conditioning occurs?
Determinants of classical conditioning
○ Intensity of US
○ Excitatory vs inhibitory CS
○ Time relationship between stimuli
Simultaneous conditioning
Delayed conditioning
Tract conditioning
Backward conditioning
○ Acquisition → extinction → spontaneous recovery

Intensity of stimuli
Stimulus influences the course of both appetitive and aversive classical conditioning
More intense CS are more effective in accelerating the acquisition of a CR
○ Fewer trials needed
More intense US are especially powerful
○ Extremely intense aversive US can produce PTSD

Excitatory vs inhibitory stimuli
To make our environment more predictable we search for relationships between stimuli
Some stimuli are predictive of the occurrence of a stimulus and some are predictive of its
absence
Both stimuli are just as important to learn about
Excitatory
When the CS products the occurrence of the US it becomes an excitatory CS
CS has a positive relationship with the US
○ The CS acquires an ability to excite the organisms
○ The CS activates behavioural and neural responses related to the US in the
absence of the actual presentation of the US
Inhibitory conditioned stimuli
When the CS predicts the absence of the US it will become a conditioned inhibitory
stimulus (CS-)
○ CS has a negative relationship with the US
Why predict the absence of something
○ We function best in a predictable environment
○ In bad environments we need to know when we are safe- so anxiety levels cna
drop
○ In good environments we need to know when to seek alternatives
○ Trackwork on train line select alternative response bus
○ Sign is an inhibitory stimulus so it inhibits us not to sit on a bench for hours
Temporal relationships between pairing
a. Simultaneous conditioning: CS and US are presented and terminated together
b. Delayed conditioning: CS is presented alone for a while, then the US is presented and
the CS and US typically terminate together. This is the most effective way
c. Trace conditioning: CS begins and ends before US is presented
d. Backward conditioning: CS is presented after US is terminated

What happens when there is a long delay?
○ Onset of CS precedes US by at least several seconds
○ CS continues until US presented
○ Like trace, US-CS interval impacts conditioning but not as severe, if you delay
food after 10 seconds from bell then the salivating starts 8-9 seconds after bell
Backward conditioning
○ Level markedly lower
○ Order is important

Reducing, eliminating or inhibiting a behaviour
Sometimes we need to decelerate a behaviour, through punishment, extinction and inhibition

Extinction
Elimates CS
Repeated present the CS without the US
With repeated exposure to the CS it stops being a preductor of the US and the CR
decreases ans stops
 Systematic desensitisation and exposure therapy
Presents stimulus in neutral environment

Acquisition, extinction and spontaneous recovery
Extinction occurs gradually, after extinction there is no CR
Relearning- fewer trials are needed to get back to CS US pairing

Number of trials does not determine rate of extinction
The total duration of exposure to the CS determines how fast the CR is extinguished
The impact of the duration, rather than the number of times an individual is exposed to
the CS, an important consideration for exposure therapy

Pavlov’s eureka moment
External inhibition- the context where the dog learnt the CR has been changed, so now it
inhibits the CR

Conditioned inhibition
Conditioned in which a NS is associated with the presentation of a US is known as
excitatory conditioning
The result is that he CS, now called an excitatory CS or CS+ acquires the capacity to
regularly elicit a CR
Conditioning in which the NS is associated with the absence or removal of a US is
known as inhibitory conditioning
Result is that he CCS now called an inhibitory CS, conditioned inhibitor or CS-, comes to
inhibit the occurrence of the CR
 Signs that say closed or out of order are meaningful because we don't normally use it.
Normal state of play is that there is an absence of something we would usually expect to
see
Week 3 Lecture- Classical Conditioning 4- Contingency and The
Rescorla-Wagner Model
Contiguity
First principle identified by associationists and refers to the connectedness in time and
space of two items
The more closely together (contiguous) in space and time the two items, the more likely
they are associated
As delay increases between CS and US, the rate of learning decreases

Last two, very little learning happens but they are highly contiguous

Contiguity is important but not sufficient
Kamin’s seminal study on blocking also showed that contiguity alone wasn't sufficient
Homework- explain why blocking isn't sufficient for contiguity to learn
Contiguity is necessary for classical conditioning
… but simultaneous and backward conditioning and the phenomena of blocking
demonstrate it is not sufficient
Must be relationship between the CS and the US to occur

Contingency
Refers to the predictability of the occurrence of one stimulus from the presence of
another
Increasing delay between the CS and the US results in the CS becoming less useful as
a predictor of the US
Contingency is the probabilistic relationship between the US and given that a CS has
occurred
The probabilistic relationship is called Wagon R model

Contingency Theory
 A CR develops when the conditioned stimulus CS is able to predict the occurrence of the
unconditioned stimulus US
After repeated CS US pairings, the individual can begin to predict when the US is
coming based on the CS being present
When the CS is presented, the individual forms an expectancy of the US, this
expectancy is what drives the CR

Role of expectations and surprise
CS → expectations → get what you expected → no change needed → no learning
CS → expectations → surprise you get more → increases your expectations → learning
(can work the same with decrease)

Contingency depends in reliability and uniqueness
Reliability: how often is the CS followed by US, what is the probability that the US will
occur after the CS has occurred
Uniqueness of CS-US pairing: how often does the US happen without CS? What is the
probability of the US occurring given that no CS has occurred

Quantifying contingency relations
Predictive relationship between CS’s adn US’s
The CS has to convey information about US occurrence
p(US/CS) > p(US/no CS)
The probability of a US occurring given that a CS is present
Is greater than
The probability of a US given that no CS is present
If this condition is met, learning (excitatory conditioning) will occur
Left side of equation notes the percentage of CS that are temporarily contiguous (paired)
with a US
If p = 1.0 then 100% of CS are paired with the US
If p = 0.5 then 50% CS’s are paired with US’s and 50% are presented alone
Right side of equation notes the percentage/proportion of time intervals without a CS in
which a US occurs
If p = 1.0 then US’s are presented on 100% of the time intervals with no CS present
If p = 0.5 then the US’s are presented 50% of the time with no CS present
For both groups, there is a 40% chance that bells will be followed by a shock, however for group
B, shock is less likely when no bell is sounded, and, for this group, the bell becomes a fearful
stimulus
Interim summary
When subjects experience CS and US’s tat are positively correlated, they acquire a
conditioned response to the CS; this is called excitatory conditioning
When subjects experience CS and US that are negatively correlated, responses are
inhibited (not performed) when the CS is present; this is called inhibitory conditioning or
conditioned inhibition
When subjects experience CS’s and US’s that are not correlated there is no conditioning
It can be determined if learning is likely to occur by quantifying and comparing the
probabilities of the US occurring with and without the CS

Rescorla’s classic conditioning experiment
Study provided ground work for the seminal rescorla-wagner model of conditioning
Basic method:
Conditioned emotional response (CER) procedure with rats:
Phase 1: operant conditioning to establish steady bar pressing
Phase 2: classical conditioning to establish CER

Procedure
CER training (daily for 5 days)
All rate exposed to 12 tones
Tones were 2 mins long and mean inter tone interval was 8 mmin
Probability of shock (the US) during tone was 0.4 for all rats
Groups differed in probability of shock during the inter tone interval

During the inter tone interval:
Group 0: no shocks
Group 1: shocked probability of 0.1
Group 2: shocked probability of 0.2
 Group 4: shocked probability of 0.4
Remember: the probability of the shock occurring with a tone was 0.4 for all the rats

Phase 3:
After CER training, the rats returned to the bar pressing for food
While the rats were bar pressing, the tones were presented as before, but no shocks
were given
If the tone triggers the conditioned fear response e.g freezing, it interferes with
(suppresses) the expression of the operant conditioned response (bar pressing)
Conditioning was assessed by a suppression ratio (the lower the ratio, the greater the
suppression, the stronger the conditioning)

Summary of results
Whenever p(US/CS) > p(US/no CS):
CS is an excitatory CS
That is; CS predicts US
Amount of learning depends on size difference between p(US/CS) and p(US/no CS)
Whenever p(US/CS) > p(US/no CS):
CS is an inhibitory CS
That is; CS predicts ABSENCE of US
The amount of learning depends on size differences between p(US/CS) and p(US/no
CS)

