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IrresistibleTroll

Uploaded by IrresistibleTroll

University of Baghdad

Dr. Sahar Hashim

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lung capacity pulmonary function respiratory system physiology

Summary

This document provides an overview of lung volume and capacity, including different types of lung volumes and capacities, and their normal values. It also discusses the factors affecting pulmonary ventilation and the regulation of respiration.

Full Transcript

Pulmonary or lung function tests are useful in assessing the functional status of the respiratory system. These tests involve measurement of lung volumes and capacities. Pulmonary ventilation can be studied by recording the volume movement of air into and out of the lungs, a method called spirometr...

Pulmonary or lung function tests are useful in assessing the functional status of the respiratory system. These tests involve measurement of lung volumes and capacities. Pulmonary ventilation can be studied by recording the volume movement of air into and out of the lungs, a method called spirometry. Pulmonary function tests are carried out mostly by using spirometer. The graphical recording of lung volumes and capacities is called spirogram. Spirometer: During expiration, the air enters the spirometer from lungs. The inverted drum moves up and the pen draws a downward curve on the recording drum. The air in lung is classified into two divisions: 1- Lung volumes. 2-Lung capacities. Lung volumes are the static volumes of air breathed by an individual. The lung volumes are of four types: 1. Tidal volume (TV) Tidal volume is the volume of air breathed in and out of lungs in a single normal quiet respiration. Tidal volume signifies the normal depth of breathing Normal value = 500 mL (0.5 L) 2. Inspiratory reserve volume (IRV) Inspiratory reserve volume is an additional volume of air that can be inspired forcefully after the end of normal inspiration. Normal value = 3300 mL (3.3 L). 3. Expiratory reserve volume (ERV) Expiratory reserve volume is the additional volume of air that can be expired out forcefully, after normal expiration. Normal value = 1000 mL (1 L). 4. Residual volume (RV) Residual volume is the volume of air remaining in the lungs even after forced expiration. Normally, lungs cannot be emptied completely even by forceful expiration. Some quantity of air always remains in the lungs even after the forced expiration. Normal value = 1200 mL (1.2 L) Lung capacities are the combination of two or more lung volumes. Lung capacities are of four types: 1. Inspiratory capacity (IC) Inspiratory capacity is the maximum volume of air that is inspired after normal expiration (end expiratory position). It includes tidal volume and inspiratory reserve volume. IC = TV + IRV = 500 + 3300 = 3800 mL 2. Vital capacity (VC) It is the maximum volume of air that can be expelled out forcefully after a deep (maximal) inspiration. Vital capacity includes inspiratory reserve volume, tidal volume and expiratory reserve volume. VC = IRV + TV + ERV = 3300 + 500 + 1000 = 4800 mL 3. Functional residual capacity (FRC) It is the volume of air remaining in the lungs after normal expiration (after normal tidal expiration). Functional residual capacity includes expiratory reserve volume and residual volume. FRC = ERV + RV = 1000 + 1200 = 2200 mL 4. Total lung capacity (TLC) Total lung capacity is the volume of air present in the lungs after a deep (maximal) inspiration. It includes all volumes. TLC = IRV + TV + ERV + RV = 3300 + 500 + 1000 + 1200 = 6000 mL Pulmonary ventilation It is the volume of air moving in and out of lungs per minute in quiet breathing. It is also called respiratory minute volume (RMV). Normal value and calculation Normal value of pulmonary ventilation is 6 L/minute. It is the product of tidal volume (TV) and the rate of respiration (RR). It is calculated by the formula: Pulmonary ventilation = Tidal volume × Respiratory rate = 500 mL × 12/minute = 6,000 mL = 6 L/minute 1. Surface tension of alveolar fluid ❖ Surfactant 2. Lung compliance ❖Elasticity ❖Surface tension 3. Airway resistance It is the amount of air utilized for gaseous exchange every minute. Alveolar ventilation is different from pulmonary ventilation. In pulmonary ventilation, 6 L of air moves in and out of lungs in every minute. But the whole volume of air is not utilized for exchange of gases. The volume of air subjected for exchange of gases is the alveolar ventilation. The air trapped in the respiratory passage (dead space) does not take part in gaseous exchange. Normal value of alveolar ventilation is 4,200 mL (4.2 L)/ minute. Respiration is a reflex process. But it can be controlled voluntarily also. Voluntary arrest of respiration (voluntary apnea) is possible only for a short period of about 40 seconds. However, by practice, breathing can be withheld for a long period. At the end of that period, the person is forced to breathe. A. Nervous