Origin of Long- Term Memory - Neuromarketing Business Association
Transcription
Origin of Long- Term Memory - Neuromarketing Business Association
Origin of LongTerm Memory 28 Mar 15 Long-Term Potentiation Published by The Neuromarketing Business Association Werner A. Goerlich How Long Term-Memory is Generated Introduction to Short and Long-Term Memory The human brain is capable to store a information for as little as thirty seconds, or a life time in Long-Term Memory. As an example we could use what happens in the brain while studding - the process of studding leads to an activation of a series of pathways, and the continuous activation of those pathways is what creates the memory of it. The Hippocampus The structure that is associated to long-term memories is the hippocampus, as seen in the image aside. It is a horseshoe shaped structure with a external tip that has a size and shape similar to a pea. This horseshoe like structure, is found in both sides of the brain and is located at the medial temporal lobe and coordinates the storage and retrieval of the memories. Memory processing begins when signals from the entorhinal cortex enter the hippocampus by a substructure the Dental Gyrus which then proceed trough the CA3 and CA1 areas, this is of particular importance since the synaptic changes to store a memory occur at that particular spot. Substructures of the Hippocampus - Dental Gyrus, CA1 and CA3 The stimulus captured and processed and passed to the hippocampus - via the nerve fibers from the entorhinal cortex (ento - interior, rhino - nose, entorhinal - interior to the rhinal sulcus) - is then passed by the dental gyrus to the CA1 area, and there on to the CA3. The neuroplasticity that has to occur, in order to create a long-term memory, is situated at the synoptical spaces between the CA1 and CA3 area. Long-Term Potentiation (LTP) The cellular and chemical underpinning of long term memory, is contributed to a phenomenon referred as Long-Term Potentiation (LTP). LTP occurs at the synaptical intersection of the neurons from the CA3 area, known as the Schaeffer-Collaterals, and the neurons of the region located in the CA1 area. The information/stimulus passes from the entorhinal cortex, to the dental gyrus, trough the CA3 region - making its run-through the SchaefferCollaterals - until the CA1 region, after that the information is passed to the subiculum and then back to the entorhinal cortex. LTP has been most commonly been studied at the CA3 neurons, at the Schaeffer-Collateral axons and the CA1 pyramidal cells. Low and High Frequency Action Potentials and LTP On the postsynaptic cells that receives the stimulus of the Schaeffer-Collaterals two main receptors, that are localized together, are associated to the creation of long term memories. The APMA receptor, that reacts to the glutamate liberation as a result of a potential passed trough the SchafferCollaterals, permitting the passing of sodium ions (Na+) and the NMDA receptor which is also permeable to sodium ions, but has high permeability to calcium (Ca 2+), but at this state is blocked by magnesium (Mg 2+). With a High Frequency Action Potential, which is comparable to long times of studying and memorization, the increased the amount of glutamate liberation permits, not only the passing of sodium ions through the APMA receptor, but a longer period -and therefor - concentration and depolarization of the synapses. This longer and higher depolarization displaces de magnesium ion that was obstructing the NMDA receptor, by electromagnetic repulsion, to the synaptic interspace, allowing sodium and calcium enter through its pore. Actual generation of Long-Term Memory In the early case, caused by the higher concentration of calcium, the amount of APMA receptor is increased preparing for a future higher concentration of calcium. In the late case, the higher levels of calcium, increases the amount of Transcription Factors (CREB), ultimately resulting in Gene Expression. Gene Expression The Transcription Factors increases the production of a variety of proteins - some include APMA receptors, which are inserted into he postsynaptic cell membrane at the synapse - others increase the Growth Factor, involved in the formation of new synapses, which is the basis of synaptic plasticity, as shown in the illustration. The Learning and Changing Brain Concluding, the memorization and learning process, is a grater bond between the CA1 and CA3 neurons. The late changes can last for twenty-four hours to a life time. It’s important to remember, that LTP is not a mechanism, but a outcome of the increased activity in two neurons, that result of a increase of APMA receptors, strengthen the synaptic connection, which allows the low frequent action potential a greater depolarization potential - This is the foundation of memory, however the hippocampus is not the only region to act in the creation of memories, other parts including the cerebral cortex. Activation of the pathways, continuous stimuli are ways to forge memories creating high frequency activation potentials. References Netter MD, F. (2014). Atlas of Human Anatomy, Amsterdam, NX: Elsevier Inc Royden Jones, J., Srinivasan, J., Allam, G., Baker, R. (2011). Netter’s Neurology, Toronto, ON: Saunders Purves, D., Cabeza R., Huettel S., LaBar, K., Platt, M., Woldorff, M. (2012). Principles of Cognitive Neuroscience. Duke, FL: Sinauer Associates, Inc Rudy, J. W. (2013). The Neurobiology of Learning and Memory. Boulder, FL: Sinauer Associates, Inc Blumenfeld, H (2011). Neuroanatomy Through Clinical Cases. Sunderland, Sinauer Associates, Inc Published by The Neuromarketing Business Association Author: Werner A. Goerlich