Part 1 summary:
Learning occurs when there is a prediction error
I.e discrepancy between the actual outcome of a conditioning trial and the expected
outcome of that trial
The Rescorla-Wagner model allows us to quantify the size of the contingency
relationship between a CS and a US

Part 2: The Rescorla-Wagner Model
Mathematical model designed to predict the outcome of classical conditioning
procedures on a trial by trial basis
Learning will occur only when the subject is surprised, that is, when what actually
happens is different from what the subject expected to happen
Always three possibilities in conditioning trials:
○ Excitatory conditioning
○ Inhibitory conditioning
○ No conditioning at all
Which of these three possibilities actually occurs depends upon:
○ The strength of the subjects expectations of what will occur
○ The strength of the US that is actually presented
Six rules of the Rescorla-Wagner model
1. If the strength of the actual US is greater than the strength of the subjects expectation,
all CS’s that were paired will receive excitatory conditioning
2. If the strength of the actual US is less than the strength of the subjects expectation, all of
the CS’s that were paired with the US will receive some inhibitory conditioning
3. If the strength of the actual US is equal to the strength of the subjects expectation, there
will be no conditioning
4. The larger the discrepancy between the strength of the expectation and the strength of
the US, the greater the conditioning that occurs (either excitatory or inhibitory)
5. More salient CS’s will condition faster
6. If two or more CS’s are presented together, the subjects expectation will be equal to their
total strength (with excitatory and inhibitory stimuli tending to cancel each other out)

Rescorla-Wagner: Acquisition
With each successive conditioning trial, the expectation of the US following the CS
should get stronger, and so the difference between the strength of the expectation and
the strength of the US gets smaller
Therefore, the fastest growth in excitatory conditioning occurs in the first trial, and there’s
less and less additional conditioning as the trials proceed
When the CS elicits an expectation that is as strong as the USm the asymptote of
learning is reached, and no further excitatory conditioning will occur with any additional
CS-US pairings

SHIFT COMMAND 4 SLIDE 43

Is learning really asymptoting?
The R-W model says no learning is occurring after asymptote reached… but it is important to
remember that this asymptote reflects the maxing out of the behavioural performance/response
that can be measured. Learning might still be occurring!

Rescorla-Wagner: Blocking
When two CS’s are presented, the subjects expectation is based on the total
expectations of both
No conditioning occurs to the added CS because there is no surprise- the strength of he
subject’s expectation matches the strength of the US
Increasing the strength/size of the US when presenting the compound CS may prevent
blocking effects

Rescorla-Wagner: Extinction & Conditioned Inhibition
The strength of the expected US is greater than that of the actual US, leading to a
decrease in the association between the CS and the US
○ Following acquisition CS → No-US
This leads to any CS or compound CS to acquire some inhibitory conditioning
○ CS → No-CS learning occurs until the absence of the US is no longer surprising
 ○ CS → conditioned inhibitor

R-W: Combining CS’s
When two CSs that elicit CRs on their own are combined, the expected US of the
compound CS is roughly equal to their total strength
E.g a CS+ and a CS- conditioned separately are presented as a compound CS and
offset each other

R-W Overexpectation effect
The R-W predicted the overexpectation effect
There is a decline in responding to a pair of well established conditioned stimuli (CS’s)
when they are presented as a compound
Overexpectation effect:if two CS’s are conditioned separately and then together, the
animal has am over-expectation about the size of the US , and both CS’s will experience
some inhibitory conditioning
○ The animal expects twice of the US, so if only the same US follows the
compound CS as did each CS alone, this does not meet the animals
expectations
SHIFT COMMAND 4 REST OF SLIDE 48
The frequency principle of CS-US pairings would predict a stronger CR to the compound
stimulus
○ I.e the mire trials linking the CS and US, the stronger the CR
It would not be expected that more CS-US pairings would result in a weakening of
CS-US associations, yet this occurs in conditions like these where compound CS’s
experience inhibitory conditioning due to the overexpectation effect

Summary
Can be thought as a model of US effectiveness
Unpredicted (surprising) US is effective in promoting learning
Well predicted US is ineffective in promoting learning

Alternative Theories of Classical Conditioning
Rescorla-Wagner model focuses on the US side of the association
○ Unpredicted (surprising) US is effective in promoting learning
○ Well-predicted US is ineffective in promoting learning
Alternative theories focus on attention to the CS instead
A common feature of these theories is the assumption that the learner will pay attention
to informative CS’s but not uninformative CS’s
These theories might also be called theories of CS effectiveness, because they assume
that the conditionability of a CS< not the effectiveness of the US, changes from one
situation to another

R-W Cannot Explain Latent Inhibition
 Recap on latent inhibition/pre-exposure effect: Classical conditioning proceeds more
slowly if a CS is repeatedly presented by itself before it is paired with the US
The Rescorla-Wagner model does not predict this CS pre-exposure effect
When the (to-be-CS) stimulus is presented by itself before the training, the expected US
is zero, and the actual US is zero
According to the Rescorla-Wagner model, since the actual US = expected US, there
should be no learning of any kind during the pre-exposure
However, subjects evidently do learn something during the pre-exposure trials, which
reduces their ability to later develop a CS-US association
Attention-based theories are able to explain the pre-exposure effect
○ Because the CS predicts nothing during the pre-exposure, attention to the CS
decreases, and so conditioning is slower when the CS is first paired with the US
at the beginning of the conditioning phase

Comparator Theories of Conditioning
Comparator theories assume that the animal compares two likelihoods:
The likelihood that the US will occur in the presence of the CS
The likelihood that the US will occur in the absence of the CS
Comparator theories are similar in many ways to Rescorla-Wagner and Attentional
theories, but differ in two ways:
They do not make predictions on a trial-by-trial basis
○ 1. They assume what is important is not the events of individual trials but rather
the overall long-term correlation between a CS and the US
○ 2. They propose that the correlation between CS and US does not affect the
learning of a CR but rather its performance
E.g. Subjects may learn an association between a CS and a US that
cannot initially be seen in their performance, but this learning can be
unmasked if the strength of a competing CS is weakened

How might we unmask learning in blocking?
Comparator theories suggest that learning still occurs to a blocked stimulus, it is just
masked….
What if you extinguish the blocking CS?
Would any conditioning to the blocked CS be revealed?

Blocking revisited

SHIFT COMMAND 4 SLIDE 57

Comparator theories of learning
Comparator theories differ from R-W’s model in two ways:
○ 1) Unlike R-W, comparator theories assume that both the CS and contextual
stimuli can acquired equal excitatory strengths, because both have been paired
with the US
 ○ 2) Comparator theories also assume that a CS will not elicit a CR unless it has
greater excitatory strength than the contextual stimuli
The animal has learned something about the CS: that the US sometimes occurs in its
presence, but the animal will not respond to the CS unless it is a better predictor of the
US than the context
Context plays a critical role in determining the response

Rescorla-Wagner, Attentional and Comparator Theories: Common Themes
The predictiveness or informativeness of the stimulus is a critical determinant of whether
a CR will occur
The predictiveness or informativeness of a stimulus cannot be judged in isolation
It must be compared to the predictiveness of other stimuli also present in the learner's
environment.
○ In reality, contextual cues are present when the US is absent as well as present à
reduces the uniqueness of the relationship with the US and therefore limits
learning

Summary
Unblocking doesn’t sit well with the Rescorla-Wagner model – but there are other
theories that offer alternative accounts of the learning process
Theories of attention – Mackintosh (1975) Pearce and Hall (1980) focus on how much
attention the CS is able to attract, as opposed to how much associative strength a US
can support (Rescorla-Wagner, 1972).
Comparator theories take contextual cues into account But R-W model is important, and
still influential, because it still has a lot of explanatory power and was first in terms of
developing a cognitive explanation of classical conditioning processes

Week 4- Operant Conditioning Part 1
Classical- pairing by timing
Operant- consequence for behaviour
Skinner box- the organism operates on its environment to achieve some desirable outcome
Some behaviour that can be done to obtain reward
○ Rate measured by experimenter
A dispenser of food is used as reinforcer (reward)
Tones or lights to signal availability of opportunity for reward or pending punishment
○ Used in discrimination and generalisation studies
E.g measure rate of bell rings to gain food (consequence)
Probability increases as positive reinforcement

