Chapter_57 Cerebral Cortex, Intellectual Functions of the Brain, Learning, and Memory.pdf

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UNIT XI

Chapter 57:

Cerebral Cortex, Intellectual Functions of
the Brain, Learning, and Memory
Slides by David J. Dzielak, Ph.D

Copyright © 2011 by Saunders, an imprint of Elsevier Inc.
 Physiologic Anatomy of Cerebral Cortex

each area of the cortex is connected to a specific
part of the thalamus.
when thalamic connection is lost cortical function
stops.
all sensory pathways pass through the thalamus
with the exception of the olfactory tract.

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 Thalamic Connections to the Cortex

Figure 57-2

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 Physiological Anatomy of the Cerebral Cortex

Figure 57-5

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 Dominant and Non-Dominant Hemisphere

Wernicke’s area more developed in one
hemisphere, responsible for verbal symbolism and
related intelligence.
95% of population has a left dominant
hemisphere.
Wernicke’s area can be as much as 50% larger in
the dominant hemisphere.

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 Dominant and Non-Dominant Hemisphere (Cont.)

damage to dominant Wernicke’s area leads to
dementia.
non-dominant side related to other forms of
sensory intelligence (music, sensory feelings).

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 Intellectual Functions of the Prefrontal
Association Area

responsible for calling forth stored information and
using it to obtain a goal.
responsible for concerted thinking in a logical
sequence.
– damage causes an inability to keep tract of
simultaneous bits of information, easily distracted.

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 Intellectual Functions of the Prefrontal
Association Area (Cont.)

elaboration of thought.
– prognosticate, plan, consider consequences of
motor actions before they are performed.
correlate widely divergent information, control
one’s activities.

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 Function of the Brain in Communication

“For millions of years
mankind lived just like the animals.
Then something happened which unleashed the
power of our imagination we learned to talk.”

Pink Floyd

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 Pathways for Auditory Communication
5. activation of motor 6. transmission of signals to motor
programs in Broca’s area for cortex to control speech muscles
4. transmission via the
control of word formation
arcuate fasciculus to
Broca’s area

3. formation of the
word that expresses a
particular thought

2. interpretation of the
word and the thought
that the word
expresses in
Wernicke’s area

1. primary auditory
area recognition of the
sound as a word
Figure 57-8 modified

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 Pathways for Visual Communication
5. transmission of signals to motor cortex
to control speech muscles 4. then to Broca’s area for
motor formation of the word

3. visual input reaches full
level of interpretation in
Wernicke’s area

2. processing of the visual
information in the parietal-
temporal-occipital association
cortex, the angular gyrus
region

1. receive the visual input in
primary visual area
Figure 57-8 modified

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 Sensory Aspects of Communication

Wernicke's aphasia

destruction of the
visual and auditory
association areas
results in an inability
to understand the
written or spoken
word.

Figure 57-7

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 Motor Aspects of Communication

speech involves two things
– formation in the mind of thoughts to be expressed and the
choice of words.
– motor control of vocalization and the act of vocalization
formation of word, thought and choice of words is
function of Wernicke’s area.
Broca’s area controls the motor coordination required
for speech.

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 Function of the Corpus Callosum

connects the two hemispheres and allows transfer
of information.
interruption of these fibers can lead to bizarre
types of anomalies.
– dominant hemisphere understands spoken word.
– non dominant hemisphere understands written word
and can elicit motor response without dominant side
knowing why response was performed.

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 Thoughts and Memory

neural mechanism for thought is not known.
most likely a specific pattern of simultaneous neural
activity in many brain areas.
destruction of cerebral cortex does not prevent one
from thinking.
– however, depth of thought and level of awareness
may be less.

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 Memory

change in the capability of synaptic transmission from
neuron to neuron as a result of prior stimulation.
memory trace is a specific pattern or pathway of
signal transmission.
once established they can be activated by the thinking
mind to reproduce the pattern and thus the memory.

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 3 Types of Memory

immediate memory
– lasts for seconds or minutes
short-term memory
– lasts for days to weeks
long-term memory
– lasts for years or for a lifetime

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 Mechanism of Memory

immediate memory may result from synaptic
potentiation through the accumulation of calcium in
the presynaptic membrane.
– would promote neurotransmitter release.
short-term memory may result from a temporary
physical or chemical change in the pre- or
postsynaptic membrane.

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 Cellular Basis for Memory

repetitive stimulation causes a progressive decline in
sensitivity called habituation.
results from progressive decline in the number of
active calcium channels.
less calcium entry less transmitter released.
stimulation of facilitator terminal prevents
habituation.

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 Molecular basis for memory

Transmitter activates G protein
which in turn activates
adenylate cyclase resulting in
an increase
in cAMP

cAMP activates a protein kinase
that phosphorylates a
component of the K+ channel
blocking its activity.

Figure 57-9
this prolongs the action
potential which increases
transmitter release.

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 Long-Term Memory

results from a structural change in the synapse.
increase in the area for vesicular release therefore,
more transmitter is released.
during periods of inactivity the area decreases in size.
enlargement of the release site area results from
synthesis of release site proteins.

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 Consolidation of Memory

converting immediate into short and long-term
memory.
results from chemical, physical and anatomical
changes in the synapse.
requires time.
interruption of the process by electrical shock or
by anesthesia will prevent memory development.
rehearsal enhances consolidation.

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 Brain centers for memory
hippocampus is critical
for long-term memory.

damage causes inability to
form new verbal or
symbolic long-term memory
anterograde amnesia.

hippocampus is involved in
determining which sensory
experiences are important
and which do not require
attention.
Kandel, Schwartz and Jessell
4th edition 2000, McGraw Hill
fig 62-5a
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 Brain Centers and Memory

thalamic structures are important for recalling
memories.
damage to thalamus causes retrograde amnesia
or the inability to recall stored experiences.
thalamus scans the cortex for the area and the
circuit for the stored memory.

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