Types of Learning Associative Learning: Classical Conditioning Behavior is associated with paired stimuli unconditioned stimulus (UCS) yields an unconditioned response (UCR) a neutral stimulus (NS) is paired with the unconditioned stimulus (UCS) until the UCS alone (now the CS) yields a conditioned response (CR) Ivan Pavlov Operant Conditioning Behavior is associated with rewards Reinforcement Punishment B. F. Skinner
Classical Conditioning
Operant Conditioning Reinforcement Punishment is any procedure that increases the response Positive Reinforcement adding or presenting a stimulus that increases the response Negative Reinforcement removing a stimulus that increases the response Punishment is any procedure that decreases the response
Types of Memory (iconic memory) (7 bits for 30seconds)
Types of Long-Term Memory Explicit Implicit conscious recall learned skills personally experienced events general facts motor or cognitive activation of associations associative learning
Memory Processes Step 2 Step 1 Step 3 Retrieval
Where is Memory Stored? Brain Impairment lead us to clues about learning and memory HM Extreme seizures forced the removal of: medial basal regions of the temporal lobe (bilaterally) most of the amygdala (bilaterally) all of the hippocampus (bilaterally) Result: Retrograde amnesia loss of some past memories Anterograde amnesia loss of the ability to form new memories Hippocampus is critical for the formation of new memories
HM Implicit Memory Intact No Explicit Memory
Hippocampus is Critical for Spatial Learning Rats must remember which doors have the reward
Caudate Nucleus Critical for Response Recognition Memory Must turn in same direction to get reward (remembers its own response)
Visual Cortex is Critical for Sensory Perception Rat must choose object that doesn’t match sample
Memory Areas Amygdala Caudate Hippocampus Visual Cortex
Cellular Mechanism for Learning Hebbian Synapse: Frequent stimulation can change the efficacy of a synapse
Enrichment Protocol Impoverished Enriched
Quantifying Dendritic Arborization
Neurobiological Changes via Learning Dendritic changes: Increased dendritic arborization Increased dendritic bulbs Synaptic changes: More neurotransmitter release More sensitive postsynaptic area Larger presynaptic areas Larger postsynaptic areas Increased interneuron modulation More synapses formed Increased shifts in synaptic input Physiological changes: Long-Term Potentiation Long-Term Depression
Hippocampal Brain Slicing
Long-Term Potentiation (LTP) each triangle represents a single action potential Slope of the EPSP (one characteristic measure of an action potential) baseline response potentiated response Hippocampus has a three synaptic pathway Stimulate one area (mossy fibers) and record the action potentials in another (CA1) Stimulate multiple times to get a baseline response Once a stable baseline is established give a brief high frequency stimulating pulse Use the same stimulating pulse as in baseline but now see a potentiated response This potentiated response can last hours, days, or even weeks (LTP)
Normal Synaptic Transmission Glutamate Channels: NMDA Mg2+ block no ion flow AMPA Na+ flows in depolarizes cell
LTP Induction With repeated activation the depolarization drives the Mg2+ plug out of the NMDA channels Ca2+ then rushes in through the NMDA channels Ca2+ stimulates a retrograde messenger to maintain LTP Ca2+ also stimulates CREB to activate plasticity genes
LTP-induced Neural Changes
Learning Requires Protein Synthesis! Anisomycin: (protein synthesis inhibitor) blocks long term memory