• 00:00 1.
    首頁
  • 00:08 2.
    請同學先進入Slido
  • 00:18 3.
    為什麼要學呼吸生理學?不知道這個也活得好好的
  • 00:46 4.
    何時需刻意地增加呼吸效率?
  • 01:52 5.
    Outline
  • 01:54 6.
    Background
  • 03:04 7.
    Background
  • 05:11 8.
    除了氣體交換(吸氧排二氧化碳)外, 呼吸系統還有那些功能?
  • 05:21 9.
    Functions of Respiratory Sys.
  • 07:15 10.
    Overview
  • 09:40 11.
    Outline
  • 09:48 12.
    Structure of Respiratory Sys.
  • 10:08 13.
    Structure of Respiratory Sys.
  • 10:38 14.
    Function of Nasal Passage
  • 11:53 15.
    Comparison of Airway Structure
  • 12:38 16.
    Airways of a Human Lung
  • 13:27 17.
    Main Airway Branches & Zones
  • 14:11 18.
    Main Airway Branches & Zones
  • 14:56 19.
    Alveoli
  • 15:58 20.
    The Human Lung
  • 16:42 21.
    Blood Supply of Lungs
  • 18:33 22.
    Respiratory Muscles
  • 20:20 23.
    Respiratory Muscles
  • 23:25 24.
    那種呼吸方式比較有效率?
  • 25:13 25.
    Pleural layers
  • 26:21 26.
    Cross Section of the Thoracic Cavity
  • 26:41 27.
    Intrapleural Space
  • 28:13 28.
    Pneumothorax
  • 29:24 29.
    Outline
  • 29:33 30.
    Instrument for Measuring Lung Vol.
  • 32:43 31.
    Spirometer, Lung Volumes and Capacities
  • 36:12 32.
    Lung Volumes and Capacities
  • 38:02 33.
    什麼時候正常吐氣結束?
  • 39:16 34.
    Functional Residual Capacity
  • 42:35 35.
    Measurement of FRC
  • 43:47 36.
    Measurement of FRC
  • 47:38 37.
    Overview
  • 47:51 38.
    Ventilation (通氣量)
  • 51:01 39.
    Dead Space (死腔)
  • 53:01 40.
    Fowler’s Method:Single-Breath Nitrogen Washout
  • 53:44 41.
    Fowler’s Method:Single-Breath Nitrogen Washout
  • 57:29 42.
    Bohr’s Method:Conservation of Mass
  • 1:01:15 43.
    Dalton’s Law
  • 1:03:50 44.
    Bohr’s Method (2)
  • 1:05:06 45.
    Alveolar Ventilation
  • 1:07:30 46.
    Alveolar Ventilation
  • 1:08:29 47.
    Uneven Ventilation inUpright Position
  • 1:09:35 48.
    Cause of the Regional Differences of Ventilation
  • 1:11:41 49.
    Closing Volume
  • 1:15:37 50.
    Closing Volume
  • 1:17:01 51.
    Partial Pressures of Gases in Various Parts
  • 1:17:57 52.
    O2 and CO2 Concentrations in Exhaled Gas
  • 1:19:15 53.
    Overview of Po2 and Pco2
  • 1:22:25 54.
    How to measure PAO2?
  • 1:22:40 55.
    Alveolar Gas Equation
  • 1:23:43 56.
    Respiratory Quotient (呼吸商)
  • 1:26:46 57.
    Alveolar Gas Equation
  • 1:27:46 58.
    Reasons to Understand the Alveolar Gas Equation
  • 1:28:26 59.
    Case Study
  • 1:30:52 60.
    改變呼吸方式可改變那種氣體的分壓?
  • 1:31:31 61.
    Hyper-, Hypo-ventilation & Hyperpnea
  • 1:33:42 62.
    跑步後很喘,如何快速回到正常的呼吸速率?
  • 1:34:33 63.
    Why hyperpnea is more efficient?
  • 1:37:46 64.
    Outline
  • 1:37:53 65.
    Overview
  • 1:38:14 66.
    Perfusion (灌流量)
  • 1:39:13 67.
