PSYC 281 History-Associationism-Neural Bases PDF

Summary

This document presents the history of learning and memory, focusing on associationism and the neural basis of learning. It covers topics like Aristotle's principles of association, the work of the British Associationists, and the experiments of Ebbinghaus. The document also explores the biological basis of learning and the role of neurons and neurotransmitters.

Full Transcript

 Early theories and thinking on memory:
Aristotle and the British Associationists
 Experimental findings from Ebbinghaus
 Neural basis of learning:
 The characteristics of a neuron
 How sensory receptors generate simple
sensations
 The major changes in the brain during
learning
 Aristotle proposed 3 principles of
associations:
Contiguity—The more closely
together in space or time two items
occur, the more likely the association
Similarity—Thought of one concept
often leads to the thought of a similar
concept
Contrast—An item often leads to the
thought of its opposite
1. apple
2. night
3. thunder
4. bread
5. chair
6. bat
7. girl
8. dentist
9. quiet
10. sunset
11. elephant
12. blue
 The British Associationists: Theory of
Knowledge
 Empiricists: Knowledge via experience
 Nativism: Some Knowledge is innate
 James Mills’ view of “Complex Ideas”:
Two or more simple sensations are
repeatedly presented together, a product
of their union may be a complex idea.
 Included figures like Thomas Hobbes,
John Locke, James Mill, John Stuart
Mill
 Everyone acquires knowledge
empirically through experience, and
every idea, concept, etc. is based on
previous experiences.
 John Locke (1690): “tabula rasa”
 Developed hypotheses about how
concepts are associated in the
memory.
 Opposite of associationism
 Certain types of knowledge are innate
 Immanuel Kant (1781): Concepts of time and
space are inborn.
 New concepts acquired through experience on
top of this innate knowledge.
 Role of experience is thus acknowledged.
Experience Memory

Sensations Ideas
 Several
sensations Ideas

 Sensations of
REDNESS
Rectangularity
 James Mill
 Two or more sensations  a COMPLEX
IDEA
 Complex ideas  DUPLEX IDEAS
 Mill also stated that
 Complex ideas can retrospectively be broken into
two or more simple ideas
 Ideas –complex or duplex- are always
formed through repeated pairings of
simple ideas
 Similar to the critique of Aristotle
 Developmental evidence
 Addition before multiplication
 Sometimes children acquire some complex
concepts before they attain simple ideas
 Though valid, in most parts an incomplete
theory.
 Brown tried to fix
inefficiencies of
Aristotle’s principles

 An important enterprise
as all of these principles
were later put to
empirical test by
contemporary scientists.
 Length of Time
coexistence of two events  strength of association
 Liveliness
vividness of sensations affect stregth of associaton
 Frequently
frequent pairing of events
 Recently
the recency of pairing
 Free From Strong Associations
whether both sensations are paired with other sensations stronger
 Constitutional Differences
individual differences
 Emotional State
how one feels at the time of association
 State of the Body
whether the person is healthy, ill, drunk, etc.
 Prior Habits
prior (previous) experience
 Nonsense syllables (e.g., HAQ, PIF, ZOD)
 How many repetitions are necessary for perfect recall?
 The concept of savings—The decrease in the number
of repetitions needed to relearn the list
 Confirmed Brown’s Secondary Principles of Association