or neural mechanism: Nervous mechanism that regulates respiration includes respiratory centers, afferent nerves and efferent nerves. The nervous system normally adjusts the rate of alveolar ventilation almost exactly to the demands of the body, even during heavy exercise and most other types of respiratory stress. Respiratory centers are group of neurons, which control the rate, rhythm and force of respiration. These centers are bilaterally situated in reticular formation of brainstem, receive afferent impulses from different parts of the body and, modulate the movements of thoracic cage and lungs accordingly through efferent nerve fibers. The respiratory center is composed of several groups of neurons. It is divided into three major collections of neurons: 1. A dorsal respiratory group, located in the dorsal portion of the medulla oblongata, which mainly causes inspiration. Its control inspiration and respiratory rhythm 2. A ventral respiratory group, located in the ventrolateral part of the medulla, which mainly causes expiration. Functions in both inspiration and expiration. The function of this neuronal group differs from that of the dorsal respiratory group in several important ways. 3- The pneumotaxic center, located dorsally in the superior portion of the pons, which mainly controls rate and depth of breathing. The function of this center is primarily to limit inspiration. This has a secondary effect of increasing the rate of breathing because limitation of inspiration also shortens expiration and the entire period of each respiration. B. Chemical mechanism: The chemical mechanism for regulation of respiration is operated through the chemoreceptors which give response to chemical changes in blood such as: 1. Hypoxia {decreased partial pressure of O2 in blood (PO2)} 2. Hypercapnea {increased partial pressure of CO2 in blood (PCO2)} 3. Increased hydrogen ion concentration. Chemoreceptors are classified into two groups: 1. Central chemoreceptors: The chemoreceptors present in the brain, situated in medulla oblongata, close to dorsal respiratory group of neurons. The main stimulant for the central chemoreceptors is the increased hydrogen ion concentration. ▪ If hydrogen ion concentration increases in the blood, it cannot stimulate the central chemoreceptors because, the hydrogen ions from blood cannot cross the blood-brain barrier and blood cerebrospinal fluid barrier. ▪ On the other hand, if carbon dioxide increases in the blood, it can easily cross the blood-brain barrier and blood cerebrospinal fluid barrier and enter the interstitial fluid of brain or the cerebrospinal fluid. There, the carbon dioxide combines with water to form carbonic acid. Since carbonic acid is unstable, it immediately dissociates into hydrogen ion and bicarbonate ion. ▪ The hydrogen ions stimulate the central chemoreceptors. Chemoreceptors in turn send stimulatory impulses to dorsal respiratory group of neurons causing increased ventilation (increased rate and force of breathing). Because of this, the excess carbon dioxide is washed out and the respiration is brought back to normal. 2. Peripheral chemoreceptors: Chemoreceptors present in the carotid and aortic region are called peripheral chemoreceptors. Reduction in partial pressure of oxygen is the most potent stimulant for the peripheral chemoreceptors; but these receptors are mildly sensitive to the increased partial pressure of carbon dioxide and increased hydrogen ion concentration. The relationship between oral health and systemic conditions, including the association between poor oral hygiene, periodontal disease, and respiratory disease, has been increasingly debated over recent decades. Oral bacteria and, especially, periodontal pathogens have been implicated as important agents with regard to causing other illnesses including respiratory diseases Four possible mechanisms to explain the biological plausibility of an association between oral conditions and nosocomial respiratory infections have been described: 1. Oral pathogens directly aspirated into the lungs. The most common respiratory pathogens are found within the dental plaque inside the oral cavity. These bacteria, once established in the mouth, can be aspirated into the lungs and cause infection. 2. Salivary enzymes associated with periodontal disease modify respiratory tract mucosal surfaces and promote adhesion and colonization by respiratory pathogens, with consequent aspiration into the lungs thereby causing infection. 3.Hydrolytic enzymes from periodonto-pathic bacteria may destroy the salivary film that protects against pathogenic bacteria. 4.The presence of a large variety of cytokines and other biologically active molecules continually released from periodontal tissues and peripheral mononuclear cells, in case of untreated periodontitis, may alter the respiratory epithelium and promote colonization by respiratory pathogens, thereby resulting in infection.

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