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Gas Exchange and Transport Gas Exchange and Transport The driving force for pulmonary blood and alveolar gas exchange is the Pressure Differential – The difference between the partial pressure of a gas (O2 or CO2) above a fluid and dissolved in fluid (alveoli or blood) Gas Exchange and Transport Pressure Differential Fig 13.1 Gas Exchange and Transport Henry’s Law: The rate of gas diffusion into a liquid depends on: 1) Pressure differential between the gas above the fluid and gas dissolved in fluid 2) Solubility (dissolving power) of the gas in the fluid CO2 highly soluble Gas Exchange and Transport Saturation with water vapor - lower PO2 Constant loading and unloading of CO2 and O2 FRC necessary to prevent swings in CO2 and O2 concentration in alveoli PO2 – 100 mm Hg: regulates breathing and 02 loading of Hb Fig 13.2 PCO2 – 40 mm Hg: chemical basis for ventilatory control via respiratory center Gas Exchange and Transport Time Required for Gas Exchange Capillary transit time is ~0.75 s During maximal exercise, capillary transit time is ~0.4 s Gas exchange during maximal exercise not a limiting factor Fig 13.2 Gas Exchange and Transport Time Required for Gas Exchange Pulmonary disease impacts this process: 1. Thicker alveolar membrane 2. Reduced surface area Fick's Law-Gas diffuses at rate proportional to: Tissue thickness (inversely) Tissue area (directly) Fig 13.2 Gas Exchange and Transport O2 Transport: •Dissolved oxygen in blood only sustains life for about 4 seconds (0.3 mL O2 / dL) •Small amount establishes PO2 which regulates breathing and oxygen loading of hemoglobin Gas Exchange and Transport O2 Transport: •Hemoglobin (Hb) – Protein in red blood cells that transports 02 bound to iron •Each Hb has 4 iron atoms (can bind 4 O2) •Hb transports 19.7 ml/dL (vs 0.3 ml/dL - plasma) (65 x that in plasma) Anemia: Low iron in red blood cells results in low oxygen carrying capacity Fig 13.3 Gas Exchange and Transport Oxyhemoglobin dissociation curve: Describes Hb saturation with O2 at various PO2 levels 100 mm Hg: 98% saturation 60 mm HG: decline in % saturation 40 mm HG: 75% of O2 remains with Hb - 5 ml delivered to tissues Athletes? Fig 13.4 Gas Exchange and Transport Bohr effect – •Increased blood acidity (lactic acid), temperature, CO2 causes downward shift to the right •Facilitates dissociation of O2 from Hb •No effect on capillary blood Hb-O2 binding Fig 13.4 Gas Exchange and Transport Oxyhemoglobin dissociation curve: Myoglobin: •Intramuscular O2 storage protein •Transfers O2 to mitochondria when PO2 falls •At 40 mm Hg, Mb 95% saturated with O2 •No Bohr effect occurs with myoglobin Fig 13.4 Dynamics of Pulmonary Ventilation Pulmonary Ventilation Ventilatory Control – How does our body control rate and depth of breathing in response to metabolic need Medulla – Inspiratory neurons activate diaphragm and intercostals Expiratory neurons activated by passive recoil of lungs *Mechanisms maintain constant alveolar and arterial gas pressures Fig 14.1 Pulmonary Ventilation 1. At rest, chemical state of the blood controls ventilation PO2, PCO2, acidity (lactate), temperature PO2 – no effect on medulla (peripheral chemoreceptors detect arterial hypoxia, altitude) PCO2 – most important respiratory stimulus to medulla at rest Fig 14.2 Pulmonary Ventilation 2. During exercise, no single mechanism explains increase in ventilation (hyperpnea) Neurogenic Factors: Cortical: Motor cortex stimulates respiratory neurons to increase ventilation Peripheral: Mechanoreceptors in muscles, joints, tendons influence ventilatory response •Peripheral chemoreceptors become sensitive to CO2, H+, K+, and temperature during strenuous exercise Pulmonary Ventilation Phases of Ventilatory Response During Exercise: I. Neurogenic – central command, peripheral input stimulates medulla Fig 14.4 II. Neurogenic – continued central command, peripheral chemoreceptors (carotid) III. Peripheral - CO2, H+, lactate (medulla), peripheral chemoreceptors Recovery – removal of central, peripheral, chemical input Rapid Slower rise exponential rise Steady Abrupt state decline ventilation