Shaping or successive approximations
 Shaping is use of reinforcement of successive approximations of a desired behaviour
When using a shaping technique, each approximate desired behavior that is
demonstrated is reinfroes, while behaviours that are not approximations of the desired
behaviour are not as reinforced
E.g cats owner first rewarded when they lifted their paw, then when they reach towards
the bell, then when they rang the bell etc

The Behaviour Increases Decreases

Added to the environment Positive reinforcement Positive punishment

Removed from the Negative reinforcement Negative punishment
environment (avoidance learning)

Positive Reinforcement
Behaviour + consequence = outcome
Texting in class + more interesting than lecture = keep on texting
Drinking coffee one morning + feeling more awake = coffee every morning

Positive Punishment
Adding something to the environment that causes behaviour to decrease
Made to do chores = something added to make it bad

Negative Reinforcement
Something is removed from the environment that causes the behaviour to increase, so
that something must have been unpleasant
E.g you got caught in traffic and missed the meeting, found out the meeting was
important and it will increase the likelihood of you being late again
Applying sunscreen to prevent sunburn
Strengthen a behaviour that avoids or removes a negative outcome
Eating healthy foods to avoid being sick
Anxiety engaging in avoidance techniques which means they will probably keep doing it

Negative Punishment
Something is removed from the environment that causes behaviour to decrease in
frequency, that something must have been pleasant
Aka response cost or omission training, involve a removal of a stimulus following
targeted behaviour, that person values or enjoys or desires
To facilitate the process they may be reinforced for exhibiting another more desirable
behaviour (DRO: differential reinforcement of other behaviour)
E.g if you don’t tidy your room you will lose your phone

Behaviour-Consequence Relationships: Emotions
Schedules of Learning
Continuous schedule
Behaviour is followed by a consequence each time it occurs
Excellent for getting a new behaviour started
Behaviour stops quickly when reinforcement stops
Not the best

Thinning intermittent reinforcement
One of two common
○ Increase response ratio or the duration of the time interval between response →
reinforcer
Providing instructions such as rules and signs e.g spanish crossing has
countdown

Partial schedules for resistance to extinction
Ratio- after predetermined number of responses you get outcome
Interval schedules- the first response after the time has elapsed → outcome e.g every
minute no matter how often you respond relies on TIME after 1
Fixed schedule- every 5 responses (ratio) or every 5 minutes (interval) outcome e.g a
predictable schedule
Variable schedules e.g every 2-5 minutes or every 2-5 responses e.g unpredictable
schedule

Can combine
Fixed ratio
Variable ratio
 Fixed interval
Variable interval

Fixed Ratio
Behaviour/reinforcement 100/1 or 15/1
Response rate: higher ratio = faster responding
Behaviour: tend to work hard (ratio run) receive reinforcement, then brief post
reinforcement pause- see point A on figure, then work hard
RESISTANCE TO EXTINCTION: LOW

Behaviour on a fixed ratio
High rates of responding → pause after receiving rewards (PRP) then onwards for the
next reward
Make the number of responses too high → ratio strain
○ A disruption in responding due to an overly demanding response requirement
Ratio strain:
Avoidance, aggression and unpredictable pause in responding e.g if things don't get
better then I don't know how much longer I can do this
E.g pressing a lever for some food is fine but doing backflips isn't worth my time
Over time they can predict when they know it is going to happen
E.g working harder just before you get the reward

Variable Ratio Schedule
Behaviour / reinforcement: random or unpredictable number of responses between
reinforcements
Response rate: fast
Behaviour: work hard and at a steady rate
RESISTANCE TO EXTINCTION: HIGH
 What if the rewards came on a temporal basis?
How would it affect the rate of responding?
○ Reduce it- no point working it its not making the rewards come any faster
○ E.g button pressing on a sydney pedestrian crossing is on a fixed interval

Fixed Interval Schedule
Behaviour or reinforcement after 1st then fixed amount of time
Response: scalloped
Behaviour: high before reinforcement and a long pause after
Lowest rate of responding
RESISTANCE TO EXTINCTION: LOW

Variable Interval Schedule
Behaviour / reinforcement first response then “average” time period elapsed
Response rate is slow
Works at a steady rate
RESISTANCE TO EXTINCTION: HIGH
 E.g petrol prices follow a variable interval schedule of reinforcement

Highest rate of responding
Variable ratio
Fixed ratio
Ratio → consistent rates of responding
Variable interval schedule
Fixed interval schedule

Part 1 Summary
Operant conditioning a relationship between a behaviour and its consequence is learned
○ + and - reinforcers increase the likelihood of that behaviour
○ + and - punishment decrease the likelihood of that behaviour
Different schedules of reinforcement can be used to produce different patterns of
behaviours that are more or less resistant to extinction

Part 2: Changing Behaviour

Differential Reinforcement
Four procedures that incorporate reinforcement to address and treat disruptive behaviour are:
1. Differential reinforcement of other behaviour (DRO)
2. Differential reinforcement of low rates of responding (DRL)
3. Differential reinforcement of incompatible behaviour (DRI)
4. Differential reinforcement of alternative behaviour (DRA) not necessarily incompatible

Differential reinforcement of other behaviours
Subject periodically receives positive reinforcer provided it is engaged in other
behaviours
 ○ E.g sitting quietly (thus omission training) involved reinforcing other behaviour,
whole interval DRO (WIDRO)- if target behaviour has not occurred throughout
entire period e.g 1 minute → positive reinforcere for other behaviour

Differential reinforcement of low rates of responding
Teacher wants the child to wash his hands, but not more than once before lunch. Using
the DRL, they get to be first in line to lunch if he avoids washing it more than once

Differential reinforcement of incompatible behaviour (DRI)
A teacher wants the child to remain in his seat so every time he gets out, the behaviour
is ignored but when he stays in, he gets rewarded with a sticker

Differential reinforcement of alternative behaviour
Every time a child makes a demand, parent ignore him, when the child asks politely they
listen

Establishing operations
EO’s are factors that affect the effectiveness of reinforces, the intensity, amount, and type i.e
quality of reinforcer determines its effectiveness

Reinforcer magnitude
Larger the reward the faster the acquisition of learning
Reinforcer must be sufficient magnitude for it to be worth making the response
If income is less than childcare costs, parents won't return to work
Reward magnitude is often a matter of being in the eyes of the beholder
E.g rats run faster for the same amount of food but run faster for the food when its
broken into more pieces
A large reinforcer to a 5 year old may be a weak reinforcer to a 25 year old
A few small reinforces are stronger than 1 large one
Contrast effects
Shifting the value of the reward in mid stream is also effective in changing behaviour
known as contrast effects
Reinforcer magnitude is all a matter of relativity
Contrast effects are obtained when the quality of the reinforcer is switched as well
Responding is influenced by the reinforcement characteristics that an organism has
come to expect in its past

Delay of Reinforcement
Gradient of delay: the delay decreases the contiguity between response and outcome
○ Temporal contiguity is an important factor in the effectiveness of operant
conditioning. Golden retriever obedience training will be more effective if he is
rewarded straight after trick
The delay decreases the contiguity between response and outcome
○ Long delays make it difficult for the person/animal to see the relationship
between their response and the consequence.
○ A delay allows time for other behaviours to occur during the interval →
superstitious reinforcement of them.
○ Deleterious effects of delay can be reduced by providing a signal that the reward
is coming i.e. clicker.

