Pulmonary System Study Guide PDF

Part 1 Pulmonary 1) Students will identify the parts of the conducting and respiratory zones of the lungs and will interpret the functions of lung volumes and capacities. The respiratory system includes the lungs and a series of airways that connect the lungs to the external environment. The structures of the respiratory system are subdivided into a conducting zone (or conducting airways), which brings air into and out of the lungs, and a respiratory zone lined with alveoli where gas exchange occurs. The functions of the conducting and respiratory zones differ, and the structures lining them also differ. Conducting zone The conducting zone includes the nose, nasopharynx, larynx, trachea, bronchi, bronchioles, and terminal bronchioles. These structures function to bring air into and out of the respiratory zone for gas exchange and to warm, humidify, and filter the air before it reaches the critical gas exchange region. The progressively bifurcating airways are referred to by their generation number. The trachea, which is the zeroth generation, is the main conducting airway. The trachea divides into the right and left mainstem bronchi (the first generation), which divide into smaller bronchi, continuing this process through 23 generations, culminating in the airways of the 23rd generation. Cartilage is present in the walls of the zeroth to 10th generations of conducting airways; it functions structurally to keep those airways open. Starting with the 11th generation, cartilage disappears; to remain open, those airways with no cartilage depend on the presence of a favorable transmural pressure. The conducting airways are lined with mucus-secreting and ciliated cells that function to remove inhaled particles. Large particles are usually filtered out in the nose, while small particles are captured by mucus and swept upward by the rhythmic beating of cilia. The walls of the conducting airways contain smooth muscle, which is regulated by the autonomic nervous system: 1. Sympathetic adrenergic neurons activate β₂ receptors on bronchial smooth muscle, leading to relaxation and dilation of the airways. These β₂ receptors are also activated by epinephrine from the adrenal medulla and by β₂-adrenergic agonists such as isoproterenol. 2. Parasympathetic cholinergic neurons activate muscarinic receptors, leading to contraction and constriction of the airways. Changes in airway diameter affect airway resistance, altering air flow. β₂-adrenergic agonists (e.g., epinephrine, isoproterenol, albuterol) are used to dilate airways in the treatment of asthma. Part 1 Pulmonary Respiratory zone The respiratory zone includes structures lined with alveoli and thus involved in gas exchange: the respiratory bronchioles, alveolar ducts, and alveolar sacs. Respiratory bronchioles are transitional structures—they have cilia and smooth muscle, like the conducting airways, but also participate in gas exchange as alveoli occasionally bud off their walls. Alveolar ducts are completely lined with alveoli, but they contain no cilia and little smooth muscle. Alveolar sacs are the terminal structures of the respiratory zone, also lined with alveoli. Alveoli are pouchlike evaginations of the respiratory bronchioles, alveolar ducts, and alveolar sacs. Each lung contains approximately 300 million alveoli, with a diameter of ~200 micrometers (μm). The thin alveolar walls and large surface area allow rapid and efficient diffusion of oxygen (O₂) and carbon dioxide (CO₂) between alveolar gas and pulmonary capillary blood. The alveolar walls contain elastic fibers and epithelial cells called type I and type II pneumocytes (alveolar cells): Type II pneumocytes synthesize pulmonary surfactant, which reduces surface tension in the alveoli, and they have regenerative capacity for type I and type II pneumocytes. The alveoli also contain phagocytic cells called alveolar macrophages, which keep the alveoli free of dust and debris since alveoli have no cilia. Macrophages migrate to the bronchioles, where cilia transport debris to the pharynx for swallowing or expectoration. Part 1 Pulmonary 2) Students will calculate ventilation rates, dilution effect of dead space, alveolar ventilation, alveolar PO2 and FEV1 /FVC ratios. Static volumes of the lung are measured with a spirometer ( Table 5.1 ). Typically, the subject is sitting and breathes into and out of the spirometer, displacing a bell. The volume displaced is recorded on calibrated paper ( Fig. 5.2 ). First, the subject is asked to breathe quietly. Normal, quiet breathing involves inspiration and expiration of a tidal volume (V t ). Normal tidal volume is approximately 500 mL and includes the volume of air that fills the alveoli plus the volume of air that fills the airways. Next, the subject is asked to take a maximal inspiration, followed by a maximal expiration. With this maneuver, additional lung volumes are revealed. The additional volume that can be inspired above tidal volume is called the inspiratory reserve volume, which is approximately 3000 mL. The additional volume that can be expired below tidal volume is called the expiratory reserve volume, which is approximately 1200 mL. The volume of gas remaining in the lungs after a maximal forced expiration is the residual volume (RV), which is approximately 1200 mL and cannot be measured by spirometry. Lung capacities In addition to these lung volumes, there are several lung capacities; each lung capacity includes two or more lung volumes. The inspiratory capacity (IC) is composed of the tidal volume plus the inspiratory reserve volume and is approximately 3500 mL (500 mL + 3000 mL). The functional residual capacity (FRC) is composed of the expiratory reserve volume (ERV) plus the RV, or approximately 2400 mL (1200 mL + 1200 mL). FRC is the volume remaining in the lungs after a normal tidal volume is expired and can be thought of as the equilibrium volume of the lungs. The vital capacity (VC) is composed of the IC plus the expiratory reserve volume, or approximately 4700 mL (3500 mL + 1200 mL). Vital capacity is the volume that can be expired after maximal inspiration. Its value increases with body size, male gender, and physical conditioning and decreases with age. Finally, as the terminology suggests, the total lung capacity (TLC) includes all of the lung volumes: It is the vital capacity plus the RV, or 5900 mL (4700 mL + 1200 mL).

Pulmonary System Study Guide PDF

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