Biological Psychology Chapter 12: Learning & Memory Lecture Notes PDF

Summary

Chapter 12 of the Biological Psychology textbook focuses on learning and memory. The lecture notes explore different types of memory, the process of memory formation (e.g. encoding, consolidation, storage, and retrieval), and areas of the brain involved in these processes. Specifically, it details the roles of the hippocampus, striatum, and other brain regions.

Full Transcript

Biological Psychology
Thirteenth Edition

Chapter 12
Learning & Memory

© 2019 Cengage. All rights reserved.
 Localized Representations of Memory
(1 of 2)
Classical conditioning
– Pioneered by Ivan Pavlov
– Pairing two stimuli changes the response to one of them
 Conditioned stimulus
 Unconditioned stimulus
 Unconditioned response
 Conditioned response

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Classical Conditioning

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 Amygdala: Plays a crucial role in associating stimuli with
emotional responses, especially fear. It's essential for
forming conditioned emotional responses.
Cerebellum: Involved in the motor learning aspect of
classical conditioning, particularly in simple reflexes like
eyeblink conditioning.
Prefrontal Cortex: Engages in higher-order thinking and is
involved in inhibiting or adjusting responses based on
learned associations.
Hippocampus: Although not directly involved in forming
stimulus-response connections, it contributes to forming
the context in which conditioning occurs, particularly
when multiple stimuli are involved or when spatial or
temporal context matters.
 Localized Representations of Memory
(2 of 2)
Instrumental conditioning
– Also known as operant conditioning
– Individual’s response followed by reinforcer or punishment
– Reinforcers
 Events that increase the probability that the response will
occur again
– Punishment
 Events that decrease the probability that the response will
occur again

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Instrumental Conditioning

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 Dopaminergic Pathways (VTA and Nucleus Accumbens): The ventral
tegmental area (VTA) and the nucleus accumbens are central to the
brain's reward system. Dopamine release in these areas reinforces
behavior that leads to positive outcomes (rewards).
Striatum (Basal Ganglia): Involved in habit formation and the
reinforcement of action-outcome associations. The basal ganglia
help encode the "habitual" aspects of learned behavior.
Prefrontal Cortex: Plays a role in decision-making and evaluating
outcomes, helping to adjust behavior based on past experiences of
reward or punishment.
Amygdala: Involved in associating rewards and punishments with
emotional responses, making certain consequences more
motivating or aversive.
Anterior Cingulate Cortex: Important for error detection and
conflict monitoring, allowing for learning from mistakes and
adjusting behavior to avoid negative outcomes.
 Lashley’s Search for the Engram
Engram
– Karl Lashley believed that specific memories were localized in
certain areas of the brain. He thought that if he could identify and
damage the exact brain area where a memory was stored, the
subject (usually a rat) would lose that particular memory.
– Hypothesis disproven
Lashley’s experiments showed that learning and memory do not rely on a
single cortical area
Lashley’s principles about the nervous system
– Equipotentiality: all parts of the cortex contribute equally to complex
functioning behaviors (e.g., learning)
– Mass action: the cortex works as a whole, and more cortex is better

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View of Rat Brain, Showing Lashley’s
Brain Cuts in Various Rats

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 Types of Memory

Hebb (1949) differentiated between two types of
memory:
– Short-term memory: memory of events that have just
occurred
– Long-term memory: memory of events from times further
back

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Differences Between Short- and Long-Term
Memory
Short-term memory has a limited capacity, but long-term memory does
not
Short-term memory fades quickly without rehearsal, while long-term
memories persist
Long-term memories can be stimulated with a cue/ hint
– Short-term memories cannot
Researchers propose all information enters short term memory
– The brain consolidates it into long-term memory
Later research weakened the distinction between short- and long-term
memory
– Not all rehearsed short-term memories become long-term memories
– Time needed for consolidation varies

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 Our Changing Views of Consolidation

Emotionally significant memories form quickly
– Locus Coeruleus increases release of norepinephrine
– Emotion causes release of epinephrine & cortisol to
activate amygdala and hippocampus—enhances
consolidation of recent experiences
Working memory
– Proposed by Baddeley & Hitch as an alternative to short-
term memory
– Emphasis on temporary storage of information to actively
attend to it and work on it for a period of time