1st time: 25 repetitions for
perfect recall
2nd time: 15 repetitions for
perfect recall
Savings= 10 repetitions or
10/25=40%
 Correlation between list
length and study time
 Repetition strengthens
the association
 The Forgetting Curve
 Passage of time has
detrimental effect
 Contiguity: Association
strength depends upon
proximity
 The concept of Backward
Association
 Assoc. Prediction 
 Much less saving
 Associationists
 No empirical work
 Interest in knowledge and thought processes
 Relationship between simple and complex ideas
 Ebbinghaus
 Behavioural approach with observable stimuli
 DV: savings
 Tangible measurements to the satisfaction of
behaviourists
 No theory about thought needed as his results are
good enough to put them into practice
 Overlearning: increased amount of savings
 Order of learning: forward vs. backward learning
 Learning takes place at three levels (Domjan, 2005)
 Cellular/molecular
 Physiological
 Behavioural (what PSYC281 is about!)
 Essentials
 Research: Brain  Behaviour
 Learning requires a nervous system
 Some basic physiological knowledge
 Sensory system captures information from the
environment
 Psychology  How do we hold and process this
information?
 Basic units of the nervous system.
 10-100 billion in the brain
 Each neuron connects up to 30000 neurons
 Three types of neurons:
 Sensory neurons (afferent neurons) transmit
information from sensory cells (receptors) to the brain
– directly or via spinal cord.
 Interneurons - majority in brain and spinal cord
 Motor neurons (efferent neurons) transmit
commands from interneurons to glands and muscles
via spinal cord – voluntary and involuntary.
 Nervous system of all
creatures are
composed of neurons
 The neuron consist of
cell body (soma),
dendrites, axon,
transmitter, and
synapse
 Neurons are
specialized cells that
transmit information
 Dendrites receive information from
other cells.
 Cell body contains a nucleus that
features the genetic information that
determines how input via dendrites are
treated.
If there’s enough stimulation,
manipulated input passed through the
axon.
 Axon transmits the manipulated
information to other cells via axon
terminals.
https://www.toppr.com/content/story/amp/structure-and-function-of-neuron-3311/
 Myelin sheath  On the axon is a coat of cells made up of lipids – the
‘white matter’. Gray matter – cell bodies, dendrites, unmyelinated axons.
 Insulates the axon, from other chemical, and physical stimuli.
 Increases the speed of transmission along the axon.
 Myelinasation isn’t complete at birth for several neurons.
 Multiple sclerosis (MS)  A disease of demyelinasation.
 Terminal buttons send signals to adjacent neurons
 Connection between neurons occur at synapses.
 Note that the two neurons DO NOT touch each other
but the communication occurs through a space called
synaptic cleft (synaptic level)
 Dendrites and cell body are
receptive to chemicals called
“transmitters” that are
released by other neurons
 These transmitters produce
excitation or inhibition in
the postsynaptic cell
 A neuron’s firing rate
reflects the combined
influences of all its
excitatory and inhibitory
inputs
https://www.youtube.com/watch?v=W2hHt_PXe5o&t=1s
https://www.toppr.com/content/story/amp/structure-and-function-of-neuron-3311/
 Receptors—Specialized neurons
designed to break down incoming
stimuli into simple sensations
 Types of receptors
Tactile
Taste
Auditory
Olfactory
Visual
 Mills: a hierachy of ideas
 Simple  complex (bottom-up?)
Duplex ideas
 Hubel & Wiesel (1965, 1979) (e.g., house)
 Feature detectors: each neuron
responds to a specific visual
Complex ideas
stimulus. (e.g., brick)
 Present in the visual cortex

Simple ideas
(e.g., redness, rectangularity)
 Feature detectors in visual cortex
 Simple Cells respond to lines at a 45-degree angles
 Single Neuron Doctrine of Perception
 Sensory systems arranged hierarchically based on
level of complexity of stimulation.
 The higher the more specific.
 Changes in brain during learning
 Synaptic level chemical changes
 Neural growth
 Increase strength of excitatory
synapses
 Implicated in storage of long-term
memory
 Hippocampus and cerebral cortex
 Long-term potentiation 
basic process of learning
 What type of chemical changes?
 Increased capacity to release
neurotransmitter
 Postsynaptic cell membrane
becomes more sensitive to
neurotransmitters
 Animal Studies and enriched living
environments
 Human studies and arborization
 The branching of dendrites prior to birth
and during the first year of life
 Other connections disappear
 Maturation or learning?
 Both show increased
dendritic branching
with learning
 Previous researchers believed no new
neurons appeared after infancy
 Recent studies have found new
neurons in adult monkeys
 Evidence exists that clinical
depression may be associated with
low levels of neurogenesis.
 Learning produces neuronal changes that
are distributed diffusely over many
sections of the brain—Karl Lashely (1950)
 Information about individual concepts are
stored in small specific sections of the
brain—Penfield (1959)
 Results’ significance  not clear.
 Best evidence: lesioned brains.
 Aristotle proposed the principles of
contiguity, similarity, and contrast
 Repeated presentation of two or more
simple ideas can lead to the formation of
complex ideas
 Ebbinghaus demonstrated several basic
principles of learning
 Learning something new correlates with
changes in the brain or nervous system