Contiguity and Reinforcement

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Gradient of Delay
Delay of reinforcement gradient: The effectiveness of the reinforcement decreases as
the delay increases
When there is no bridging cue, just how long can the interval be?
30 seconds and the rat can still learn the association

Speed of Reward
Addiction is linked to the speed of reward
○ Why checking emails is more rewarding than finishing a psych report
This is why Internet pornography is much more addictive than pornography contained in
a magazine or video.
And this is exactly why modern poker machines are much more addictive than older
pokies – the “one-armed bandits”.
Modern pokies increase the gambling 'dosage' to much higher levels.
All this speed means more bets, and more bets mean more excitement and more
excitement means more dopamine.
 More dopamine means the modern pokie is more addictive than its predecessors

Response-Reinforcer Contingency
The Reinforcer must be the result of some Response
○ The greater the consistency between the Reinforcer and the Response, the
quicker/more effective the conditioning.
GOALS MUST BE SET AND MET BEFORE A REWARD IS GIVEN
Response Control: two month old infants who can make a mobile move, smile and coo
at it, while those who have no control over its motion, stop smiling

Reinforcers: Primary and secondary
A primary reinforcer is a stimulus that is reinforcing even without previous training.
Primary reinforcers are biologically relevant stimuli or events i.e. they have survival
value. Examples include food, water, and sex.
A conditioned (secondary) reinforcer is an arbitrary event (such as a tone, clicker or
token) that increases the frequency of an operant response. Events that have been
associated with rewarding experiences acquire reinforcing power.
They are reinforcing because they permit an organism to obtain a primary reinforcer.
There are a variety of classes of reinforcers that can be subsumed under the heading
secondary reinforcer:
○ Tokens: money
○ Social: smile or thank you → feel good
○ Activity reinforcers: screen time (premack principle)
○ Covert reinforcers: giving yourself a quiet slap on the back for sticking to your
goals

Functions of Conditioned Reinforcement
Conditioned reinforcers:
Tell organism it has done right thing
Tell the organism what to do next
Bridge long periods between unconditioned reinforcers

Conditioned Reinforcement: Clicker training
Used for training animals – from dogs to horses to dolphins (Karen Pryor)
Pair a hand-held clicker with food through straightforward classical conditioning.
The sound of the clicker can then reinforce other behaviours – such as “Sit”.

Clicker Training: Advantages
Clickers sound the same no matter how you are feeling when you press it
A clicker is easier to discriminate from everything else we say to the dogs!
Split second timing is possible with the clicker thereby reinforcing the precise behaviour.
Using a primary reinforcer, such as food, can cause the dog to become focused on the
food, and the food giver, rather than on the behaviour.
The clicker can reinforce the behaviour immediately.
So how powerful is a secondary reinforcer?
A number of variables affect the strength of a secondary reinforcer:
1. The magnitude of the primary reinforcer
2. The number of pairings (with the primary reinforcer)
3. Time elapsing between the presentation of the secondary reinforcer and the primary
reinforcer

Token Economies
Token Economies were pioneered by Ted Allyon and Nate Azrin
Used to teach and maintain normal behaviour of psychotic residents in a psychiatric
institution.
Were suffering from severe problems with verbal and social behaviour
Those included in the token economy earned little metal tokens by making responses.

Use of Tokens with Humans
Reinforcement in a token economy.
This graph shows the effects of using tokens to reward socially desirable behaviour in a
mental hospital ward.
Desirable behaviour was defined as cleaning, bed making, attending therapy sessions,
and so forth.
Tokens earned could be exchanged for basic amenities such as meals, snacks, coffee,
game-room privileges, or weekend passes.
The graph shows more than 24 hours per day because it represents the total number of
hours of desirable behaviour performed by all patients in the ward.

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Activity as a secondary reinforcer: Premack’s Theory
"What is a reinforcer?" David Premack (1965) supplied a way out of the dilemma--just
look at what an organism does as what is important
"reinforcement involves a relation, typically between two responses, one that is being
reinforced and another that is responsible for the reinforcement. This leads to the
following generalisation: Of any two responses, the more probable response will
reinforce the less probable one" (1965, p. 132).
This generalisation, known as the Premack Principle, is usually stated somewhat more
simply:
High probability behaviour reinforces low probability behaviour

Premack’s Theory of Reinforcement
If you eat your veggies → then you get to eat ice cream
If you study first then you can watch tv
And punishment
If you’re naughty you have to do chores
Chaining
Chaining refers to a method of teaching a behaviour using behaviour chains. Behaviour
chains are sequences of individual behaviours that when linked together form a terminal
behaviour.
It involves reinforcing individual responses occurring in a sequence to form a complex
behaviour. It is frequently used for training behavioural sequences (or "chains") that are
beyond the current repertoire of the learner.
The chain of responses is broken down into small steps using task analysis. Parts of a
chain are referred to as links.
Problem: rat needs to get to top platform
○ Response chain: a sequence of behaviours occurring in a specific order
reinforced on the occurrence of the terminal response.
○ Each step in the response chain acts both as a conditioned reinforcer (SR) for
the previous step and as a discriminative stimulus (SD) for the next step

Discriminative Stimulus
Discriminative stimulus: a stimulus that indicates whether or not responding will lead to
reinforcement.
○ The ladder serves as a discriminative stimulus indicating that if they climb up they
will be rewarded (or will be closer to the reward)

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Two main chaining techniques
Forward Chaining: Using forward chaining, the behaviour is taught in its naturally
occurring order.
Each step of the sequence is taught and reinforced when completed correctly. Once 1st
is mastered →next step
Backward Chaining: Using backward chaining the learner first performs the final
behaviour in the sequence at the predetermined criterion level, reinforcement is
delivered.
Next, reinforcement is delivered when the last and the next-to-last behaviours in the
sequence are performed to criterion.
○ This sequence proceeds backwards through the chain until all the steps in the
task analysis have been introduced in reverse order and practised cumulatively
Both techniques more successful than whole task learning

Response Chains
Response Chain Considerations
Dependent on reinforcement for continued performance.
If a link breaks, all behaviours prior to the broken link will be extinguished.
Each reinforcer does not have equal value.
Responses farthest from reinforcement are the weakest and easiest to extinguish.
Mission Impossible: Squirrel chaining behaviour
This takes place in England - the owners of the yard added each piece of the Rube Goldberg
contraption slowly so that when the squirrel learned one section and got the nuts, they then
added the next section. Finally it ended with what you see on the clip! It took over 2 weeks to
get to this point.

Part 2 Summary
Different reinforcement schedules can also be used to reduce unwanted behaviours
○ The undesirable behaviour is not reinforced, but instead other, incompatible, or
alternative responses are reinforced
○ Or lower rates of the unwanted behaviour targeted are reinforced.
The magnitude, delay, and contingency of the reinforcer impacts is effectiveness
Reinforcers can either be primary (e.g., food) or secondary (money)
Premack’s principles proposed that activities are reinforcing
○ High probability behaviours (behaviours that the organism frequently does when
given the opportunity) reinforce low probability behaviours (behaviours that the
organism would be unlikely to do on their own)
Complex chains of behaviours can be learned through a process of chaining where
separate “chains” or behaviours are learned and linked together.

Week 5- Extinction in Operant and Classical Conditioning
What is learning?
Change in behaviour as a result of experience
○ Adaptive: behaviour is plastic and flexible to suit the environment in which we find
ourselves
Non associative learning
○ Habituation, sensitisation- changes to make our experience more suited to the
surroundings
Associative learning
○ Learning to predict relationships between events, actions and outcomes
○ Allows us to seek out and obtain rewards and avoid situations that are dangerous

Mechanisms of Extinction
Pavlovian conditioning- learning that an event/object/context predicts a particular
outcome
US: a biologically salient event/outcome
UR: the natural response elicited by the US
CS: an initially neutral stimulus that, through repeated pairings with the US, comes to
elicit the same response
CR: the response that is elicited by the CS (usually the same as the UR)
Operant conditioning- learning that particular actions will result in particular outcomes
 Reinforcement- an event that increases the likelihood of repeating the response that
preceded it
Positive reinforcement = presentation of a favourable (appetitive) outcome
Negative reinforcement = outcome is removal of an aversive stimulus
Punishment = an event that decreases the behaviour that precedes it
Positive punishment = adding an aversive outcome
Negative punishment = outcome is removal of an appetitive stimulus

Prediction error
The amount of learning that will occur in any one trial depends on how surprising the
unconditioned stimulus is (Rescorla and Wagner, 1972)
The difference between the expected and the actual outcome
∆Ⅴ=α(λ−Ⅴ)
∆Ⅴ = change in associative strength
α = associability or learning parameter
λ = magnitude of the US
Ⅴ = current associative strength