    Shunt (分流)
  • 1:42:18 68.
    Shunt Equation
  • 1:44:31 69.
    Uneven Perfusion in Upright Position
  • 1:45:17 70.
    Zone Model
  • 1:47:40 71.
    Hypoxic Pulmonary Vasoconstriction
  • 1:49:43 72.
    Overview
  • 1:50:05 73.
    Matching of Ventilation & Perfusion
  • 1:51:27 74.
    Mis-matching of Ventilation & Perfusion
  • 1:52:14 75.
    V /Q 受什麼影響?
  • 1:52:18 76.
    Matching of Ventilation & Perfusion
  • 1:54:10 77.
    Distribution of V and Q Within the Lung in the Upright Position
  • 1:55:35 78.
    Distribution of V /Q Ratio
  • 1:58:21 79.
    V /Q 如何影響氣體的分壓?
  • 1:58:27 80.
    Effects of V /Q Ratio on PAo2 & PAco2
  • 2:00:20 81.
    Effects of V /Q Ratio on PAo2 & PAco2
  • 2:00:55 82.
    V /Q v.s. Po2 & Pco2
  • 2:03:44 83.
    V /Q Inequality of Normal Lung in the Upright Position
  • 2:09:09 84.
    Riley’s Three Compartment Model
  • 2:11:38 85.
    Riley’s Three Compartment Model
  • 2:13:44 86.
    Gas Exchange Computer Lab
  • 2:14:50 87.
    Outline
  • 2:15:07 88.
    Key Points
  • 2:15:13 89.
    General Concepts and Terminology
  • 2:18:25 90.
    General Concepts and Terminology
  • 2:19:47 91.
    PL = Pal – Ppl(1)Pw = Ppl – Pbs(2)(1) + (2)Prs = PL + Pw = Pal – Pbsa) Pbs =0  Pw = Ppl = Pes Prs = Palb) Pao = VRaw + Pal When flow=0, Pao = Pal = Prsc) PL = Pal – Ppl = Pao|flow=0 – Pes
  • 2:24:57 92.
    PL = Pal – Ppl(1)Pw = Ppl – Pbs(2)(1) + (2)Prs = PL + Pw = Pal – Pbsa) Pbs =0  Pw = Ppl = Pes Prs = Palb) Pao = VRaw + Pal When flow=0, Pao = Pal = Prsc) PL = Pal – Ppl = Pao|flow=0 – Pes
  • 2:25:22 93.
    Key Points
  • 2:25:32 94.
    Static Mechanical Properties
  • 2:27:18 95.
    Compliance Changes in Different Diseases
  • 2:28:28 96.
    Calculation of Compliance of Lung
  • 2:30:06 97.
    Key Points
  • 2:30:11 98.
    Resistance
  • 2:31:28 99.
    The Airway Resistance
  • 2:32:21 100.
    The Airway Resistance
  • 2:34:15 101.
    The Airway Resistance
  • 2:36:27 102.
    The Airway Resistance
  • 2:37:11 103.
    Calculation of Dynamic Resistance
  • 2:38:17 104.
    Evaluation of Airway Resistance
  • 2:40:59 105.
    Evaluation of Abnormality in Lung Vol.
  • 2:42:41 106.
    Flow-volume Curves
  • 2:43:51 107.
    Isovolume Pressure-flow Curves
  • 2:44:59 108.
    Flow-Volume Relationship
  • 2:46:06 109.
    Dynamic Airway Compression
  • 2:52:41 110.
    EPP is Influenced by Lung Elastic Recoil
  • 2:54:57 111.
    Pursed Lip Breathing (噘嘴吐氣)
  • 2:56:30 112.
    Abnormality in Lung Vol.
  • 2:57:23 113.
    Interpretation of Flow-Vol Loop
  • 2:58:10 114.
    Obstructive Lung Vol. Defect
  • 2:58:46 115.
    Chronic Obstructive Pulmonary Disease (慢性阻塞性肺病; COPD)
  • 2:59:00 116.
    Emphysema (肺氣腫)
  • 2:59:30 117.
