1 / 19

Lecture 18: Memory

Lecture 18: Memory. Memories. Memory 1 : a lasting consequence of an event (a broken glass) Memory 2 : a trace of an event that needs recovery with a key (a recollection about a broken glass). Stim. F, L. F. Curve 1. Curve 2. L. Hysteresis.

archiee
Télécharger la présentation

Lecture 18: Memory

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Lecture 18: Memory

  2. Memories • Memory 1: a lasting consequence of an event (a broken glass) • Memory 2: a trace of an event that needs recovery with a key (a recollection about a broken glass)

  3. Stim F, L F Curve 1 Curve 2 L Hysteresis An isolated muscle is being stimulated at a constant rate and strength. Muscle force will depend on muscle length. During slow stretching and slow shortening, the muscle will display different dependences F(L). This behavior is called hysteresis.

  4. Declarative (explicit) Nondeclarative (implicit) Facts and events Nonassociative Associative Amygdala, cerebellum, BG, cortex Reflexes Hippocampus, medial temporal lobe, diencephalon Skills, habits Memories

  5. Memory • Habituation: learning not to respond to a stimulus following its multiple presentations (usually, when it is not very meaningful) • Sensitization: learning to respond to smaller magnitudes of a stimulus (usually, if it is very meaningful)

  6. Skill • A motor program? Can it be applied to different effectors? • Are there control functions stored in the brain? In what variables? • A reflex? • Perception-action coupling? How different is it from a reflex?

  7. Learning Mirror Writing

  8. Three Stages • Encoding: putting an event into an internal code • Storage: maintaining the code over time • Retrieval: using a key (intrinsic or extrinsic) to recover the code/event

  9. Short-Term Memory • Encoding: typically an acoustic, visual, or somatosensory code • Storage: limited capacity (7 ± 2 “pieces”); decay; followed by consolidation or loss of memory

  10. In Out A Reverberating Circuit The activity in this simple reverberating circuit will persist until some crucial substances are depleted. Open circles show excitatory synapses.

  11. Input Receptor Long-term memory Central processing Consolidation Short-term memory Effector Output Consolidation of Memory Processing a sensory stimulus may lead to creating a short-term memory trace in parallel with producing an effector (motor) output. Short-term memory can be consolidated into long-term memory.

  12. Conditioning • Classical conditioning: associating a response with a stimulus based on repetitive presentations (e.g., ringing a bell is associated with getting food); the animal has no initiative • Operant conditioning: searching for an action that leads to a desired consequence; active exploration. Even monosynaptic reflexes can show it (as demonstrated by Jon Wolpaw)!

  13. Conditioning • Classical conditioning: Pavlov’s experiments • The theory of conditioned reflexes starting from inborn reflexes • Towers of silence

  14. Key beam A Photo plate Object Object beam Key beam B Image Holography Holography creates an image (a memory) of an object on a photographic plate with the help of two light beams: the object beam and the key beam (A). One plate can store a number of images using different key beams. If the plate is illuminated by a key beam, an image of the corresponding object will emerge (B).

  15. Synapses as the Site for Memory Pro: • There are phenomena of LTP and LTD (cerebellum, hippocampus) • Where else? Contra: • Repetition without repetition • “Disposable synapses” • Lashley: Each neuron takes part in many memories; each memory is represented all over • LTP: too short, mostly animal studies • Importance of whole-brain (emotion) mechanisms • Eccles: use and disuse of synapses, spinal memory • Spinal memory experiments

  16. Spinal Memory Experiments • Stage 1: extirpation of half of the cerebellum. This leads to asymmetrical monosynaptic reflexes. • Stage 2: spinalization. If enough time elapses between the two surgeries, the asymmetry persists. If not, it disappears. • Cooling experiments: MSRs appear, followed by their asymmetry.

  17. Questions Without Answers • Which of the external events are being remembered? • Which of the brain processes that accompany the events are being fixed in memory? • Can all or only some of the neural elements fix memories? • What are the neural substrates of STM and LTM, and what are the mechanisms of exchange between them? • What happens in memory disorders? What is affected—whole-brain mechanisms, storage, attention, classification, retrieval, etc.?

  18. Memory Disorders: Amnesia Amnesia is a partial loss of memory. • Causes: brain injury, stroke, encephalitis, electric shock, etc. • Anterograde: affects the ability to recollect events that occurred after an injury • Retrograde: affects the ability to recollect events that occurred prior to an injury

  19. Memory Disorders Korsakoff’s syndrome: • Chronic alcohol abuse • Defective retrieval • Partial cues or prompts help Alzheimer’s: • Motor skills are not affected • Priming experiments show major defects

More Related