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・ General Anesthesia ・ Anesthesia and EEG ・ Mechanism of Anesthesia -GABA A Receptor-

Consciousness and Anesthesia Takashi Mashimo (Graduate School of Medicine)        眞下 節(医学系研究科麻酔・集中治療医学教室). ・ General Anesthesia ・ Anesthesia and EEG ・ Mechanism of Anesthesia -GABA A Receptor-. General Anesthesia. Operation without Anesthesia.

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・ General Anesthesia ・ Anesthesia and EEG ・ Mechanism of Anesthesia -GABA A Receptor-

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  1. Consciousness and AnesthesiaTakashi Mashimo (Graduate School of Medicine)       眞下 節(医学系研究科麻酔・集中治療医学教室) ・General Anesthesia ・Anesthesia and EEG ・Mechanism of Anesthesia -GABAA Receptor-

  2. General Anesthesia

  3. Operation without Anesthesia

  4. First Anesthesia with Ether by Dr. Morton in 1846

  5. A Patient under General Anesthesia

  6. Purpose of General Anesthesia Amnesia and Unconsciousness Immobility with Surgical Stimuli Suppression of Stress Responses to Surgical Stimuli

  7. Three Requisites for General Anesthesia Sedative, Hypnotic (Anesthetic) Analgesic(Opioid) Muscle Relaxant

  8. Inhalational Anesthetics

  9. Anesthesia Machine

  10. Intravenous Anesthetics

  11. Continuous Infusion of Propofol and Remifentanyl

  12. Components of the Anesthetized State General anesthesia consists of several components. Some of the discrete brain regions and neural circuits are involved in specific components of the anesthetized state. General anesthetics interact with subpopulations of nervous system cells to create each of the separate properties of anesthesia

  13. Main Components of General Anesthesia Sedation(鎮静、思考力低下) Amnesia(記憶消失) Unconsciousness, Hypnosis (無意識) Analgesia(無痛) Immobility(不動化) Adrenergic Suppression(交感神経抑制)

  14. Sites in the CNS that are thought to be involved in the anesthetic components; sedative, hypnotic and immobilizing actions of propofol Correlation between propofol level and anesthetic depth Rudolph & Antkowiak: Nature Reviews Neuroscience 5: 709, 2004

  15. Dose-response Curves of Main Components of General Anesthesia ED50s of Dose-response Curves of Anesthetic Components: Amnesia<Unconsciousness<Immobility<Adrenergic Suppression

  16. How do Anesthetics Produce the Broad Effects throughout the Brain? Individual aspects of the anesthetized state are attributable to different sets of nerve cells, which are themselves distinguished by specific surface proteins (receptors) that interact with anesthetics. New compounds designed to target just those proteins, and hence the desirable effects of anesthetics –as well as sedatives, sleep aids and memory drugs.

  17. Anesthesia and EEG Arousal (Consciousness) and Anesthesia (Unconsciousness)

  18. Unconsciousness (Hypnosis) Mechanism of arousal (consciousness) is complex. Centers of arousal are thought to be frontal cortex, thalamus and midbrain reticular formation. It is difficult to pinpoint a single anatomical source of unconsciousness during anesthesia. Unconsciousness is simply the result of cognitive unbinding: a severing of communication between the many brain regions that cooperate in higher cognition processing.

  19. GABAA Receptor and EEG Activation of GABAA receptor with general anesthetics 10Hz spindle wave GABAA Receptor Increase in amplitude of 10Hz spindle wave

  20. Electroencepharogram (EEG) EEG is thought to originate in the cone cells of cerebral cortex. Dendrite of Cone Cell - - - Cerebral Cortex - - - - - + + + + + + ① Cone Cell Thalamus

  21. Stages of Sleep and EEG Stage 2: 10Hz spindle waves Stage 3: 2Hz slow waves (20~50%) Stage 4: 2Hz slow waves (over 50%)

  22. Changes in EEG during Anesthesia Awake/light anesthesia: low amplitude rapid wave Low amplitude 1 sec 10Hz Moderate anesthesia: high amplitude slow wave High amplitude 1 sec 5Hz

