Learning versus Memory

• Learning - a logical construct that refers to the acquisition of new information (refers to the process of acquiring)
• Memory - the process of storage and/or retrieval of acquired information

Electrophysiological Changes with Learning

• First presentation
• Attention
• Diffuse activation
• Later presentations
• Activity in many areas becomes habituated to stimulus presentation
• Area of UCS projection, lateral hypothalamus and DTAS remains active
• UCS has the unique property of activating the limbic system.
• CS projects via sensory nuclei to cortex.

Types of Learning

• Habituation - learning not to attend to non-changing inconsequential stimuli
• Sensitization- increase in response probability after strong stimulus
• Classical Conditioning- associative learning.

Associative conditioning: where the presentation of a "neutral stimulus" (CS) is paired with the presentation of a unconditioned stimulus (UCS) until the CS comes to elicit the response which was previously made to the (UCS).

• The UCS-UCR connection is wired into the CNS (anatomically arranged)
• E. g., withdrawal response (UCR) of a subject to foot shock (UCS); this is built into the organism.
• The number of UCS-UCR combinations of this type are limited in number.
• Instrumental Conditioning - situation in which outcome is dependent on response
• Operant Conditioning - response is instrumental in outcome, but animal is free to operate on his environment.
• Perceptual Learning - learning relationships between stimuli -- sensory associations.
• Language Learning
• Motor Learning - learning skilled actions -- non-associative learning

Neural Correlates

• Study correlations between electrical activity and learning.
• Problem - relation between electrical activity and neural events.
• Observed correlation - not necessarily reflecting learning.

Orienting

• Diffuse activation.
• Behavioral adjustments - important in initial phase of conditioning process,
• General activation.
• Habituation - eventually only (lost if RF lesions, H-Peon, 61) localized response. Where?
• EEG changes - much quicker than behavior.

Acquisition

• Hippocampus responsenot present early but appears and remains until CRs begin to appear.
  • Reappears in discrimination training and extinction.
  • Behavioral orientation correlated almost perfectly with hippocampal activation.
  • Hippocampal stimulation - stimulus-bound orienting also interrupts ongoing behavior.
  • Hippocampus - may work to prevent orienting response to nonsignificant stimuli.
• Limbic system response appears in Amygdala and Posterior Hypothalamus
• Limbic System - May be correlated with internal stimuli whereas RF may mediate external stimuli
• Cortical desynchronization appears before overt response; more persistent during extinction.
• Localized cortical desynchronization - sensory & motor cortex.

Maintenance

• For simple task
• Response in anterior thalamic nuclei, amygdala, sensory relays.
• Not in cortex (except motor), reticular formation
• As response acquires meaning, the response shifts from specific sensory structures to nonsensory specific structures (not reticular formation, but thalamus and limbic system extinction)
• Learning not to respond (habituation).
• Pavlov's disinhibition suggests that extinction is active process.
• Frequency-specific cortical responses can reappear in specific sensory areas.

Role of the Cortex in Learning

• Switchboard analogy - severing association neurons between sensory-motor areas has little effect.
• Association areas
• Areas 17-18-19 tend to respond to progressively more complex stimuli.
• Information not relayed from other cortical areas (respond if other cortical areas removed).
• Frontal lobes project from dorsal median nucleus of thalamus
• Lesions deficit in relayed response
• Same effect - lesions in hippocampus or caudate
• Hyperactivity
• Age important - more dramatic in old.
• Relief from pain.
• Posterior Association Areas - temporal lobe
• Kluver and Bucy (1937) psychic blindness; learning-set loss. No delayed-response loss.