| 1. | |
Introduction | 1. Introduction of this course 2. Overview of mechanics |
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Introduction | 1. Introduction of this course 2. Overview of mechanics |
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| 2. | |
The Goal of the Brain | 1. Function of Brain 2. Information, probability and prediction |
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The Goal of the Brain | 1. Function of Brain 2. Information, probability and prediction |
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| 3. | |
Overview of Function | 1. Information flows through molecular sensors 2. Information transformation in sensory-motor pathway |
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Overview of Function | 1. Information flows through molecular sensors 2. Information transformation in sensory-motor pathway |
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| 4. | |
Overview of Structure | 1.Structure of neurons 2. Classifying neurons |
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Overview of Structure | 1. Structure of neurons 2. Classifying neurons |
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| 5. | |
Membrane voltage : passive properties(1) | 1. properties of water, ion, and neuronal membrane 2. ion channels, equilibrium potential and resting potential |
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Membrane voltage : passive properties(1) | 1. properties of water, ion, and neuronal membrane 2. ion channels, equilibrium potential and resting potential |
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Membrane voltage : passive properties(2) | 1. an equivalent circuit of neuronal membrane 2. common features of ion channels 3. function of action potential |
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Membrane voltage : active properties(1) | 1. patch clamp recording 2. action potential and voltage gated ion channel |
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Membrane voltage : active properties(1) | 1. patch clamp recording 2. action potential and voltage gated ion channel |
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Membrane voltage : active properties(2) | 1. Hodgkin-Huxley model and action potential conduction 2. Ion channel diversity |
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Membrane voltage : active properties(3) | 1. Three Key Properties of Voltagegated Ion Channels 2. Conduction velocity | |
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Voltage-Regulated Channels | 1. Functional Classification of Ion Channels 2. Maintaining Homeostasis |
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Voltage-Regulated Channels | 1. Functional Classification of Ion Channels 2. Maintaining Homeostasis |
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| 8. | |
Synapse (1) | 1. synaptic transmission and release probability 2. paired pulse depression and facilitation |
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Synapse (2) | 1. synaptic transmission and release probability 2. paired pulse depression and facilitation |
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Synapse | 1. synaptic transmission and release probability 2. paired pulse depression and facilitation |
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| 9. | |
Neurotansmitters, Receptors, and Signal Transduction (1) | 1. Dale s principle 2. Types of neurotransmitter |
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Neurotansmitters, Receptors, and Signal Transduction (2) | 1. Receptors : ionotropic receptor, metabotropic receptor 2. G protein and second messenger |
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Neurotansmitters, Receptors, and Signal Transduction | |
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| 10. | |
Gross Anatomy of the Brain (1) | 1. Anatomical terms | |
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Gross Anatomy of the Brain (2) | 2. major division of CNS and cortex, and brodmann map | |
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Gross Anatomy of the Brain | 1. Anatomical terms 2. major division of CNS and cortex, and brodmann map |
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| 11. | |
Theory of learning (1) | 1. input and output of a neuron | |
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Theory of learning (2) | 2. Hebbian and anti-hebbian plasticity | |
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Theory of learning | 1. input and output of a neuron 2. Hebbian and anti-hebbian plasticity |
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| 12. | |
Development of Connectivity (1) | 1. Development of neuronal structure | |
| Development of Connectivity (2) | 2. Synaptic rearrangement in LGN and visual cortex | |||
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Development of Connectivity | 1. Development of neuronal structure 2. Synaptic rearrangement in LGN and visual cortex |
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| 13. | Mechanisms of Learning (1) | 1. Model for the study of associative plasticity : hippocampus 2. Glutamate receptors 3. Long term potentiation and depression(LTP, LTD) |
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| Mechanisms of Learning (2) | 1. Habituation and Sensitization of Gill-Withdrawal Reflex 2. Classical conditioning in Aplysia 3. Synaptic timing dependent plasticity(STDP) |
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Mechanisms of Learning | Mechanisms of learning and plasticity in neurons | |
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