    Asthma (氣喘)
  • 3:00:54 118.
    吸煙豬肺影片
  • 3:03:38 119.
    Restrictive Lung Vol. Defect
  • 3:03:54 120.
    Examples of Restrictive Lung Dz.
  • 3:03:54 121.
    Restrictive Lung Vol. Defect
  • 3:04:21 122.
    Examples of Restrictive Lung Dz.
  • 3:05:08 123.
    做那些動作使呼吸效率增加?為什麼?
  • 3:06:00 124.
    做那些動作使呼吸效率增加?為什麼?
  • 3:07:40 125.
    Key Points
  • 3:07:47 126.
    Hysteresis
  • 3:10:14 127.
    Surface Tension
  • 3:12:07 128.
    Law of LaPlace
  • 3:13:39 129.
    Surfactants
  • 3:14:10 130.
    Importance of Lung Surfactant
  • 3:15:11 131.
    Work of Breathing
  • 3:16:16 132.
    Effects of Diseases on PV Curve
  • 3:18:41 133.
    為什麼肺氣腫的病人每次的呼吸都很吃力?
  • 3:20:10 134.
    Effects of Diseases on PV Curve
  • 3:21:11 135.
    Key Points
  • 3:21:24 136.
    PL = Pal – Ppl(1)Pw = Ppl – Pbs(2)(1) + (2)Prs = PL + Pw = Pal – Pbsa) Pbs =0  Pw = Ppl = Pes Prs = Palb) Pao = VRaw + Pal When flow=0, Pao = Pal = Prsc) PL = Pal – Ppl = Pao|flow=0 – Pes
  • 3:21:52 137.
    Elastic Recoil of the Chest Wall
  • 3:24:13 138.
    Elastic Recoil of the Chest Wall
  • 3:26:22 139.
    Lung-Chest Wall Couplingin Static Status at Different Lung Volume
  • 3:28:27 140.
    Lung-chest Wall Coupling to Determine FRC
  • 3:33:36 141.
    Static Elastic Properties of the Lung and Chest Wall
  • 3:36:08 142.
    Static Elastic Properties of the Lung and Chest Wall
  • 3:38:26 143.
    Transmural Pressure Across the Lung Wall in Dynamic Status
  • 3:40:45 144.
    The Mechanics of Quiet Breathing
  • 3:46:27 145.
    P-V Relationships and Schematic Events of Resp. Cycle
  • 3:52:37 146.
    P-V Relationships and Schematic Events of Resp. Cycle
  • 3:54:33 147.
    Outline
  • 3:54:47 148.
    Overview
  • 3:55:07 149.
    Diffusion and Gas Transport
  • 3:56:11 150.
    Alveolo-Capillary Barrier
  • 3:56:46 151.
    Diffusion
  • 3:57:53 152.
    Diffusion Capacity
  • 3:59:04 153.
    Diffusion Capacity
  • 4:00:58 154.
    Physiologic Changes That Alter Diffusion Capacity
  • 4:00:59 155.
    Diffusion Capacity
  • 4:01:15 156.
    Physiologic Changes That Alter Diffusion Capacity
  • 4:03:09 157.
    Capillary Transit Time
  • 4:06:10 158.
    Perfusion-limited Gas
  • 4:07:21 159.
    Diffusion-limited Gas
  • 4:07:54 160.
    Diffusion and Perfusion Limitations
  • 4:10:12 161.
    Interpretation of Pulmonary Function Test
  • 4:15:02 162.
    Transport of O2 and CO2
  • 4:15:09 163.
    Oxygen Transport
  • 4:15:48 164.
    Blood Gas Measurement
  • 4:16:53 165.
    Blood Gas Measurement
  • 4:18:53 166.
    O2 Bound to Hb
  • 4:19:21 167.
    O2 Bound to Hb
  • 4:21:29 168.
    What does pulse oximeter measure?O2 dissolved in the blood plasmaO2 bound with hemoglobin
  • 4:22:30 169.
    O2 Concentration & Saturation in Anemia
  • 4:23:58 170.
    Cooperative Interactions
  • 4:26:40 171.