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Short-Term Memory
Characteristics:
Duration: Lasts for about 15-30 seconds without rehearsal.
Capacity: Limited to 5-9 items (known as Miller’s Law).
Function: Allows immediate recall of information, like
remembering a phone number long enough to dial it.
Prefrontal Cortex: Responsible for the active maintenance of
information for brief periods. It’s critical in keeping things
"online" for a short time.
Parietal Lobes: Also involved in holding onto certain types of
sensory information briefly, especially in spatial memory
tasks.
 Long-Term Memory
Types of Long-Term Memory:
Explicit (Declarative) Memory: Conscious memories that can be verbalized.
Episodic Memory: Memory of specific events or experiences (e.g., your last
birthday).
Semantic Memory: General knowledge or facts (e.g., knowing that Paris is
the capital of France).
Implicit (Non-declarative) Memory: Unconscious memories, such as skills or
habits.
Procedural Memory: How to perform tasks like riding a bike or playing an
instrument.
Classically Conditioned Responses: Emotional responses or learned
reflexes.
Hippocampus: Plays a central role in forming and consolidating new explicit
memories. Damage to the hippocampus can result in difficulty forming new long-
term memories (anterograde amnesia).
Cerebral Cortex: Where long-term memories are stored once consolidated.
Different types of memories (e.g., visual, auditory) are stored in corresponding
sensory areas.
Basal Ganglia & Cerebellum: Important for procedural memory and motor skills.
 Working Memory
Working memory is a more complex system than short-term memory. It
involves not only temporarily holding information but also manipulating it.
Working memory is crucial for reasoning, problem-solving, and decision-
making. Unlike short-term memory, working memory involves actively
processing and manipulating the information, such as doing mental math or
holding a conversation while forming responses.
Dual Processing: Can handle multiple types of information simultaneously (e.g.,
visual-spatial data while listening to verbal instructions).
Limited Capacity: Similar to STM, it can only handle a few items at a time.
Prefrontal Cortex: Essential for the active maintenance and manipulation of
information. The prefrontal cortex is crucial for the central executive functions
of working memory.
Parietal Cortex: Works with the prefrontal cortex in spatial and attentional
aspects of working memory.
Dorsolateral Prefrontal Cortex (DLPFC): Involved in maintaining and
manipulating information over short periods, especially when tasks require
complex problem-solving or reasonin
Components of Working Memory (Baddeley’s Model):
Central Executive: The "manager" that directs attention
and coordinates activities of the other components.
Phonological Loop: Handles verbal and auditory
information (e.g., repeating a phone number to
yourself).
Visuospatial Sketchpad: Manages visual and spatial
information (e.g., mentally rotating objects).
Episodic Buffer: Integrates information across
modalities and connects working memory with long-
term memory.
 The Hippocampus and Spatial Memory

Navigation depends on your surroundings and your
spatial memory
Damage to the hippocampus also impairs abilities on
spatial tasks such as:
– Radial mazes: a subject must navigate a maze that has
eight or more arms with a reinforcer at the end
– Morris water maze task: a rat must swim through murky
water to find a rest platform just underneath the surface

