Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Intracranial pressure wikipedia , lookup
Cardiac output wikipedia , lookup
Obstructive sleep apnea wikipedia , lookup
Freediving blackout wikipedia , lookup
High-altitude adaptation in humans wikipedia , lookup
Hemodynamics wikipedia , lookup
Biofluid dynamics wikipedia , lookup
Pre-Bötzinger complex wikipedia , lookup
Circulatory system wikipedia , lookup
Common raven physiology wikipedia , lookup
Haemodynamic response wikipedia , lookup
Respiratory Physiology [the Ins and Outs] Jim Pierce Bi 145a Lecture 16, 2009-10 The Lungs The Lungs Pulmonary Tree Trachea and Esophagus Trachea Respiratory Epithelium Respiratory Epithelium Explained Brush Border and Goblet Cells Structure of the Distal Airway Alveoli Terminal Bronchioles, Respiratory Bronchioles, and Alveoli Blood Supply of the Distal Airway Alveolar Membrane (TEM) Pulmonary Circulation Lungs in situ Bronchial Arteries The Diaphragm Accessory Muscles Upper Airway Development Upper Airway Development Upper Airway Development Airway Budding Airway Budding Airway Budding Growing into the Pleural Cavity Lower Airway Development Lower Airway Development Airway Maturation Airway Maturation Airway Maturation Airway Maturation Capillary Blood Flow Lung Physiology The Lung has three jobs Absorb Oxygen Excrete Carbon Dioxide (and affect pH) Neurohormal and Hematopoetic Function (Remember - it’s a filter that all of the blood must traverse) Lung Physiology It’s not surprising to find Neurohormonal Function (note that 100% of the Cardiac Output must cross the lung) Thus, the body has placed a variety of enzymes on the vascular endothelium. Metabolic Roles Lung Physiology Do Not Forget that the lung is a Neurohormonal Organ People do because the gas exchange physiology is very interesting. Perhaps the role of the lung in immunologic dysfunction is more interesting. Lung Physiology Furthermore, Multipotent Stem Cells, Reticulocytes, and Megakaryocytes sometimes escape from the bone marrow and wedge into the lung microvasculature. They finish differentiation because of the presence of Reticular Fibers Pulmonary Physiology So we need to ask: 1) How do we BREATHE? That is, get air in and out of the lungs What are the parts of the airway and lungs that allow us to move the air? What are the muscles that move the air in and out? What controls them? Pulmonary Physiology 2) How do we VENTILATE? That is, how do we get air to the alveoli? What causes the movement of air to get to the terminal respiratory tract? What are the volumes of air that are breathed that make it there? How does the air distribute in the lung? What factors affect the distribution of air in the lungs? Pulmonary Physiology 3) How do we PERFUSE the lung? That is, how does blood flow in the lung? What brings the blood to the lungs? How is the blood flow distributed around the lungs? Where does the blood go? Where does the interstitial fluid go? What factors affect the regulation of blood flow? Pulmonary Physiology 4) How do we EXCHANGE GASES? That is, how do we get the O2 in and the CO2 out? What factors affect diffusion from the alveoli to the capillary? How does blood flow affect the balance of gases? How does ventilation affect the balance of gases? When is the exchange blood flow limited? When is the exchange ventilation limited? Pulmonary Physiology 5) How do we match VENTILATION and PERFUSION? That is, how do we make the blood and air go to the same place? What regulatory factors insure that ventilated lung are perfused? What factors insure that perfused lung is ventilated? How do we turn off perfusion or ventilation when the lung is not ventilating or perfusing? Pulmonary Physiology 6) How do we adjust pulmonary function to compensate for changes in the periphery? Increase in Oxygen Demand Increase in Carbon Dioxide Production Change in pH Breathing In the medulla, there is a respiratory center This center takes “respiratory inputs” Then it produces “respiratory outputs” Thus, it is directly responsible for controlling breathing (rate and depth) Breathing The medullary respiratory assesses Local (i.e. brain) pH Local pCO2 Afferent signals from the brain (thinking) Afferent signals from the periphery carotid bulb Heart, Lung The primary force on breathing is pCO2 Breathing The medullary respiratory center indicates: Frequency of Initiation of inspiration Duration of inspiration Force of inspiration