    O2 Bound to Hb
  • 4:29:34 172.
    O2 Bound to Hb
  • 4:32:08 173.
    Factors Affecting O2 Bound to Hb
  • 4:34:29 174.
    CO2 Transport
  • 4:35:43 175.
    CO2 Transport
  • 4:37:32 176.
    CO2 Transport
  • 4:38:08 177.
    CO2 Equilibrium Curve
  • 4:41:31 178.
    Assessment of Arterial Hypoxemia
  • 4:45:20 179.
    Case study
  • 4:50:51 180.
    Outline
  • 4:50:58 181.
    Control of Respiration
  • 4:51:57 182.
    Overview
  • 4:53:01 183.
    Receptors
  • 4:54:04 184.
    Receptors
  • 4:56:17 185.
    Receptors
  • 4:57:39 186.
    Central Controller in Brain Stem
  • 4:58:02 187.
    你覺得吸氣比重要還是呼氣比重要?
  • 4:58:55 188.
    Central Controller
  • 4:59:31 189.
    Central Controller
  • 5:00:51 190.
    Respiratory Neurons in the Brain Stem
  • 5:04:20 191.
    正常情況下,什麼時候正常呼吸的型態會改變?
  • 5:04:30 192.
    Central Controller
  • 5:05:13 193.
    Central Controller
  • 5:05:13 194.
    Central Controller
  • 5:05:24 195.
    Central Controller
  • 5:06:24 196.
    Effectors
  • 5:07:11 197.
    Outline
  • 5:07:16 198.
    Overview
  • 5:07:26 199.
    Chemical Control of Resp.
  • 5:08:38 200.
    Central Chemoreceptor
  • 5:10:20 201.
    Peripheral Chemoreceptor
  • 5:11:26 202.
    Silent Hypoxia (Happy Hypoxia)
  • 5:12:23 203.
    Regulation of breathing in response to changes in blood PCO2, PO2, and pH (H+) via negative feedback control
  • 5:14:14 204.
    Video
  • 5:15:18 205.
    Outline
  • 5:15:35 206.
    Acid-base Balance
  • 5:17:08 207.
    Effectiveness of a Buffer System
  • 5:18:33 208.
    Bicarbonate
  • 5:19:09 209.
    The Effect of Bicarbonate on Blood pH
  • 5:21:20 210.
    Davenport Diagram
  • 5:23:02 211.
    Respiratory Disturbances
  • 5:23:42 212.
    Metabolic Disturbances
  • 5:24:33 213.
    Compensatory Responses
  • 5:26:36 214.
    Compensatory Responses
  • 5:27:25 215.
    Outline
  • 5:27:34 216.
    Rest-to-Work Transitions
  • 5:28:40 217.
    Sub-maximal Exercise
  • 5:29:21 218.
    Ventilatory Control During Submaximal Exercise
  • 5:29:39 219.
    High Intensity Exercise
  • 5:30:46 220.
    High Intensity Exercise
  • 5:31:28 221.
    Oxygen Debt
  • 5:33:10 222.
    呼吸系統是運動的限制因子嗎?
  • 5:33:15 223.
    Do the Lungs Limit Exercise Performance?
  • 5:33:53 224.
    Effect of Training on Ventilation
  • 5:34:51 225.
    How to Increase Resp. Function During Exercise?
  • 5:39:34 226.
    How to Increase Resp. Function During Exercise?
  • 5:42:41 227.
    Effect of High Altitude on Resp. Function
  • 5:43:23 228.
    Immediate: Increased in Ventilation
  • 5:46:15 229.
    Days: Decreased Affinity of Hemoglobin for Oxygen
  • 5:48:29 230.
    Days to weeks: Increased Hemoglobin Production
  • 5:49:53 231.
    Respiratory Adaptations to High Altitude
  • 5:51:21 232.
    Overview
  • 5:51:51 233.
    The End
  • Index
  • Notes
  • Comment
  • Fullscreen
Resp Physiol 20221004
Duration: 5:51:52, Browse: 518, Last Updated: 2022-10-06
    • 00:00 1.
      首頁
    • 00:08 2.
