Deck 4: Long-Term Memory

A) he lost the ability to form new explicit memories
B) he lost the ability to form new implicit memories
C) he could speak but it could not write
D) he lost the use of spoken language but retained the written language

A) were severely reduced
B) were potentiated
C) were not affected
D) lost their emotional context

A) cannot be consciously recalled
B) last a very short time
C) have a strong emotional content
D) can be consciously recalled

A) remember his first day in school
B) recognize a doctor he met the previous day
C) recognize an old friend from elementary school
D) learn to read in a mirror

A) Working memory
B) Explicit memory
C) Episodic memory
D) Autobiographical memory

A) activity; weakening
B) activity; strengthening
C) inactivity; strengthening
D) inactivity; weakening

A) relational binding
B) long-term potentiation
C) reconsolidation
D) free recall

A) fire in completely random ways
B) are stable and predictable
C) can never change
D) could change with experience

A) CA1 and CA3 in the hippocampus
B) the entorhinal cortex and the dentate gyrus in the hippocampus
C) CA1 and the subiculum in the hippocampus
D) the dentate gyrus and the entorhinal cortex in the hippocampus

A) a serious disease
B) a single, strong, brief electrical stimulation
C) a drug injection that causes a strong muscular contraction
D) a burst lasting 15 seconds of high-frequency electrical pulses

A) population spikes in the dentate gyrus
B) population spikes in the CA1 region
C) tetani in the perforant path
D) population spikes in the entorhinal cortex region

A) Epinephrine
B) Serotonin
C) Glutamate
D) Dopamine

A) it allows the entry of calcium ions all the time
B) it allows the entry of calcium ions but only when sufficiently depolarized
C) it allows the entry of calcium ions whenever it binds to glutamate
D) it triggers the opening of AMPA channels

A) NMDA receptor functioning is critical for spatial memory
B) NMDA receptor functioning is unnecessary for spatial memory
C) AMPA receptor functioning is critical for spatial memory
D) AMPA receptor functioning is unnecessary for spatial memory

A) the formation of long-term memories
B) the formation of short-term memories
C) to learn the relationship between items in the environment and create cognitive maps
D) to help with forgetting

A) explains why synapses can be both stable and plastic
B) a question related to the two primary functions of LTM: to retain specific episodes and to extract general patterns
C) explains why neurons can be both stable and plastic
D) explains how memory has evolved in the presence of a quasi-stable genome

A) to save metabolic energy
B) to allow rest in certain areas of the brain
C) because consciousness would interfere with dreaming
D) because the same processes needed for reactivation are also used to process incoming stimuli

A) poor memory
B) normal memory
C) desire to reduce external stimulation
D) irritability

A) stage 1
B) stage 2
C) stage 3
D) REM stage

A) lower-frequency theta waves
B) high-frequency beta waves
C) slow oscillations
D) ponto-geniculo-occipital waves

A) by knowing that one will be tested later
B) only by promise of monetary reward
C) only by sleep
D) by the combination of sleep and the promise of monetary reward

A) hippocampal inactivity
B) hippocampal hyperactivity
C) amygdala activity
D) frontal cortex inactivity

A) context-free memories are stored in the neocortex; context-free memories are stored together with episodic memories
B) context-free memories are stored in the hippocampus; context-free memories are stored together with episodic memories
C) only context-free memories are stored outside of the hippocampus; all episodic memories remain in the hippocampus
D) only episodic memories are stored outside of the hippocampus; context-free memories remain in the hippocampus

A) interventions can impair memory, but only when the interventions are administered a long time after new learning
B) interventions can impair memory, but only when the interventions are administered shortly after new learning
C) interventions can impair memory, but only when the interventions are administered before new learning
D) memories are consolidated only if they cannot be erased under any circumstances

A) memories are reconsolidated when they have already been erased once and therefore they are final, cannot be erased under any circumstances
B) only rats who had not been reminded of the tone and then not given the protein-synthesis inhibitor showed no memory for the fear conditioning
C) only rats who had been reminded of the tone and then given the protein-synthesis inhibitor showed no memory for the fear conditioning
D) only rats who had not been reminded of the tone and then given the protein-synthesis inhibitor showed no memory for the fear conditioning

A) only for Pavlovian fear conditioning and object recognition
B) only for motor-sequence learning and object recognition
C) only for spatial memory and episodic memory
D) for various types of learning, including Pavlovian fear conditioning, motor-sequence learning, object recognition, spatial memory and episodic memory

A) only in rodents
B) in both rats and humans
C) only in humans
D) in all species tested, but only if protein-synthesis inhibitors are used

A) first collect fMRI data from several instances of the same cognitive event, then a computer program compares the voxel (tridimensional pixel) activity across the different instances of the same event to find patterns
B) first collect fMRI data from a single instance of a cognitive event, then a computer program compares the voxel (tridimensional pixel) activity to find patterns
C) first collect fMRI data from several instances of the same cognitive event, then a computer program compares the voxel (tridimensional pixel) activity across the different instances of the same event to find lack of patterns
D) conduct brain imaging technique that allows recording in free-moving animals

A) configuring brain activity into a uniquely different state that it was in during encoding
B) configuring brain activity into the same state that it was in during encoding, but only after one night of sleep
C) configuring brain activity into the same state that it was in during encoding, but only if protein synthesis inhibitors were injected in the hippocampus
D) configuring brain activity into the same state that it was in during encoding