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 Hippocampus and Spatial Memory
The hippocampus plays a central role in forming and using cognitive maps—
mental representations of spatial environments. It enables you to understand
and recall where things are in relation to one another.
1.Place Cells:
1. Inside the hippocampus, there are specialized neurons called place cells.
These cells become active when an individual is in a specific location within
an environment.
2. When a person or animal moves, different place cells activate, allowing the
brain to map out spatial relationships and locations.
2.Memory for Routes and Landmarks:
1. The hippocampus allows us to remember specific routes or paths we’ve
taken and to recognize and use landmarks to guide us.
2. This ability helps in learning and recalling not just the current environment
but also new environments and spatial layouts.
3.Integration with Other Brain Regions:
1. The hippocampus works closely with other parts of the brain, like the
entorhinal cortex, which contains grid cells. These cells provide a grid-like
coordinate system to help track movement through space.
 Striatum
Procedural Memory:
Striatum’s Role: The striatum is essential for procedural memory
because it helps in learning and automating repetitive tasks through
practice.
Once a task becomes automatic, the striatum allows it to be
performed without conscious effort.
Habit Formation:
Striatum’s Role: The striatum is heavily involved in forming and storing
habits.
It helps encode the stimulus-response associations that underpin habit
formation, where repeated behaviors become automatic over time.
The more a behavior is practiced, the more the striatum strengthens
the neural circuits involved, making the behavior habitual.
Instrumental (Operant) Conditioning:
Striatum’s Role: The striatum plays a key role in
reinforcing actions that lead to positive outcomes.
It helps encode the associations between actions
and rewards, influencing decision-making and
reinforcing behaviors based on past experiences of
reward or punishment
Working Memory:
Striatum’s Role: While the prefrontal cortex is the
main area responsible for working memory, the
striatum contributes to tasks that require the
integration of cognitive and motor functions, such
as task-switching or learning sequences of actions.
 Implicit Memory: The striatum supports memories
that are not consciously recalled but influence
behavior, such as habits and procedural tasks.
The striatum has strong connections with the
prefrontal cortex, which is involved in executive
functions and decision-making.
It also receives input from the dopaminergic
neurons of the substantia nigra and ventral
tegmental area (VTA), which are critical for
processing rewards and reinforcement learning.
Outputs from the striatum project back to the
thalamus and other areas of the basal ganglia,
forming circuits that regulate movement, habits,
and learning.
 Hippocampus vs. Striatum
However, most tasks activate both systems
Hippocampal learning at the beginning of a task, but once the
task becomes “habitual” or “automatic,” more emphasis on
striatum
The hippocampus is associated with declarative (explicit)
memory, such as the memory of facts and events.
In contrast, the striatum is associated with non-declarative
(implicit) memory, such as skills and habits.
While the hippocampus helps with the formation of memories
that require conscious recall (e.g., remembering what you
learned in class), the striatum supports memory for tasks that
become automatic and routine over time (e.g., driving or
typing).
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 Brain Areas for Two Types of Learning

Hippocampus Striatum

Speed of learning Can learn in a single trial Learns gradually over many trials

Type of behavior Flexible responses Habits

Based on what type of Sometimes connects information Generally requires prompt
feedback? over a delay feedback

Explicit or implicit Explicit Implicit
learning?

What happens after Impaired declarative memory, Impaired learning of skills and
damage? especially habits
episodic memory

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 OTHER BRAIN AREAS IN MEMORY AND
LEARNING
Amygdala
Function: The amygdala is key for processing emotional memories, particularly
those related to fear and pleasure.
Role in Learning: It enhances the encoding of memories that are emotionally
charged (e.g., traumatic events or joyful experiences). Emotional arousal often
strengthens the consolidation of memories.
Emotion and Memory: The amygdala interacts with the hippocampus to
prioritize the storage of emotionally significant memories.
Damage: Damage to the amygdala can impair the ability to remember
emotional events, though factual memory may remain intact.
Temporal Lobe (Cortex)
Function: The temporal lobe, particularly the medial temporal lobe, includes
the hippocampus and plays a crucial role in declarative memory and language
learning.
Role in Learning: It helps in the encoding, storage, and retrieval of explicit
memories. It also processes auditory information, which is essential for
learning language and music.
Damage: Damage to the medial temporal lobe can cause memory deficits,
particularly in forming new long-term memories.
Cerebellum
Function: The cerebellum is involved in procedural memory and motor
learning, helping us learn skills and habits, such as riding a bike or playing
an instrument.
Role in Learning: It helps automate repetitive, coordinated movements
and is essential for classical conditioning, particularly in motor tasks.
Damage: Damage to the cerebellum can impair motor learning and the
ability to perform coordinated movements, but it may not affect explicit
memory for facts or events.
Parietal Cortex
Function: The parietal cortex contributes to spatial learning and memory,
helping us navigate our environment.
Role in Learning: It is involved in processing sensory information and
working with the hippocampus to create cognitive maps of our
surroundings.
Damage: Damage to the parietal cortex can lead to difficulties in spatial
orientation and recalling the spatial layout of environments.
Prefrontal Cortex
Function: The prefrontal cortex is involved in working memory (the temporary
holding and manipulation of information) and higher cognitive functions like
decision-making, planning, and problem-solving.
Role in Learning: It helps manage and manipulate information in working
memory, which is necessary for complex tasks, reasoning, and learning new
concepts.
Executive Functions: The prefrontal cortex also contributes to goal-directed
learning, where individuals use feedback to adjust behaviors to achieve
specific outcomes.
Damage: Damage to this area can affect short-term memory, attention, and
the ability to plan or make decisions.
Dopaminergic System (Ventral Tegmental Area and Nucleus Accumbens)
Function: The dopamine system is essential for reward-based learning and
motivation.
Role in Learning: The release of dopamine, particularly in the nucleus
accumbens and ventral tegmental area (VTA), signals the brain that a behavior
is rewarding, helping to reinforce actions that lead to positive outcomes.
Reinforcement Learning: This system helps form associations between actions
and their rewarding consequences, which is key for learning new behaviors
based on rewards and punishments.
 Learning and Memory Processes in the Brain
1.Encoding:
1. Information is first processed and "encoded" in the brain. This involves
converting sensory input (visual, auditory, etc.) into a form that can be
stored.
2. Brain Areas: Hippocampus (for declarative memories), sensory areas (for
initial processing).
2.Consolidation:
1. After encoding, the information must be stabilized to form long-term
memories. This often happens during sleep, where memories are replayed
and strengthened.
2. Brain Areas: Hippocampus and cortex (especially during sleep).
3.Storage:
1. Memories are stored in distributed networks across the brain, particularly in
the areas involved in processing that type of information (e.g., visual
memories in the visual cortex, motor memories in the cerebellum).
2. Brain Areas: Sensory cortices, hippocampus, and association areas.
4.Retrieval:
1. Retrieval is the process of bringing stored information back into conscious
awareness. This can involve remembering facts, events, or skills.
2. Brain Areas: Prefrontal cortex (for retrieval), hippocampus (for reactivating
stored memories).
 Learning and the Hebbian Synapse