      請同學先進入Slido
    • 00:18 3.
      為什麼要學呼吸生理學?不知道這個也活得好好的
    • 00:46 4.
      何時需刻意地增加呼吸效率?
    • 01:52 5.
      Outline
    • 01:54 6.
      Background
    • 03:04 7.
      Background
    • 05:11 8.
      除了氣體交換(吸氧排二氧化碳)外, 呼吸系統還有那些功能?
    • 05:21 9.
      Functions of Respiratory Sys.
    • 07:15 10.
      Overview
    • 09:40 11.
      Outline
    • 09:48 12.
      Structure of Respiratory Sys.
    • 10:08 13.
      Structure of Respiratory Sys.
    • 10:38 14.
      Function of Nasal Passage
    • 11:53 15.
      Comparison of Airway Structure
    • 12:38 16.
      Airways of a Human Lung
    • 13:27 17.
      Main Airway Branches & Zones
    • 14:11 18.
      Main Airway Branches & Zones
    • 14:56 19.
      Alveoli
    • 15:58 20.
      The Human Lung
    • 16:42 21.
      Blood Supply of Lungs
    • 18:33 22.
      Respiratory Muscles
    • 20:20 23.
      Respiratory Muscles
    • 23:25 24.
      那種呼吸方式比較有效率?
    • 25:13 25.
      Pleural layers
    • 26:21 26.
      Cross Section of the Thoracic Cavity
    • 26:41 27.
      Intrapleural Space
    • 28:13 28.
      Pneumothorax
    • 29:24 29.
      Outline
    • 29:33 30.
      Instrument for Measuring Lung Vol.
    • 32:43 31.
      Spirometer, Lung Volumes and Capacities
    • 36:12 32.
      Lung Volumes and Capacities
    • 38:02 33.
      什麼時候正常吐氣結束?
    • 39:16 34.
      Functional Residual Capacity
    • 42:35 35.
      Measurement of FRC
    • 43:47 36.
      Measurement of FRC
    • 47:38 37.
      Overview
    • 47:51 38.
      Ventilation (通氣量)
    • 51:01 39.
      Dead Space (死腔)
    • 53:01 40.
      Fowler’s Method:Single-Breath Nitrogen Washout
    • 53:44 41.
      Fowler’s Method:Single-Breath Nitrogen Washout
    • 57:29 42.
      Bohr’s Method:Conservation of Mass
    • 1:01:15 43.
      Dalton’s Law
    • 1:03:50 44.
      Bohr’s Method (2)
    • 1:05:06 45.
      Alveolar Ventilation
    • 1:07:30 46.
      Alveolar Ventilation
    • 1:08:29 47.
      Uneven Ventilation inUpright Position
    • 1:09:35 48.
      Cause of the Regional Differences of Ventilation
    • 1:11:41 49.
      Closing Volume
    • 1:15:37 50.
      Closing Volume
    • 1:17:01 51.
      Partial Pressures of Gases in Various Parts
    • 1:17:57 52.
      O2 and CO2 Concentrations in Exhaled Gas
    • 1:19:15 53.
      Overview of Po2 and Pco2
    • 1:22:25 54.
      How to measure PAO2?
    • 1:22:40 55.
      Alveolar Gas Equation
    • 1:23:43 56.
      Respiratory Quotient (呼吸商)
    • 1:26:46 57.
      Alveolar Gas Equation
    • 1:27:46 58.
      Reasons to Understand the Alveolar Gas Equation
    • 1:28:26 59.
      Case Study
    • 1:30:52 60.
      改變呼吸方式可改變那種氣體的分壓?
    • 1:31:31 61.
      Hyper-, Hypo-ventilation & Hyperpnea
    • 1:33:42 62.
      跑步後很喘,如何快速回到正常的呼吸速率?
    • 1:34:33 63.
      Why hyperpnea is more efficient?
    • 1:37:46 64.
      Outline
    • 1:37:53 65.
      Overview
    • 1:38:14 66.
      Perfusion (灌流量)
    • 1:39:13 67.
      Shunt (分流)
    • 1:42:18 68.
