Brain Science Fundamentals
- 한국과학기술원
- Christopher Fiorillo
페이스북
트위터
카카오톡
네이버밴드
링크복사
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- 주제분류
- 자연과학 >생물ㆍ화학ㆍ환경 >생명과학
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- 강의학기
- 2011년 2학기
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- 조회수
- 8,833
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This course is intended to serve as an introduction to neuroscience. The typical approach to teaching an introductory neuroscience course is to focus almost exclusively on the mechanics of brain function (the biophysical mechanisms by which molecules and cells interact in the brain). This course will cover basic biophysical mechanisms at all levels from molecules to neurons to neural systems. However, in addition, this course will cover theoretical aspects of information processing and how information processing relates to both the mechanics of the nervous system and the system’s general computational goals.
- 수강안내 및 수강신청
- ※ 수강확인증 발급을 위해서는 수강신청이 필요합니다
Function of Brain(1)
차시별 강의
| 1. | |
Introduction and overview | 1. Introduction of this course 2. Overview of mechanics |
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| 2. | |
Function of Brain(1) | 1. Function of Brain 2. Information, probability and prediction |
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Function of Brain(1) | 1. Function of Brain 2. Information, probability and prediction |
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Function of Brain(2) | 1. Information flows through molecular sensors 2. Information transformation in sensory-motor pathway |
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Function of Brain(2) | 1. Information flows through molecular sensors 2. Information transformation in sensory-motor pathway |
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| 3. | |
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 : beyond action potential | 1. Hodgkin-Huxley model and action potential conduction 2. Ion channel diversity |
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Membrane voltage : beyond action potential | 1. Ion channel diversity 2. Maintaining Homeostasis |
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Synaptic transmission | 1. synaptic transmission and release probability 2. paired pulse depression and facilitation |
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Synaptic transmission | 1. synaptic transmission and release probability 2. paired pulse depression and facilitation |
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| 7. | |
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. Types of Small neurotransmitter :catecholamine, amino acids, acetylcholine | |
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Neurotansmitters, Receptors, and Signal Transduction 3 | 1. Receptors : ionotropic receptor, metabotropic receptor 2. G protein and second messenger |
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| 8. | |
Gross Anatomy of the Brain | 강 의 노 트 | |
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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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| 9. | |
Theoretical Aspects of Learning and Plasticity | 1. input and output of a neuron 2. Hebbian and anti-hebbian plasticity |
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| 10. | |
Development of Neuronal Connectivity 1 | 1. Development of neuronal structure | |
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Development of Neuronal Connectivity 2 | 1. Activity dependent synaptic arrangement 2. Synaptic rearrangement in LGN and visual cortex |
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| 11. | |
Mechanisms of Learning and Plasticity in Neurons 1 | 강 의 노 트 | |
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Mechanisms of Learning and Plasticity in Neurons 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 and Plasticity in Neurons 2 | 1. Mechanism of LTP and LTD 2. Egg carton model and signal transduction in synaptic plasticity |
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Mechanisms of Learning and Plasticity in Neurons 3 | 1. Habituation and Sensitization of Gill-Withdrawal Reflex 2. Classical conditioning in Aplysia 3. Synaptic timing dependent plasticity(STDP) |
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| 12. | |
Neurotansmitters, Receptors, and Signal Transduction 1 | 강 의 노 트 | |
| 13. | |
Theoretical Aspects of Learning and Plasticity | 강 의 노 트 | |
| 14. | |
Development of Neuronal Connectivity 1 | 강 의 노 트 | |
| 15. | |
Overview of Senses | 1. Sensory divisions and Receptor cells 2. Receptive fields |
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Overview of Senses | 강 의 노 트 | |
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| 16. | |
The Retina | 1. Circuitary and anatomy of visual system 2. Phototransduction cascade and adaptation |
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The Retina | 강 의 노 트 | |
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The Retina (2) | 1. Bipolar Neurons and Gangilon neurons 2. color processing and motion sensitivity |
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| 17. | |
The Higher Visual System | 1. Lateral geniculate nucleus and Striate Cortex 2. Physiology of striate cortex 3. Dorsal and ventral stream |
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The Higher Visual System | 강 의 노 트 | |
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| 18. | |
Reward and Attention | 1. Dopamine and reward 2. Hebbian plasticity and reward signal |
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The Motor System | 1. anatomy of cortex and spinal cord 2. central pattern generator and bistability |
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The Motor System | 강 의 노 트 | |
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