Hebbian synapse
– A synapse that increases in effectiveness because of
simultaneous activity in the presynaptic and postsynaptic
neurons
– Such synapses may be critical for many kinds of
associative learning
If Neuron A repeatedly causes Neuron B to fire, the synaptic
connection between these two neurons becomes stronger.
Over time, Neuron A will need less stimulation to activate
Neuron B, and the connection becomes more efficient.

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Steps of Hebbian Learning:
1.Neural Firing: When the presynaptic neuron (Neuron
A) releases neurotransmitters across the synapse, it
activates the postsynaptic neuron (Neuron B).

2.Simultaneous Activation: If Neuron A and Neuron B
are consistently activated at the same time, the
synaptic connection strengthens.

3.Synaptic Potentiation: As this connection strengthens,
it becomes easier for Neuron A to excite Neuron B in
the future, leading to more efficient communication.
Long-Term Potentiation and Short-Term Potentiation
in Learning and Memory
Long-term potentiation (LTP) and short-term potentiation (STP) are critical
processes involved in synaptic plasticity—the ability of the brain to change and
strengthen synaptic connections in response to experience.
Short-Term Potentiation (STP)
Short-term potentiation (STP) refers to the temporary strengthening of synaptic
transmission that occurs over a short period, typically lasting from milliseconds to
a few minutes. STP does not involve long-lasting changes in the structure or
function of the synapse and is typically used for short-term processes, such as
immediate memory or working memory.
Duration: Lasts seconds to a few minutes, making it a short-lived phenomenon.
Cause: Usually results from an increased availability of neurotransmitters (like
glutamate) or enhanced responsiveness of postsynaptic receptors.
Reversibility: If the increased stimulation ceases, the synaptic strength quickly
returns to baseline levels.
No Structural Change: STP does not involve structural changes in neurons or
synapses. It is mainly a functional change in neurotransmitter release or receptor
sensitivity.
 Mechanisms of STP:
Increased Neurotransmitter Release: With repeated stimulation of a
presynaptic neuron, there can be an accumulation of calcium ions in the
presynaptic terminal. This extra calcium causes the neuron to release
more neurotransmitters into the synaptic cleft.
Postsynaptic Changes: The postsynaptic neuron might become more
responsive to neurotransmitters, usually through increased receptor
activity (e.g., glutamate binding to NMDA or AMPA receptors).
Temporary Potentiation: The increased neurotransmitter release
temporarily enhances the strength of the synaptic connection, but this
effect diminishes as calcium levels return to normal.