      Shunt Equation
    • 1:44:31 69.
      Uneven Perfusion in Upright Position
    • 1:45:17 70.
      Zone Model
    • 1:47:40 71.
      Hypoxic Pulmonary Vasoconstriction
    • 1:49:43 72.
      Overview
    • 1:50:05 73.
      Matching of Ventilation & Perfusion
    • 1:51:27 74.
      Mis-matching of Ventilation & Perfusion
    • 1:52:14 75.
      V /Q 受什麼影響?
    • 1:52:18 76.
      Matching of Ventilation & Perfusion
    • 1:54:10 77.
      Distribution of V and Q Within the Lung in the Upright Position
    • 1:55:35 78.
      Distribution of V /Q Ratio
    • 1:58:21 79.
      V /Q 如何影響氣體的分壓?
    • 1:58:27 80.
      Effects of V /Q Ratio on PAo2 & PAco2
    • 2:00:20 81.
      Effects of V /Q Ratio on PAo2 & PAco2
    • 2:00:55 82.
      V /Q v.s. Po2 & Pco2
    • 2:03:44 83.
      V /Q Inequality of Normal Lung in the Upright Position
    • 2:09:09 84.
      Riley’s Three Compartment Model
    • 2:11:38 85.
      Riley’s Three Compartment Model
    • 2:13:44 86.
      Gas Exchange Computer Lab
    • 2:14:50 87.
      Outline
    • 2:15:07 88.
      Key Points
    • 2:15:13 89.
      General Concepts and Terminology
    • 2:18:25 90.
      General Concepts and Terminology
    • 2:19:47 91.
      PL = Pal – Ppl(1)Pw = Ppl – Pbs(2)(1) + (2)Prs = PL + Pw = Pal – Pbsa) Pbs =0  Pw = Ppl = Pes Prs = Palb) Pao = VRaw + Pal When flow=0, Pao = Pal = Prsc) PL = Pal – Ppl = Pao|flow=0 – Pes
    • 2:24:57 92.
      PL = Pal – Ppl(1)Pw = Ppl – Pbs(2)(1) + (2)Prs = PL + Pw = Pal – Pbsa) Pbs =0  Pw = Ppl = Pes Prs = Palb) Pao = VRaw + Pal When flow=0, Pao = Pal = Prsc) PL = Pal – Ppl = Pao|flow=0 – Pes
    • 2:25:22 93.
      Key Points
    • 2:25:32 94.
      Static Mechanical Properties
    • 2:27:18 95.
      Compliance Changes in Different Diseases
    • 2:28:28 96.
      Calculation of Compliance of Lung
    • 2:30:06 97.
      Key Points
    • 2:30:11 98.
      Resistance
    • 2:31:28 99.
      The Airway Resistance
    • 2:32:21 100.
      The Airway Resistance
    • 2:34:15 101.
      The Airway Resistance
    • 2:36:27 102.
      The Airway Resistance
    • 2:37:11 103.
      Calculation of Dynamic Resistance
    • 2:38:17 104.
      Evaluation of Airway Resistance
    • 2:40:59 105.
      Evaluation of Abnormality in Lung Vol.
    • 2:42:41 106.
      Flow-volume Curves
    • 2:43:51 107.
      Isovolume Pressure-flow Curves
    • 2:44:59 108.
      Flow-Volume Relationship
    • 2:46:06 109.
      Dynamic Airway Compression
    • 2:52:41 110.
      EPP is Influenced by Lung Elastic Recoil
    • 2:54:57 111.
      Pursed Lip Breathing (噘嘴吐氣)
    • 2:56:30 112.
      Abnormality in Lung Vol.
    • 2:57:23 113.
      Interpretation of Flow-Vol Loop
    • 2:58:10 114.
      Obstructive Lung Vol. Defect
    • 2:58:46 115.
      Chronic Obstructive Pulmonary Disease (慢性阻塞性肺病; COPD)
    • 2:59:00 116.
      Emphysema (肺氣腫)
    • 2:59:30 117.
      Asthma (氣喘)
    • 3:00:54 118.