Inspiratory / Expiratory pause Expiratory duration Expiratory force Breathing The respiratory cycle: Inspiration Inspiratory Pause (usually zero) Expiration Expiratory Pause Breathing How do we inspire? How do we expire? Breathing The brain controls the muscles of breathing indicating the respiratory rate. C3, C4, C5 nerve roots innervate the diaphragm via the phrenic nerve Other Cervical and Thoracic roots innervate the accessory muscles. Breathing – ACTIVE FORCE Muscles of Breathing: Principle Muscles Diaphragm Intercostal Accessory Muscles There are no skeletal muscles in the lung The Diaphragm Accessory Muscles Breathing – PASSIVE FORCE The connective tissue of the chest wall Determines the minimum and maximum volume of the chest cavity Does not control the minimum or maximum lung volume The connective tissue of the lung Primarily is elastic and tends to collapse Has some stiffness from connective tissue Chest Wall Remember: Chest wall is Separate from Lung Lungs Grew into the Pleural Cavity Chest Wall Lung Chest Wall and Lung The total force from muscles of the chest wall tend to Expand the Chest The lung – with no muscles but lots of elastic tissue – tends to collapse Chest Wall and Lung Chest Wall and Lung The “negative” pressure keeps the lungs “stuck” to the chest wall (it’s not truly negative – it’s actually just 5 below atmospheric) Breathing The overall ability of the chest and lung to allow a change in airway pressure based on volume moved is COMPLIANCE Chest Wall and Lung When the muscles relax, the equilibrium is at the end of a comfortable exhale It is possible to contract muscles To exhale more To inhale (We have “exhale” and “inhale” reserve) Chest Wall and Lung Why? It’s like a garage door opener: The balance of the heavy door and powerful spring keeps the “net mass” very low, making it easy to open and close Chest Wall and Lung Like the garage door opener: The balance of the chest wall expansion and lung contraction keeps the “net mass” very low, making it easy to open and close Inspiration When inspiratory muscles contract… The Thoracic Cage expands… Inspiration The thoracic cage expands both anteriorly and laterally Inspiration This is done by rib and sternum movement Ribs move like a bucket handle Inspiration Sternum moves like a water pump Inspiration Together, the thorax expands Breathing When inspiratory muscles contract… The Thoracic Cage expands… Generating a negative pressure On the Pleural Space Breathing As the Chest wall expands, the negative pressure in the pleural space actively expands the lung Breathing Thus, the negative inspiratory force is transmitted from chest wall to lung -TRANSMURAL! This leads to a pressure gradient between the mouth and lung… Which leads to gas flow. Ventilation Once we get negative pressure on the lung, we observe a net flow of air. P = Q * R Pressure gradient Flow Resistance (of airways) Inspiration All inspiration is active: Force is required to expand the thorax and draw air into the lungs Exhalation Exhalation can be either active or passive Passive exhalation is the “relaxation” of the inspiratory muscles Active exhalation is the contraction of the axial skeletal muscles Passive Exhalation During passive exhalation The inspiratory muscles relax The lung recoil is greater than the chest expansive force Thus, the lung and chest contract. This increases the pressure inside the lung This causes a pressure gradient, leading to airflow out through the airways Passive Exhalation One can prevent passive exhalation without continuous use of force. By closing the epiglottis, the airways are “disconnected” from the environment. Regardless of the pressure gradient, no air will flow Active Exhalation During active exhalation Intercostal, Abdominal muscles Contract This brings the chest to its smallest volume and braces it while the abdominal organs are forced upward into the diaphragm This increases the pressure in the chest cavity as well as in the lungs. As long as the airways remain open, Air will flow down the pressure gradient Active Exhalation Active Exhalation During active exhalation As long as the airways remain open, Air will flow down the pressure gradient Active exhalation with a closed epiglottis prepares you for a cough. Active exhalation at the end of passive exhalation produces only a small, slow exhale because the small airways have collapsed Chest Wall and Lung Chest Wall and Lung Questions?