Short-Term Memory: If you’re memorizing a phone number for a few
seconds before dialing it, your brain might use STP. The synaptic
connections between neurons involved in storing the number are
temporarily enhanced, allowing you to retain the information briefly. Once
you dial the number and no longer need to remember it, the potentiation
fades, and the synapses return to their normal strength.
 Role in Learning and Memory:
STP is thought to play a role in the early stages of learning
by facilitating rapid, temporary changes in synaptic strength.
While STP alone is not sufficient for long-lasting memory, it
helps form the initial steps in the learning process by
temporarily enhancing communication between neurons.
Hippocampus: STP is most commonly studied in the
hippocampus, which is critical for learning and memory,
especially spatial memory and declarative memory (facts
and events).
Cerebral Cortex: Plays a role in short-term memory,
particularly in areas responsible for sensory processing.
 Long-Term Potentiation in Vertebrates

Long-term potentiation (LTP) occurs when one or more
axons bombard a dendrite with stimulation
– Leaves the synapse “potentiated” for a period of time and
the neuron is more responsive

– https://www.youtube.com/watch?v=4Hm08ksPtMo

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 Long-Term Potentiation
Long-term potentiation (LTP) is the long-lasting strengthening of synaptic
connections between neurons after repeated stimulation. LTP is
considered one of the primary cellular mechanisms that underlie learning
and memory in the brain.
Key Characteristics of LTP:
Duration: LTP can last from hours to days, weeks, or even longer,
providing the basis for long-term memory storage.
Specificity: LTP is specific to the synapses that are repeatedly activated.
Only the synapses involved in the learning process are strengthened.
Associativity: Synapses that are activated together can be strengthened
together, which may explain how associations are formed during learning.
Requires Repeated Activation: LTP typically requires high-frequency
stimulation or repeated co-activation of presynaptic and postsynaptic
neurons.
 Mechanisms of LTP:
1. Postsynaptic Changes:
NMDA Receptor Activation: LTP begins with the activation of NMDA
receptors, which are glutamate receptors located on the postsynaptic
neuron.
These receptors are blocked by magnesium ions (Mg²⁺) at rest but are
unblocked when the neuron is depolarized, allowing calcium ions (Ca²⁺) to
enter the cell.
Calcium Signaling: The influx of calcium triggers intracellular signaling
pathways that lead to the strengthening of the synapse.
This includes the activation of protein kinases, such as CaMKII
(calcium/calmodulin-dependent protein kinase II), which plays a key role in
LTP induction.
AMPA Receptor Insertion: One of the main effects of LTP is an increase in
the number of AMPA receptors on the postsynaptic membrane.
These receptors are also glutamate receptors and are responsible for fast
excitatory neurotransmission.
More AMPA receptors mean that the postsynaptic neuron will respond
more strongly to neurotransmitters.
2. Presynaptic Changes:
Enhanced Neurotransmitter Release: LTP may also involve
changes in the presynaptic neuron that increase the release of
neurotransmitters.
This can happen through retrograde signaling from the
postsynaptic neuron to the presynaptic neuron, prompting it to
release more neurotransmitter (e.g., glutamate).

3. Structural Changes:
Synapse Growth and Formation: Over time, LTP can lead to
structural changes at the synapse.
Dendritic spines (tiny protrusions on the postsynaptic neuron) can
grow or become more stable, providing more surface area for
synapses.
This structural change underlies the long-lasting nature of LTP.
 Role in Learning and Memory:
LTP is considered the cellular foundation for long-term memory
formation.
The strengthening of synapses through LTP allows neurons to
communicate more effectively, which is thought to correspond to
the formation and storage of long-term memories.
Different patterns of LTP might encode different types of
information, such as spatial memory, declarative memory, or
procedural memory.

Learning a New Skill: When learning to play a musical instrument,
repeated practice strengthens the neural connections involved in
motor skills and auditory processing. Over time, LTP helps these
neural pathways become more efficient, so you can play a piece of
music more easily and accurately. The strengthened connections
support the long-term retention of the skill.
The AMPA and NMDA Receptors Before
Long-Term Potentiation

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 Properties of Long-Term Potentiation

Specificity: only synapses onto a cell that have been
highly active become strengthened
Cooperativity: simultaneous stimulation by two or more
axons produces LTP much more strongly than does
repeated stimulation by a single axon
Associativity: pairing a weak input with a strong input
enhances later responses to a weak input
A prolonged decrease in response at a synapse that
occurs when axons have been less active than others
– Compensatory process: as one synapse strengthens,
another weakens

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Associativity in Long-Term Potentiation