      吸煙豬肺影片
    • 3:03:38 119.
      Restrictive Lung Vol. Defect
    • 3:03:54 120.
      Examples of Restrictive Lung Dz.
    • 3:03:54 121.
      Restrictive Lung Vol. Defect
    • 3:04:21 122.
      Examples of Restrictive Lung Dz.
    • 3:05:08 123.
      做那些動作使呼吸效率增加?為什麼?
    • 3:06:00 124.
      做那些動作使呼吸效率增加?為什麼?
    • 3:07:40 125.
      Key Points
    • 3:07:47 126.
      Hysteresis
    • 3:10:14 127.
      Surface Tension
    • 3:12:07 128.
      Law of LaPlace
    • 3:13:39 129.
      Surfactants
    • 3:14:10 130.
      Importance of Lung Surfactant
    • 3:15:11 131.
      Work of Breathing
    • 3:16:16 132.
      Effects of Diseases on PV Curve
    • 3:18:41 133.
      為什麼肺氣腫的病人每次的呼吸都很吃力?
    • 3:20:10 134.
      Effects of Diseases on PV Curve
    • 3:21:11 135.
      Key Points
    • 3:21:24 136.
      PL = Pal – Ppl(1)Pw = Ppl – Pbs(2)(1) + (2)Prs = PL + Pw = Pal – Pbsa) Pbs =0  Pw = Ppl = Pes Prs = Palb) Pao = VRaw + Pal When flow=0, Pao = Pal = Prsc) PL = Pal – Ppl = Pao|flow=0 – Pes
    • 3:21:52 137.
      Elastic Recoil of the Chest Wall
    • 3:24:13 138.
      Elastic Recoil of the Chest Wall
    • 3:26:22 139.
      Lung-Chest Wall Couplingin Static Status at Different Lung Volume
    • 3:28:27 140.
      Lung-chest Wall Coupling to Determine FRC
    • 3:33:36 141.
      Static Elastic Properties of the Lung and Chest Wall
    • 3:36:08 142.
      Static Elastic Properties of the Lung and Chest Wall
    • 3:38:26 143.
      Transmural Pressure Across the Lung Wall in Dynamic Status
    • 3:40:45 144.
      The Mechanics of Quiet Breathing
    • 3:46:27 145.
      P-V Relationships and Schematic Events of Resp. Cycle
    • 3:52:37 146.
      P-V Relationships and Schematic Events of Resp. Cycle
    • 3:54:33 147.
      Outline
    • 3:54:47 148.
      Overview
    • 3:55:07 149.
      Diffusion and Gas Transport
    • 3:56:11 150.
      Alveolo-Capillary Barrier
    • 3:56:46 151.
      Diffusion
    • 3:57:53 152.
      Diffusion Capacity
    • 3:59:04 153.
      Diffusion Capacity
    • 4:00:58 154.
      Physiologic Changes That Alter Diffusion Capacity
    • 4:00:59 155.
      Diffusion Capacity
    • 4:01:15 156.
      Physiologic Changes That Alter Diffusion Capacity
    • 4:03:09 157.
      Capillary Transit Time
    • 4:06:10 158.
      Perfusion-limited Gas
    • 4:07:21 159.
      Diffusion-limited Gas
    • 4:07:54 160.
      Diffusion and Perfusion Limitations
    • 4:10:12 161.
      Interpretation of Pulmonary Function Test
    • 4:15:02 162.
      Transport of O2 and CO2
    • 4:15:09 163.
      Oxygen Transport
    • 4:15:48 164.
      Blood Gas Measurement
    • 4:16:53 165.
      Blood Gas Measurement
    • 4:18:53 166.
      O2 Bound to Hb
    • 4:19:21 167.
      O2 Bound to Hb
    • 4:21:29 168.
      What does pulse oximeter measure?O2 dissolved in the blood plasmaO2 bound with hemoglobin
    • 4:22:30 169.
      O2 Concentration & Saturation in Anemia
    • 4:23:58 170.
      Cooperative Interactions
    • 4:26:40 171.
      O2 Bound to Hb
    • 4:29:34 172.