  23. BIS (EEG) Electrode during Anesthesia

  24. Sevoflurane Anesthesia and EEG BIS value 100 BIS = 80 Awake 80 低振幅速波 Light anesthesia BIS = 60 高振幅徐波 (α wave) 60 Moderate anesthesia BIS = 40 40 高振幅徐波 (δwave) BIS=15 Deep anesthesia 20 Burst & suppression BIS = 0 Too deep anesthesia 0 Flat EEG

  25. Power Spectrum of EEG 2%sevoflurane anesthesia ② ① ② 2Hz Power spectrum of EEG ① 10Hz

  26. EEG Power Spectra during Sevoflurane Anesthesia 10Hz 2Hz Sevoflurane1.0% BIS61 Sevoflurane1.5% BIS53 Sevoflurane2.0% BIS46

  27. EEG Power Spectra during Sevoflurane Anesthesia in Infants and Adults Infant Adult 1.0% 1.5% 2.0% 2.5% 3.0% Concentration of sevoflurane (%)

  28. Sevoflurane Concentrations in Which an Amplitude of the EEG’s 10Hz wave Reaches the Highest P<0.05 2.3±0.3% 1.8±0.4% Sevoflurane (%) InfantAdult

  29. Mechanism of General Anesthesia

  30. The effect of anesthesia is analogous to pulling out plugs at the switchboard in the brain Unconsciousness is simply the result of cognitive unbinding: a severing of communication between the many brain regions that cooperate in higher cognition processing. If one imagines groups of neurons as forming lines in a vast telephone network, the effect of general anesthesia is analogous to pulling out plugs at the switchboard.

  31. Anesthetics interacts with multiple varieties of specific proteins, known as receptors, on the surface of neurons

  32. Receptors and Anesthetics Anesthetics interacts with multiple varieties of specific proteins, known as receptors, on the surface of neuron cells. Families of receptors contain different versions which tend to predominate in different areas of the CNS. The presence of particular receptor subtypes on only certain subpopulations of neurons will determine which cells are influenced by an anesthetic. Receptor variants are the targets of current anesthetic drugs, understanding how the drugs interact with the receptors to change the cell’s function and how those cellular changes produce the components of anesthesia.

  33. GABA and GABAA Receptor GABA is an inhibitory neurotransmitter, which has the ability to block neuronal communication It helps to maintain overall balance in the CNS by dampening neuron’ ability to respond to excitatory messages from other cells. GABAA receptor is thought to play a central part in the actions of anesthetics

  34. Orser BA, Sci Am, June:32-9,2007

  35. GABAA receptor plays a central part in the actions of anesthetics Anesthetics increases the function of GABAA receptors by interacting at discrete binding cavities or attaching to specific amino acids in the receptors themselves. Anesthetics prolong the chloride ion channel opening, which causes hyperpolarization of the cell membrane. It extends the inhibitory effects of GABA molecules bound to the receptor.

  36. Anesthetics and GABA:Changing Charge Orser BA, Sci Am, June:32-9,2007 Anesthetics bind the GABAA receptor and prolonging the channel opening, which causes hyperpolarization of the cell membrane

  37. GABAA Receptor GABAA receptor is a protein complex composed of five subunit parts, which can be mixed and matched in various combinations. At least 19 different GABAA receptor subunits exists in mammals, and most of those have variant subtypes. Most GABAA receptors are composed of 2 alpha subunits, 2 betas and 1 gamma.

  38. GABAA Receptor’s Subunit Composition The GABAA receptor’s subunit composition dramatically alters its pharmacological properties: just one subunit difference within a GABAA receptor’s structure can determine whether and how it will respond to a particular anesthetic drug.

  39. Anesthetics is Jamming Nervous Transmission Anesthetics dampen neuronal communication, in part, by enhancing the effects of neurotransmitter GABA, a signaling molecule that inhibits nerve cells from firing. Current research is focused on how the anesthetics interact with cellular GABAA receptors to block neural activity.

  40. cDNA pBluescript cDNA mRNA 神経受容体発現と電気生理学的測定 cDNA プラスミドに組み込み 2電極電位固定法 大腸菌内で大量に増殖 プラスミドを収穫し,制限酵素で直線化 24-48時間培養 Xenopus oocyte アフリカツメガエル卵へ注入 プロモーター部位より翻訳

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