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 Long Term Potentiation in Hippocampal
Neurons (1 of 2)
Glutamate attaches to both receptors.
At the AMPA receptor, it opens a channel to let sodium ions
enter.
At the NMDA receptor, it binds but usually fails to open the
channel, which is blocked by magnesium ions.
Repeated glutamate excitation of AMPA receptors
depolarizes the membrane
The depolarization displaces magnesium molecules that
had been blocking NMDA receptors
Glutamate is then able to excite the NMDA receptors,
opening a channel for calcium ions to enter the neuron
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 Long Term Potentiation in Hippocampal
Neurons (2 of 2)
Entry of calcium through the NMDA channel triggers
further changes
Activation of a protein sets a series of events in motion
More AMPA receptors are built and dendritic branching
is increased
These changes potentiate the dendrite’s future
responsiveness to incoming glutamate

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The AMPA and NMDA Receptors
During Long-Term Potentiation

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 Presynaptic Changes

Changes in the presynaptic neuron can also cause LTP
– Extensive stimulation of a postsynaptic cell causes the
release of a retrograde transmitter that travels back to
the presynaptic cell to cause the following changes:
 Decrease in action potential threshold
 Increase neurotransmitter release
 Expansion of the axons
 Transmitter release from additional sites

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Key Differences Between LTP and STP

Long-Term Potentiation Short-Term Potentiation
Feature
(LTP) (STP)

Long-lasting (hours to a Short-lasting (milliseconds
Duration
lifetime) to minutes)

Involves structural Involves temporary
Mechanism changes and receptor changes in
insertion neurotransmitter release
Permanent or semi-
Temporary, no structural
Changes in Synapse permanent, involving new
changes
receptor growth
Supports short-term
Supports long-term
Role in Learning memory and immediate
learning and memory
recall

Learning a new language Memorizing a phone
Example
or skill number briefly
 Improving Memory—Drugs

Understanding the mechanisms of changes that impact
LTP may lead to drugs that improve memory
Caffeine, Ritalin, and Modafinil enhance learning by
increasing arousal
Some herbs have doubtful effects
– Ginkgo biloba
– Bacopa monnieri