What happens if the expected outcome is omitted?
Negative prediction error: I expect something to happen and it doesn’t

Pavlovian Conditioning
PAVLOVIAN CONDITIONING = learning that an event / object / context predicts a particular
outcome
Appetitive: Unconditioned Stimulus is favourable E.g. Pavlovian conditioned approach
Aversive: Unconditioned Stimulus is unfavourable E.g. Pavlovian fear conditioning
EXTINCTION = decrease in the conditioned response as a result of CS-alone
presentations

Theories of Extinction
Unlearning or erasure of the CS-US association
New learning of a second, competing association that inhibits the expression of the
original association

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Mechanisms of Extinction
Conditioned response is not erased after extinction
Extinguished fear responses often recover without any additional CS-US retraining
This is because extinction learning and memory is closely tied to the context where
extinction occurred
The original CS-US memory is not context dependent

Clinical significance- why would we want to study extinction?
1. To understand how we learn about our environment, to understand how we learn about
changes to our environment
2. To understand anxiety
a. Uncontrollable fear in non threatening situations
b. Exposure therapy is extinction

Using extinction in clinical settings
Extinction is context specific
Learned behaviour reinstates following the brief exposure to the unconditioned stimulus
Extinction dissipates over time

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Adolescents show poor extinction retention
Some evidence for sex differences
○ Not always
Fluctuating hormones may mediate sex differences
If considered by estrous phase:
○ Proestrus (high estradiol) = facilitated extinction
○ Metestrus (low estradiol) = impaired extinction
Hormone supplements/blocks can facilitate/impair extinction
○ In females
○ And males
○ Suggests that hormone cause extinction rate
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In adolescents the effect is opposite
Proestrus and Diestrus (high oestrogen) = impaired extinction

Summary
Extinction is the reduction in Pavlovian conditioned response
 ○ E.g Pavlovian conditioned fear
Extinction is not the erasure of original learning
Extinction is context dependant, original learning can generalise across different
contexts
Extinction can be used as a therapy for phobias and other anxiety-related disorders
Extinction can be used as a therapy for phobias and other anxiety related disorders
Extinction varies across development
○ Juveniles: forgetting rather than extinction
○ Adolescents: extinction deficit
Extinction is affected by sex/hormones

Part 2 Operant Conditioning

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Mechanisms of Extinction
Clinical significance of extinction
Reduce unwanted behaviours e.g....
○ Conduct disorder and other disruptive behaviours
○ Substance use disorder, gambling use disorder
Problems with extinction as an intervention
○ What is the reinforcer?
○ Are there more than one reinforcers
○ What is being extinguished
○ Extinction burst
○ Extinguished behaviours can return

Clinical significance of extinction and reinstatement
Addiction is learning about drugs
Extinction can be used to change drug seeking behaviour
Reinstatement can be used to model relapse

Reinstatement/primed reinstatement
Reinforcer itself acts as a “discriminative stimulus”/signal that pellets were available

Drug Primed reinstatement
Injection of drug provides and interoceptive signal that drug is available
Passage of time is enough to cause increase after

Conditioned response is not erased after extinction:
Reinstatement
Renewal
Spontaneous recovery
 Recovery of responding after extinction occur in operant conditioning as for pavlovian
conditioning
Stimuli that are presented during reinforced responses from associations with the
reinforcer
These stimuli can mediate responding after extinction

Stress induced reinstatement
Stronger for drug rewards, with stress is a lot higher
Circulatory of stress induced reinstatement is different from forms of reinstatement
Stress shares a common neural substrate with many drugs of addiction
Rapid requisition
Rat need to learn a new response to get the same reinforcer

Resurgence
Showing all options that worked in the past
Shows an important difference between classical and operant conditioning

Classical extinction leaves the CS with two available meanings:
1. CS → US (excitatory conditioning)
2. CS → no US (inhibitory conditioning)

Operant extinction leaves the individual with two available options
1. Give up
2. Try other means
(having another response available makes extinction faster)

Reducing relapse by extinguishing the context drug induced reinstatement, context is important
for extinction condition for rate with no cue extinction, they show increase extinction compared
to cue extinction

Extinguishing behaviour by reducing the reinforcer
Run down corridor to get heaps of food pellets
Then they still run down but only 6 pellets
Extinction when there is less
But if there is only 50 pellets the whole time its pretty steady

Extinguishing behaviour by providing an alternative reinforcer (social reward) they would rather
hang with buddies then get meth
Age dependant effects of extinction
Adolescents show extinction deficit as with pavlovian conditioning
Sex dependant effects of extinction/reinstatement
Stress induced reinstatement is stronger in females than in males

Summary
 Extinction is the reduction in a learned behaviour
Extinction is not erasure of the original learning, and original learning can be retrieved
○ Spontaneous recovery (after passage of time)
○ Reinstatement (through non-contingent exposure of the reinforcer)
○ Renewal (through change in context)
Also see
○ Resurgence
○ Cue-induced reinstatement
○ Stress-induced reinstatement
○ Rapid reacquisition
Extinction can be used to reduce inappropriate fear/anxiety
Extinction can be used to eliminate unwanted behaviours
Extinction may be used to help reduce craving when treating substance use disorder
(but it’s not very effective).
In both cases be aware of individual differences (including age and sex)
After extinction, the CS or the response has two meanings, context is often used to
disambiguate these.
Operant responding is supported by many different aspects
○ Associations between the response and the outcome (R-O)
○ Associations between discrete cues and the outcome (S-O)
○ Associations between the discrete cues and the response (S-R)
○ Associations between the context, the outcome and the response (occasion
setting)
Omitting the outcome is not the only way of changing behaviour
○ Change the magnitude of the reinforcer
○ Add a punishment
○ Provide an alternative reinforcer

Week 6 Lecture- Aversive Conditioning: Punishment, Escape and
Avoidance Learning
Aversive Control: Punishment
What is punishment?
The weakening of a behaviour through either the:
1. Application of an aversive stimulus (positive punishment)
2. Removal of an appetitive stimulus (negative punishment)
Positive punishment
○ Consists of the presentation of an aversive event following a response that leads
to a decrease in the future strength of that response
Negative punishment
○ Consists of the removal of an appetitive event following a response leads to a
decrease in the future strength of that response
Punishment
○ Bear in mind that the to be punished behaviour is enjoyable to stop that individual
doing the misdemeanour and they won’t want to stop
And what we have seen from extinction is that we cannot unlearn a behaviour- we can
only suppress or inhibit it; or train an individual to omit to it

Two types of negative punishment
1. Time out
a. Loss of access to positive reinforcement for a brief time following occurrence of
problem behaviour e.g send child to room, likely to be ineffective if time out
setting is more reinforcing, or if it is too long of a time out
2. Response cost aka omission training
a. Removal of valued reinforcer following occurrence of inappropriate behaviour
b. The stimulus that is removed must decrease the frequency of the operant
behaviour. The benefit of this is you can adjust the punishment to suit the size of
the problem behaviour. Time out → suspension → expulsion
c. Taking toys away if they are naughty, swear jar, paying a fine for speeding
Negative punishment vs extinction
Does the behaviour grow weaker because performing it:
○ no longer leads to something? Extinction
○ Leads to the removal of something that you would otherwise posses? Then
negative punishment
Similarities
○ Both involve removal of reinforcers
○ Both result in decreasing strength of behaviour
Differences
○ Extinction- behaviour that previously produced the reinforcer no longer does and
behaviour stops e.g whining no longer produces lollipop
○ Negative punishment- performing the behaviour results in a loss of reinforcer that
is already possessed e.g whining results in lollipop being taken away

Intrinsic vs extrinsic punishment
Intrinsic
○ The behaviour performed is inherently punishing e.g less likely to lift heavy object
Extrinsic
○ The event that follows the behaviour is punishment e.g being chastised after
posting something inappropriate

Primary vs secondary punishers
Primary
○ Events that are inherently / innately punishing e.g intense heat, loud noises,
hunger pangs
Secondary
○ An event that has become punishing because it in the past has been associated
with some other punisher

