the nerVOus system 257
hoW do memories form in the brain?
- Memories form when sensory messages are processed through
short-term and long-term storage mechanisms. - The storage mechanisms involve circuits between the
cerebral cortex and parts of the limbic system, thalamus,
and hypothalamus.
taKe-hoMe Message
amnesia The loss of fact
memory.
memory Storage of infor-
mation in the brain.
n Memory is how the brain stores and retrieves facts and
other types of information.
Learning and modifications of our behavior would be impos-
sible without memory. Memories develop in stages. The
first is short-term storage of bits of sensory information—
numbers, words of a sentence, and so on—for a few minutes
or hours. In long-term storage, seemingly unlimited amounts
of information get tucked away more or less permanently
(Figure 13.22).
Only some of the sensory information reaching the cere-
bral cortex is transfered to short-term memory. Information
is processed for relevance, so to speak. If irrelevant, it is
forgotten; otherwise it is consolidated with the banks of
information in long-term storage structures.
The brain processes facts separately from skills. Dates,
names, faces, words, odors, and other bits of explicit
information are facts that are stored together with the
circumstance in which they were learned. Hence you
might associate the smell of bread baking, say, with your
grandmother’s kitchen. This “fact” recall may be brief or
long-term and is called declarative memory. By contrast,
skill memory is gained by practicing specific motor activi-
ties. How to maneuver a snowboard or play a piano con-
certo is best recalled by actually performing it, rather than
by remembering the circumstances in which the skill was
first learned.
Separate memory circuits handle different kinds of
input. A circuit leading to declarative memory (Figure
13.23A) starts with inputs at the sensory cortex that flow
to the amygdala and hippocampus in the limbic system.
The amygdala is the gatekeeper, connecting the sensory
cortex with parts of the thalamus and with parts of the
hippocampus that govern emotional states. Information
flows on to the prefrontal cortex, where multiple banks of
fact memories are retrieved and used to stimulate or inhibit
other parts of the brain. The new input also flows to basal
nuclei, which send it back to the cortex in a feedback loop
that reinforces the input until it can be consolidated in
long-term storage.
Skill memory also starts at the sensory cortex, but this
circuit routes sensory input to a region deeper in the brain
that promotes motor responses (Figure 13.23B). Motor
skills entail muscle conditioning. The skill memory circuit
extends to the cerebellum, the brain region that coordinates
motor activity.
amnesia is a loss of fact memory.
How severe the loss is depends on
whether the hippocampus, amygdala,
or both are damaged, as by a head
blow. Amnesia does not affect a per-
son’s capacity to learn new skills.
Memory
Figure 13.22 Memories are processed in two stages.
Short-term memory is temporary. Long-term memories
may be stored in the cerebral cortex for years.
Input forgotten
Recall
of stored
input
Emotional state, having time
to repeat (or rehearse) input,
and associating the input
with stored categories of
memory influence transfer
to long-term storage
Short-term Memory
Input irretrievable
Sensory stimuli, as from
the nose, eyes, and ears
Temporary storage in
the cerebral cortex
Long-term Memory
Figure 13.23 Memories of facts and skills are stored
differently. a Possible circuits involved in declarative memory.
B A snowboarder provides a dramatic demonstration of
skill memory.
B
13.10
smell
A amygdala hippocampus
thalamus and
hypothalamus
basal nuclei
touch
hearing
vision
prefrontal cortex
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