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 Habituation
Habituation is a decrease in the strength of a behavioral response
after repeated exposure to a benign, non-threatening stimulus.
Over time, the organism "learns" that the stimulus is not important,
and as a result, it stops responding to it.
Synaptic Mechanisms of Habituation:
Habituation is thought to result from synaptic depression, where
there is a decrease in neurotransmitter release at the synapse
between sensory and motor neurons.
1.Reduced Calcium Influx: With repeated stimulation, the amount of
calcium that enters the presynaptic neuron during an action potential
decreases.
Since calcium is necessary for neurotransmitter release, less
neurotransmitter is released into the synapse.
2.Decreased Neurotransmitter Release: With less calcium entering
the neuron, fewer neurotransmitter-containing vesicles fuse with
the presynaptic membrane.
This results in a reduced amount of neurotransmitter (like
glutamate) being released into the synaptic cleft.
3.Weaker Synaptic Response: On the postsynaptic side, the reduced
neurotransmitter release leads to a smaller postsynaptic potential,
making it less likely to trigger an action potential in the postsynaptic
neuron. As a result, the behavioral response (e.g., reflex) weakens
over time.
Short-Term Habituation: The changes described above (reduced
neurotransmitter release) occur relatively quickly and are transient.
They fade over time, and the response can be restored if the
stimulus is presented after a break.
Long-Term Habituation: With prolonged or repeated exposure
over a longer period, more permanent changes can occur at the
synapse, including a reduction in the number of synaptic
connections (synaptic pruning). This can lead to more long-lasting
habituation.
 Sensitization
Sensitization is an increase in the strength of a behavioral response
following exposure to a strong stimulus. Sensitization makes the
organism more responsive to subsequent stimuli, even if those
stimuli are mild or neutral.
Synaptic Mechanisms of Sensitization:
Sensitization involves synaptic facilitation, where there is an
increase in neurotransmitter release at the synapse, making the
response stronger.
1.Serotonin Release: In sensitization, a strong or harmful stimulus
activates interneurons that release serotonin onto the presynaptic
terminals of sensory neurons.
2.Activation of Second Messengers: Serotonin binds to receptors on
the presynaptic neuron, activating second messenger systems,
particularly cyclic AMP (cAMP), which in turn activates protein
kinase A (PKA).
3.Enhanced Neurotransmitter Release: PKA reduces the closing of
potassium channels, prolonging the action potential in the
presynaptic neuron. This allows more calcium to enter the neuron
during the action potential, resulting in more neurotransmitter being
released.
4.Stronger Postsynaptic Response: The increased release of
neurotransmitter (such as glutamate) into the synaptic cleft causes a
larger postsynaptic response, enhancing the organism’s reaction to
the stimulus.
Short-Term Sensitization: This process happens quickly and lasts for
minutes to hours, depending on the intensity of the stimulus. The
changes are temporary and involve the modulation of
neurotransmitter release.
Long-Term Sensitization: With repeated or prolonged sensitization,
structural changes occur at the synapse, including the formation of
new synaptic connections. This leads to a more permanent increase
in the strength of the response, much like what happens in long-
term potentiation (LTP).
 Amnesia
Anterograde Amnesia
Inability to form new memories after the onset of amnesia. People with
anterograde amnesia can remember events and knowledge from before the
brain injury or trauma but struggle to retain new information.
Causes:
Damage to the hippocampus or nearby structures (e.g., medial temporal
lobes), which are crucial for converting short-term memory into long-term
memory.
Conditions such as Korsakoff’s syndrome (often caused by chronic alcohol
abuse and thiamine deficiency), Alzheimer's disease, or traumatic brain
injury (TBI).
Surgical interventions like removal of parts of the hippocampus to treat
epilepsy (e.g., the famous case of Patient H.M.).
Hippocampus: Critical for encoding new declarative (explicit) memories.
Medial Temporal Lobe: Involved in memory consolidation.
Mammillary Bodies and Thalamus: Damage here can also cause anterograde
amnesia, often linked to Korsakoff’s syndrome.
Retrograde Amnesia
Loss of memory for events that occurred before the onset of amnesia. People
with retrograde amnesia can form new memories, but they may be unable to
recall personal experiences or knowledge from before their brain injury or
trauma.
Causes:
Traumatic brain injury (TBI) due to accidents, falls, or blows to the head.
Stroke, tumors, or brain infections.
Progressive neurological conditions like Alzheimer's disease.
Electroconvulsive therapy (ECT) can cause temporary retrograde amnesia in
some patients.
Cortex: Particularly the temporal and frontal lobes, where long-term
memories are stored.
Hippocampus: While retrograde amnesia often spares the hippocampus, its
connections to other brain areas, like the prefrontal cortex, may be affected.
Thalamus: Involved in memory retrieval.
Type Definition Cause Example

Damage to
Inability to form new Forgetting events after
Anterograde Amnesia hippocampus or medial
memories a brain injury
temporal lobes

Head trauma, stroke, or Forgetting personal
Retrograde Amnesia Loss of past memories neurodegenerative history after an
diseases accident

Both retrograde and Transient ischemic
Temporary memory
Global Amnesia anterograde memory attack (TIA) or mild
confusion
loss stroke
Forgetting events
Post-Traumatic Memory loss after Physical injury to the
surrounding an
Amnesia brain trauma brain
accident

Inability to recall Not remembering
Normal developmental
Infantile Amnesia memories from early events from before age
process
childhood 3

Forgetting a traumatic
Memory loss due to Psychological stress or
Dissociative Amnesia event, such as an
psychological trauma trauma
assault
 Korsakoff’s Syndrome

Brain damage caused by prolonged thiamine (vitamin
B1) deficiency
– Impedes brain’s ability to metabolize glucose
– Leads to a loss of or shrinkage of neurons in the brain
Often due to chronic alcoholism
Distinctive symptom: confabulation (taking guesses to
fill in gaps in memory)
– Also apathy, confusion, and memory loss

© 2019 Cengage. All rights reserved.
 Alzheimer’s Disease
Associated with a gradually progressive loss of memory, often occurring
in old age
– Affects 50 percent of people over 85 and 5 percent of people 65–74
– Early onset seems to be influenced by genes
 99 percent of cases are late onset
No drug is currently effective
Alzheimer’s disease is associated with an accumulation and clumping of
the following brain proteins:
– Amyloid beta protein
 Creates plaques from damaged axons and dendrites and
decreases plasticity
– An abnormal form of the tau protein
 Creates tangles
 Part of the intracellular support system of neurons