Problems with use of punishment
1. Punishment of an inappropriate behaviour does not directly strengthen the occurrence of
appropriate behaviour, may result in a suppression of behaviour e.g punishment for
swearing may reduce all verbal interactions
2. The person delivering the punishment could become a discriminative stimulus for
punishment. The unwanted behaviour is suppressed only when that person is present
e.g speed is only curbed when speed cameras are present
3. Might teach individual to avoid that person or context e.g choose alternative route
4. Likely to elicit a strong emotional response, may interfere with any subsequent attempts
to teach appropriate behaviour
5. Can elicit an aggressive reaction, directed at punisher or other target
6. Might teach them that punishment is an acceptable means of controlling behaviour,
employee gets shouted at and then takes it out on partner
7. Use is often strongly reinforced, punisher may use it more often
Benefits
Lang and Melamed 1969 used punishment to stop psychogenic vomiting and rumination in a 9
month old boy. Brief and repeated mild shocks that shocked him when he started vomiting, by
third session, one or two shocks made him stop vomiting, and then he was dismissed from the
hospital 5 days later

Effective use of punishment
1. Should be immediate
2. Should be intense enough from the outset to suppress the target behaviour
3. Should consistently follow each occurance of the unwanted behaviour
4. Negative punishment is generally preferable to positive punishment- less harmful side
effects
5. More effective when accompanied by an explanation
6. Should be combined with positive reinforcement

Conditioned suppression account
Does not directly weaken behaviour but proces emotional response that interferes with
the occurrence of the behaviour
E.g when a rat is shocked, it becomes too frightened to press the lever. Lever response
is omitted by fear response
Ie replaced behaviour with emotional response or another behaviour that interferes with
being able to produce it
Effects of punishment are temporary

Avoidance account
Punishment involved avoidance learning in which the avoidance response consists of
any behaviour other than the behaviour that is being punished i.e learn where speed
cameras are
Another example of the permanency of original learning

Summary
There are two types of negative punishment
○ Time out
○ Response cost
Can be intrinsic or extrinsic
Primary or secondary (conditioned)
Number of important problems/limitations of punishment
To be effective it needs to be administered immediately, consistently and be of sufficient
intensity to suppress the behaviour
Number of theoretical accounts of punishment
○ Conditioned suppression account
○ Avoidance learning

Aversive Control: Escape and Avoidance
 Positive punishment motivates escape
○ Escape is getting away from aversive stimulus in progress, results in termination
of an aversive stimulus
Negative reinforcement reinforces avoidance learning
○ Avoidance behaviour occurs before aversive stimulus preventing the delivery of it
Negative contingency between response and aversive stimulus
Results in increase in operant conditioning

Escape
In the presence of aversive stimulus
Make response
Aversive event terminates
Action is negatively reinforced
If there is no escape
Uncontrollable bad events → perceived lack of control → generalised helpless behaviour

If there is escape, and you can anticipate the aversive event before it affects you and evade it?
We have avoidance learning

Avoidance
1. Active avoidance- making a response to avoid event e.g running away
2. Passive avoidance learning not to make a response to avoid a conflict e.g staying quiet

Active avoidance
Rat trained in a shuttle box with a hurdle in the middle
 Tone for 10 seconds then electric shock
If rat avoidance shock when tone comes then the shock is turned off or cancelled
This is called signalled avoidance because the experimenter provides a signal to
indicate when the shock is imminent

Avoidance learning is measured in latency to respond to the signal. This subject avoided shock
on the 9th trial and continued to do so thereafter

Can learn to use SD to avoid US

Passive Avoidance
Passive avoidance using a shuttle box procedure
It is a form of operant conditioning where the person/animal must abstain from an act or reaction
- which will otherwise → have a negative outcome. The animals learn to suppress their normal
dark-seeing reflex because their entry into a dark chamber is paired with a foot shock → learn to
stay on the bright side of the box

Obsessive Compulsive Disorder vs Phobia
OCD typically involves an active avoidance response
Phobic behaviour typically involves a passive avoidance response
Example:
○ A person with OCD will clean frequently or compulsively check things
○ A person with a phobia will avoid object of their fear e.g dogs

Avoidance Paradox
A response/behaviour is made before the aversive stimulus occurs
Behaviour clearly increases, so it is reinforced
What is delivered to reinforce it?
○ Therefore not getting something can hardly, in and of itself, qualify as rewarding
Bit of a problem for behaviourists who need to be able to specify a
stimulus
Not getting punished or injured is rewarding only if punishment is expected i.e only if the
subject is anxious or fearful, and if this expectation in some ways gets reduced

Theories of Avoidance
Mowrer's two process theory of avoidance
1. First the subject learns to associate the warning stimulus with the aversive stimulus
a. This is a classical conditioning process:
b. The warning stimulus of the light in the CS, the aversive stimulus (shock) is the
US
2. Now the subject can be negatively reinforced during the warning stimulus; this is the
second, operant conditioning process
a. Thus the two process theory reduces avoidance learning to escape learning
b. The organism learns to escape from the CS and the fear it elicits

Avoidance conditioning and phobias
Phobia is irrational fear of specific object or situation
Disproportionate to the real threat
Acquisition → classical conditioning
Elevator CS - feeling trapped US - fear UR
Elevator CS - fear CR
Maintenance - avoidance (negative reinforcement)
Elevator SD- avoid elevator RR → reduced fear SR

Support for two factor theory
Two factor theory predicts that the avoidance responding will be learned only to the
extent that the warning signal terminates when a response is made
Kamin 1958 trained four groups of rats in a two chamber avoidance apparatus
 ○ Terminate signal - avoid shock
○ No termination of signal - avoid shock
○ Terminates signal - does not avoid shock
○ Control
Significance amount of avoidance responding occurred in the first group only (response
terminates the signal and enables animal to avoid shock
As predicted by two factor theory, avoidance responding was poor in the group that was
able to avoid shock but could not terminate the signal

Further support
We know that delaying the onset of reinforcement reduces the effectiveness of reward…
so it should be possible to reduce the level of reinforcement by introducing a delay
between the avoidance response and the termination of the feared stimulus
After the avoidance response, the CS was terminated:
○ Immediately
○ 2.5 seconds after response
○ 5 seconds after response
○ Or 10 seconds after the response
As predicted the animals in zero delay avoided successfully in 80% of the trials
10 second delay avoided shock in 10% of trials
Effectiveness of CS termination to support avoidance was decreased by increasing
delay
Results suggest that the source of reinforcement in avoidance conditioning was the
reduction of fear generated by the termination of the CS

Sidman Free-Operant Avoidance
Avoidance can be learned without a warning CS
Shocks at random intervals
Response gives safe time
Extensive training, but rats learn avoidance (errors, high variability across subjects)
Bit of a problem for the two factor theory but
Have trained dogs using this
Every time dog jumped over hurdle, they ensured a shock free period of 30 seconds
Once dogs learned avoidance response, confined to half of the shuttle box and given
discriminative fear conditioning trials
Excitatory can amplify avoidance
Inhibitory can reduce avoidance
Evidence that the conditioned stimuli have acquired drive properties
Supports the two factor theories position that it is the CS that drives the avoidance
response
Solomon Kamin and Wynne (1953) was against two factor theory
Herrnstein and Hineline (1966)

One Factor Theory
Avoidance is negatively reinforced by the lower rate of aversive stimulation to which it is
associated
○ Reduction of aversive stimulation accompanying avoidance maintains avoidance
Which theory is correct?
○ Depends
Several processes seem to be involved in avoidance learning

The fearlessness problem
Fear and avoidance are not firmly linked as the theory believes:
According to the theory, fear provides the motive to perform the avoidance response
Early in experiments a dog would exhibit various signs of fear (whining, urination,
shaking) when tone was presented
But once the avoidance response is well learned subjects respond without apparent fear
Kamin, Brimer, and Black (1963)
Rats pressed lever in chamber for food, then in shuttle box associated auditory with
shock (excitatory such as tone or light) then put back in operant chamber CS+ from
shuttle box presented
 Measured suppression of lever press

Alternation of behaviour (yo-yo)
Every successful avoidance puts CS on extinction
With extinction, fear dops so motivation to avoid decreases
Resulting in more shocks, strengthening CS again and increasing avoidance response
But we don't really see this in dog jumping trial