      O2 Bound to Hb
    • 4:32:08 173.
      Factors Affecting O2 Bound to Hb
    • 4:34:29 174.
      CO2 Transport
    • 4:35:43 175.
      CO2 Transport
    • 4:37:32 176.
      CO2 Transport
    • 4:38:08 177.
      CO2 Equilibrium Curve
    • 4:41:31 178.
      Assessment of Arterial Hypoxemia
    • 4:45:20 179.
      Case study
    • 4:50:51 180.
      Outline
    • 4:50:58 181.
      Control of Respiration
    • 4:51:57 182.
      Overview
    • 4:53:01 183.
      Receptors
    • 4:54:04 184.
      Receptors
    • 4:56:17 185.
      Receptors
    • 4:57:39 186.
      Central Controller in Brain Stem
    • 4:58:02 187.
      你覺得吸氣比重要還是呼氣比重要?
    • 4:58:55 188.
      Central Controller
    • 4:59:31 189.
      Central Controller
    • 5:00:51 190.
      Respiratory Neurons in the Brain Stem
    • 5:04:20 191.
      正常情況下,什麼時候正常呼吸的型態會改變?
    • 5:04:30 192.
      Central Controller
    • 5:05:13 193.
      Central Controller
    • 5:05:13 194.
      Central Controller
    • 5:05:24 195.
      Central Controller
    • 5:06:24 196.
      Effectors
    • 5:07:11 197.
      Outline
    • 5:07:16 198.
      Overview
    • 5:07:26 199.
      Chemical Control of Resp.
    • 5:08:38 200.
      Central Chemoreceptor
    • 5:10:20 201.
      Peripheral Chemoreceptor
    • 5:11:26 202.
      Silent Hypoxia (Happy Hypoxia)
    • 5:12:23 203.
      Regulation of breathing in response to changes in blood PCO2, PO2, and pH (H+) via negative feedback control
    • 5:14:14 204.
      Video
    • 5:15:18 205.
      Outline
    • 5:15:35 206.
      Acid-base Balance
    • 5:17:08 207.
      Effectiveness of a Buffer System
    • 5:18:33 208.
      Bicarbonate
    • 5:19:09 209.
      The Effect of Bicarbonate on Blood pH
    • 5:21:20 210.
      Davenport Diagram
    • 5:23:02 211.
      Respiratory Disturbances
    • 5:23:42 212.
      Metabolic Disturbances
    • 5:24:33 213.
      Compensatory Responses
    • 5:26:36 214.
      Compensatory Responses
    • 5:27:25 215.
      Outline
    • 5:27:34 216.
      Rest-to-Work Transitions
    • 5:28:40 217.
      Sub-maximal Exercise
    • 5:29:21 218.
      Ventilatory Control During Submaximal Exercise
    • 5:29:39 219.
      High Intensity Exercise
    • 5:30:46 220.
      High Intensity Exercise
    • 5:31:28 221.
      Oxygen Debt
    • 5:33:10 222.
      呼吸系統是運動的限制因子嗎?
    • 5:33:15 223.
      Do the Lungs Limit Exercise Performance?
    • 5:33:53 224.
      Effect of Training on Ventilation
    • 5:34:51 225.
      How to Increase Resp. Function During Exercise?
    • 5:39:34 226.
      How to Increase Resp. Function During Exercise?
    • 5:42:41 227.
      Effect of High Altitude on Resp. Function
    • 5:43:23 228.
      Immediate: Increased in Ventilation
    • 5:46:15 229.
      Days: Decreased Affinity of Hemoglobin for Oxygen
    • 5:48:29 230.
      Days to weeks: Increased Hemoglobin Production
    • 5:49:53 231.
      Respiratory Adaptations to High Altitude
    • 5:51:21 232.
      Overview
    • 5:51:51 233.
      The End
    Location
    Folder name
    Respiratory Physiology (呼吸生理學)
    Author
    賴亮全
    Branch
    賴亮全教授
    Created
    2022-10-06 22:00:38
    Last Updated
    2022-10-06 23:43:42
    Duration
    5:51:52