© 2019 Cengage. All rights reserved.
Brain Atrophy in Alzheimer’s Disease

© 2019 Cengage. All rights reserved.
Cerebral Cortex of an Alzheimer’s Patient

© 2019 Cengage. All rights reserved.
INTELLIGENCE

© 2019 Cengage. All rights reserved.
 Intelligence refers to the ability to acquire, process, and apply
knowledge and skills to solve problems, adapt to new situations, and
learn from experiences.
In biopsychology, intelligence is explored through the interaction of
biological structures (such as the brain and nervous system) and
psychological processes (like cognition, memory, and problem-
solving).
 Types of Intelligence
General Intelligence (g-factor): Proposed by Charles Spearman, the g-factor refers to a
general cognitive ability that underlies performance in a variety of intellectual tasks.
This theory suggests that individuals who perform well in one cognitive domain (e.g.,
mathematical reasoning) tend to perform well in others (e.g., verbal ability), suggesting a
common underlying capacity.
Multiple Intelligences: Howard Gardner’s Theory of Multiple Intelligences proposes that
intelligence is not a single general ability but rather consists of distinct types:
1. Linguistic: Ability to use language effectively.
2. Logical-Mathematical: Ability to reason and solve mathematical problems.
3. Spatial: Ability to visualize and manipulate objects.
4. Musical: Sensitivity to sounds, rhythms, and music.
5. Bodily-Kinesthetic: Control of bodily motions and handling objects skillfully.
6. Interpersonal: Ability to understand and interact with others.
7. Intrapersonal: Self-awareness and self-regulation.
8. Naturalistic: Understanding of nature and the environment.
Triarchic Theory of Intelligence: Proposed by Robert Sternberg, this theory breaks intelligence
into three parts:
1. Analytical Intelligence: Problem-solving and logical reasoning (similar to the g-
factor).
2. Creative Intelligence: Ability to generate novel ideas and think outside the box.
3. Practical Intelligence: "Street smarts" or the ability to adapt to everyday
challenges.
Prefrontal Cortex: PFC is crucial for executive functions, such as planning, decision-
making, working memory, and problem-solving. It's often referred to as the "seat of
intelligence" due to its involvement in integrating information and controlling complex
behaviors.
Dorsolateral Prefrontal Cortex: Associated with working memory, cognitive flexibility, and
abstract thinking.
Ventromedial Prefrontal Cortex: Involved in decision-making, especially in emotional and
social contexts.Parietal Lobes:
The parietal lobes play a key role in spatial reasoning and manipulating information. The
parieto-frontal integration theory (P-FIT) suggests that intelligence results from efficient
communication between the frontal and parietal regions, integrating sensory and
cognitive information for problem-solving.
Temporal Lobes: The temporal lobes, particularly the left hemisphere, are involved in
verbal intelligence, language processing, and memory. The right hemisphere contributes
to nonverbal, visual-spatial intelligence.
Hippocampus: The hippocampus, important for forming and retrieving long-term
memories, plays a critical role in learning and integrating new information, supporting the
development of intellectual skills over time.
Cerebellum: Although traditionally associated with motor functions, the cerebellum also
contributes to cognitive processes, particularly attention, and the coordination of
complex tasks. Recent research shows that it may play a role in various cognitive
functions, including working memory and executive functioning.
Neural Efficiency and Intelligence
Neural efficiency hypothesis suggests that people with higher intelligence may use
their brains more efficiently.
Faster Neural Processing: People with higher IQ scores often show more efficient
neural activity, especially in the frontal and parietal regions. They may use fewer
neural resources to solve complex problems, indicating more efficient information
processing.
White Matter Integrity: White matter is composed of myelinated nerve fibers that
facilitate communication between different brain regions. Higher intelligence has
been linked to greater white matter integrity, which allows faster and more efficient
neural signaling.
Intelligence and Neurotransmitters
Dopamine: Dopamine is essential for working memory, attention, and executive
functioning. The dopaminergic system, particularly in the prefrontal cortex and
striatum, is involved in the reward-based learning processes that underlie problem-
solving and decision-making
Glutamate: The primary excitatory neurotransmitter, glutamate is crucial for synaptic
plasticity (the brain’s ability to form and strengthen connections) and learning. Long-
term potentiation (LTP), a process involved in forming long-term memories, relies
heavily on glutamatergic signaling.
Acetylcholine: This neurotransmitter supports attention and memory, particularly in
the hippocampus. It is essential for learning and neuroplasticity, playing a role in both
cognitive development and maintaining cognitive function.
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