Persistence of Avoidance
Cognitivists believe avoidance responding is based not on fear but on subjects
expectation that a response will avoid shock
During training, warning stimulus is followed by shock, it is assumed that subjects form
an expectation that shock will occur when the stimulus is presented
When the animal eventually jumps over the barrier to avoid a shock, a new expectation
forms (shock does not occur if the response is made
So the next time th warning stimulus is presented, the animal recalls both expectations
(shock occurs if it doesn't jump but not if it does) and because it prefers not to be
shocked, it will perform the response that produces this outcome

Cognitive explanation of avoidance learning based on expectations
Thus, fear has little role in this theory…it can account for the shortcomings of two factor
theory. First re the disappearance of fear during training
But the animals continue to jump because it still expects shock to occur if it doesn't jump,
and prefers to avoid this outcome
Secondly in the difficulty extinguishing avoidance behaviour this also follows directly
from a cognitive analysis
○ In the absence of a response shock will occur BUT
○ If the response is made the shock will not occur
Early in extinction, the dog holds both of these expectations and therefore responds
And when shock does not occur its expectation that responding will not be followed by
shock is confirmed and therefore continues to jump

Response prevention → extinction
Animals don't get a chance to learn what would happen if they did not jump
Cognitive theory of avoidance
Fear allows it to explain the continuation of avoidance responding in the absence of fear,
but not for the same reason it has difficulty explaining evidence that fear does influence
avoidance

Other factors: response problem
Experimenters tried to teach rats to press a bar to avoid press
Hundreds of trials are needed to learn to press a bar to avoid shock and yet many never
do
Because each species have species specific defence reactions, so the particular SSDR
that occurs depends on
○ Nature of aversive stimulus
○ Response opportunities provided by the environment

SSDR
Innate, evolved reactions
If familiar escape route is there they can do, otherwise can freeze
Predominate in initial stages of avoidance
Hierarchy
○ If SSDR works, keep it
○ If not try next

Summary
Positive punishment/aversive events motivate escape beahviours wich are strengthened
via negative reinforcement
Involves avoiding the aversive event before it occurs
Avoidance learning can take passive or active form
Number of theories of avoidance
○ Two factor
 Classical and operant conditioning are involved
Avoidance is driven by an escape from fear, not prevention of aversive
event
○ Cognitive theory of avoidance
Responding is based on fear but on subjects expectation that a response
will avoid an aversive stimulus
Species specific defence responses (SSDR’s
○ Innate response to threat or fear
Some avoidance behaviours are more easily learned than others

Week 7 Lecture- Behavioural Neuroscience: Genetics
Behaviour is the response of an individual to a stimulus (trigger) in the environment
Some people (species) respond differently to a similar environments because of:
○ Their genetic make-up (nature)
Evolution (e.g human vs bird)
Parental traits (colour of skin, height, intelligence, ability to sing)
○ Factors in their environment (nurture/experience)
How they are feeling (hungary, tired, hot etc)
Previous experiences (or taught a skill or how to behave)
Culture

Genetics
Chromosomes
Found in every cell
Genes drive the function of our cells
46 chromosomes- 23 pairs, it is unusual to see chromosomes as single structures as
they are usually in a replicated stage, there are two of each (sister chromatids) joined
together at the centromere
Females - XX
Males- XY
Females always contribute X and males do XY- sex of offspring is alwasy determined by
the male

Genes
Regions of DNA that are units of hereditary (information can be passed from one
generation to another)
DNA= double strands of nucleotide “base pairs” on chromosomes
These are in the nucleus of cells
DNA = deoxyribonucleic acid

Nucleus
 Membrane bound part of a cell which contains all genetic information to promote survival
of the cell (organism)
Cells are present in all body parts- groups of cells make an organism
Each cell contains a nucleus and contains chromosomes made up of genes

What and Why Genes
Chromosomes are made up of genes
Particular sequences of DNA are genes
DNA in each gene programmes the manufacturing of different proteins for use in the
body
Proteins are made with amino acids
Amino acids are obtained from our diet and are the building blocks of life

9 Essential Amino Acids
20 used to make proteins
9 of these are essential for us to make proteins which makes us live
○ Histidine
○ Isoleucine
○ Leucine
○ Lysine- beans
○ Methionine
○ Phenylalanine
○ Threonine
○ Tryptophan- can be found in turkey, sesame seeds
○ Valine

DNA makes proteins essential for life
The sequence of amino acids to form the protein is determined by an intermediate RNA
(ribonucleic acid) from DNA
DNA is self replicating molecule
Each base determines one base of RNA
RNA Copy of one strand of the DNA
A TRIPLET of bases determines one amino acid
Formation of proteins by combining amino acids Body structures or enzymes

The Making of Proteins
Genetic information gets translated into proteins for use in the body
○ May become biological tissue/cells
○ May become enzymes
○ Enzymes (catalysts) produce chemical reactions so that our bodies function
normally - saliva has an enzyme called amylase which helps us to breakdown the
sugar that we eat
Genetic life cycle:
○ SHIFT COMMAND 4 SLIDE 13
 ○ Replication- essential in cell division when making new cells

Genes-protein-whole body
Group of cells make up an organism
Cells are in protein
Protein → body parts and enzymes

Replication and Division of cells
Cells can be directly replicated to produce more cells with the same genetic information
(Mitosis) Diploid cells
Particular cells divide their genetic information - ready for recombination with another
organism (Meiosis)
Meiosis 1- separation of chromosome pair
Meiosis 2- division of sister chromatids - 4 haploid cells - gametes

SHIFT COMMAND 4 SLIDE 16

SHIFT COMMAND 4 SLIDE 17

Homozygous vs Heterozygous
Recombination of genes allows for the biological expression of different characteristics
(physical or psychological)
Our genes on the chromosomes are responsible for making proteins
They are also responsible for our characteristics
○ Colour of eyes
○ Colour of skin
○ Height
○ Intelligence
○ Predisposed to run fast
If a chromosome contains two identical genes on the chromosome pair we are said to be
homozygous for that gene (characteristic)
If a chromosome contains two different genes (for the same characteristic) we are said
to be heterozygous for that gene
E.g homozygous is blue blue eyes
Heterozygous is brown blue eyes
The characteristic of eye colour is determined by homozygous vs heterozygous genes
and if the genes are dominant or recessive
Dominant genes only require one gene to be presents on the chromosome to produce
that characteristic
Recessive genes require both genes to be present on the chromosome to produce that
characteristic

Eye Colour
For eye colour; brown is dominant B and blue is recessive b
 Recessive characteristics can only be seen if the gene is homozygous

SHIFT COMMAND 4 SLIDE 29

Genetic Alterations
Mutations: alterations of deletions of genetic sequence-may be beneficial or not!
Failure to divide properly in reproduction, get additional genes e.g Down’s syndrome has
3 chromosomes at chromosome 21

Beneficial Mutations
Peppered moth- mutations to black moth
Beneficial during sooty industrial revolution
Many of our ancestral genes are dormant- can we turn them on again?
Newer therapies are aiming at turning genes on or off

Epigenetics and gene expression
Behaviour can be influenced without mutations (permanent genetic changes)
The same genes can be “expressed” or “activated” to different degrees
If the chemical environment in a cell changes, histones tighten or release their grip on
DNA thus regulating the expression of that gene

Heritability
The way we behave is predicted by our genetic make-up and moulded by our
environment
The less an effect of our environment on a particular behaviour shows that the behaviour
has high heritability
High heritability- behaviour is greatly influenced by genes
○ Organisation and cleanliness skills “just like her Mum/Dad”
Low heritability- behaviour is greatly determined by environment
○ Surgeons are trained to be organised and clean
Identical twin studies- nature versus nurture

Evolution of Behaviour
Natural selection: each gene may be kept or eliminated to help survival of a species
(turned on or off?)
If an animal carries a gene to cause slow running, they are likely to be caught and eaten,
limiting their breeding capacity
Survival (and reproduction) of the fittest
Genetic traits that produce an advantage over others in the same species will be kept
(caused through breeding by the survivors)
Traits that produce advantages may change over time (with changes in environment)
Evolution of behaviour depends on the species

Summary
 Our behaviour is partly determined by our genetic make-up
Genes are sequences of DNA
DNA makes up our chromosomes, present in each cell nucleus
DNA provides the information required to join amino acids
Many amino acids joined together are proteins
Proteins are important in our bodies to make new cells or enzymes
Genetic information can be replicated in new cells (Mitosis)
Genetic information can be divided into gametes (Meiosis)
Meiosis enables the recombination (mixing up) of genes through breeding (joining of
gametes)
Some genes are dominant, some are recessive
Behaviours that are determined by genetic make-up have high heritability
Genetic traits that help survival of the species are kept by breeding of survivors that have
that trait

Week 8 Lecture- The Nervous System and Brain Cells
The Nervous Systems
(Everything is simplified)

How do we: feel emotion? Experience reward? See, hear and smell? Co-ordinate movement?
Reason or judge? Learn or remember? Feel pain?
There are gross distinctions between what different parts of the brain do, and also gross
indistinction where they affect each other

Understanding basic human physiology
Promote homeostasis is keeping all cells happy:
Oxygen
Nutrients and water
Balance H and levels PH=7.4
Temperature 37.2 degrees
Rid waste product e.g CO2
H+ = free hydrogen ions

All of these factors are important for cell survival
Cells can only function in the right environment
Too acidic- acidosis, neurons are unable to send messages
Too basic- alkalosis, neurons send uncontrolled messages
Death results if the PH levels are out of the range from 6.8-8.0

Nervous systems
Central (CNS):
Cerebrum
Cerebellum
Brain stem
Spinal cord
Peripheral (PNS):
All nerves outside of the spinal cord
Somatic NS
Autonomic NS

Somatic Nervous System (Voluntary)
Spinal cord; skin, muscle, nerve,, ventral roots and dorsal roots
Sensing environment is dorsal roots on outer side
Ventral and dorsal is different properties
They receive signal and go to brain
Motor signals to move your arm via the ventral system
ALS motor neuron has problems with the ventral roots

Peripheral Nerves
Cranial nerves (12 pairs)
Cervical nerves (8 pairs)
Thoracic nerves (12 pairs)
Lumbar nerves (5 pairs) frequent for back pain
Sacral nerves (5 pairs)
Coccygeal nerve (1 pair)
Lobes of Cerebrum (cortex)

Grey area is cerebellum
Yellow below it is brain stem

Somatic nervous system (voluntary)
Receives sensory information and delivers motor output
Received through dorsal roots
Motor output is delivered via ventral roots to muscle
6 areas that the nerves join the CNS- cranial, cervical, thoracic, lumbar, sacral,
coccygeal
Four lobes of the cerebrum (frontal, parietal, occipital, temporal)
Brain receives sensory information (of touch) at the somatosensory cortex and produces
behaviour by modulating motor output from the primary motor cortex

Autonomic nervous system (involuntary)
Sympathetic- extends from thoracic and lumbar spine
○ Short preganglionic nerves
○ Long postganglionic nerves
Parasympathetic- extends from cranium and sacral spine (craniosacral)
○ Long preganglionic nerves
○ Short preganglionic nerves
Both are usually active, but change intensity as the need arises
Parallel systems that work in opposition together
Increase sympathetic means decreased parasympathetic
Sympathetic is four F’s
○ Fight
○ Flight
○ Fright
○ Fuck
 Parasympathetic is non emergency
○ Digestion
○ Growth
○ Immune responses
○ Energy storage

Pre and post ganglion lengths
Red circle and blue circle
Pre ganglion on sympathetic is longer than post
Post ganglion on parasympathetic is longer than pre
Work in opposition on

Communication of brain to body
Peripheral nervous system
○ Somatic (sensorimotor)
○ Autonomic (parasympathetic, sympathetic)
Hormones
○ Hypothalamus & pituitary (many different hormones)
○ Pineal gland (melatonin)
○ Slower and a wider range of effect as it goes through the blood stre
Consider: speed and range of effect
Many different hormones are released through the pituitary gland and blood flow throughout the
blood

Keeping the brain happy
The brain is highly vascularised (many arteries and veins) which maintain a constant
fresh supply of oxygen and nutrients (glucose) to the brain and cells
The brain is protected and nourished in several ways
○ The blood brain barrier
○ Cerebrospinal fluid (CSF)
○ Glial cells

The blood brain barrier
The blood-brain barrier (BBB) is a crucial immunological feature of the human central nervous
system (CNS). Composed of many cell types, the BBB is both a structural and functional
roadblock to microorganisms, such as bacteria, fungi, viruses or parasites, that may be
circulating in the bloodstream

Crossing the blood brain barrier
Brain capillary endothelial cells have continuous tight junctions
 Only highly lipophilic drugs and small uncharged molecules can cross from blood
capillaries to cerebrospinal fluid (CSF) by diffusion
Important nutrients- amino acids and glucose are actively transported across to CSF by
proteins in the capillary membrane called transporters. Transportation across the
membrane requires energy use

Cerebrospinal fluid and ventricles
Ventricles are big holes in your brain

Order of operations of generating cerebral spinal fluid
1. Created at choroid plexus of lateral ventricle
2. Circulates to 2
3. Then down the cerebellum
4. Then around brain at the top
Ventricles and CFS
CFS is made by choroid plexus in lateral and third ventricles
The ventricles and subarachnoid space circulate cerebrospinal fluid through and around
the brain to provide nourishment and protection (cushioning) of neural tissue
There are four ventricles (lateral, third, fourth and cerebral aqueduct)
Once CFS has circulated around the brain it is reabsorbed by the arachnoid villi (of
subarachnoid space) into venous blood (return to heart)
The cranial and spinal meninges also protect and nourish these ares: dura mater,
arachnoid mater and pia mater

Part 2 Brain Cells
Neuron Network
The human brain has approximately 100 billion neurons and even more glial cells
Huge network for communication and complex processing
White vs Grey matter

Grey matter is neuronal cell bodies
White matter is the axon before the cell body covered in the fatty sheath

Discovering brain cells was not easy
Neurons
Glial cells- astrocytes and oligodendrocytes
Ependymel cells- line with the CSF filled ventricles (neurogenesis)
Microglia- remove dead or degenerating neurons or glia (phagocytosis)

Neurons
Most have 4 main parts:
Soma- middle, nucleus
Dendrites- spiny bits around receive signals
Axon- if fires, passes down axon
Presynaptic terminals- to here, and then they communicate with other cells

Typical Neuron
Axon + Dendrites = Neurites
Classification of Neuron Type
Neurons are classified by
The number of neurites from cell body
Their dendrites- how many and if they have spines or not
Their axon length
○ Golgi type 1- long “internuncial”
○ Golgi type 2- small “interneurons”
The neurotransmitter used by the neuron
Neuronal connections- primary sensory neurons or motor neurons

Classification by neurites
Cells can be unipolar, bipolar or multipolar- defined by the number of neurites connected
to the soma
Pyramidal cells:
○ An apical dendrite extends from the apex of the pyramidal cell soma
○ Basilar dendrites are connected to the base of the soma (not the axon)

Classification by Dendrites
Neurons are classified by the shape and kind of dendrites
Stellate (starshaped A or D on slide 6) vs pyramidal (triangular)
Has spines (spinous) or doesn’t have spines (aspinous)
Dendritic spines are involved in learning and memory
Dendritic trees constantly change (grow or recede)- aids in neuroadaptation
Dendrites are sources of information for the neuron- the more dendrites the more info
the neuron receives

Grey area is a amyloid plaque, the cell that's near the plaque has fewer dendrites than ones
further away
More plaques has memory and learning problems, less dendrites is associated with
memory loss and cognitive deficits in Alzheimer’s disease

Afferent vs Efferent Neurons
Afferent is to the connection
Efferent is from the connection
 They are not touching, they are very close together ad the arriving neurotransmitter
releases its energy into the space and then the exiting can pick it up

Summary
Cortex is composed of white (myelinated axons) and grey matter (neuron cell bodies)
Brain and cells consist of neurons, glial cells (glia), ependymal cells and microlglia
There are 4