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Joe Pistack MS/ED Respiratory system contains: Upper respiratory tract. Lower respiratory tract. Upper respiratory tract contains: The nose The nasal cavities Pharynx Larynx Upper trachea Lower respiratory tract: Lower trachea Bronchi Bronchioles Alveoli Nose-includes an external portion that forms part of the face. Nasal cavitiesseparated into right and left halves by a nasal septum. Air enters the nasal cavities through two openings called nostrils. Nasal hairs in the nostrils filter large particles of dust that would otherwise be inhaled. Nasal conchae-three bony projections appear on the lateral walls of the nasal cavities. Support mucous membrane. Contains blood vessels and mucoussecreting cells. Paranasal sinuses: Maxillary sinuses Frontal sinuses Ethmoidal sinuses Sphenoidal sinuses Mucous from the paranasal sinuses drain into the nasal cavity. Deviated septumNasal septum bends to one side or the other. Obstructs flow of air, makes breathing difficult. Surgical repair is called a septoplasty. Pharynx or throatLocated behind the oral cavity, between the nasal cavities. Includes three parts: Nasopharynx Oropharynx laryngopharynx Nasopharynx-upper section. Oropharynx-middle section. Laryngopharynx-lower Function section. of pharynx: Conducts food toward the esophagus. Functions as a passageway for both food and air. Also called the voicebox Three functions: (1)Passageway for air during breathing (2)Produces sound (3)Prevents food and foreign objects from entering the trachea Triangular structure made primarily of cartilage, muscles,and ligaments. Thyroid cartilage-largest of the cartilaginous structures . Protrudes in the front of the neck as the Adam’s apple. Epiglottis-located at the top of the larynx, acts as a flap, covers the opening of the trachea during eating so that food doesn’t enter the lungs. Folds of tissue composed of muscle and elastic ligaments covered by mucous membrane. The space between the vocal cords is the glottis. False vocal cords-do not produce sounds. True vocal cordsproduce sound, air flowing from the lungs through the glottis during exhalation causes the vocal cords to vibrate producing sound The loudness of your voice depends on the force with which air moves past the true vocal cords. The pitch of your voice depends on the tension exerted on the muscles of the true vocal cords. You form words with your pharynx, oral cavity, tongue and lip movement. Swallowing plays a key role in preventing food or water from entering into the respiratory tubes. Neurological patients who have difficulty swallowing are at risk for aspiration. (entrance of food or water into the lungs) Windpipe-tube 4 to 5 inches in length and 1 inch in diameter. Extends from the lower edge of the larynx downward into the thoracic cavity where it splits into the right and left bronchi Carina-point where the trachea splits, at the manubriosternal junction (where the manubrium of the sternum meets the sternal body) This area is very sensitive, touching during suctioning causes vigorous coughing. Insertion of a tube through a surgical incision into the trachea below the level of an obstruction. By passes the obstruction and allows air to flow through the tube into the lungs. Lies in front of the esophagus, the food tube. C-shaped rings of cartilage partially surround the trachea for its entire length. The rings are open on the back side of the trachea so that the esophagus can bulge forward as food moves along the esophagus into the stomach. Without the cartilaginous rings, the trachea would collapse and shut off air supply. Consists of : Bronchi Bronchioles Alveoli Resembles an upside down tree. Right and left primary bronchi are formed as the lower part of the trachea divides into two tubes. Primary bronchienter the lungs at a region called the hilus. Primary bronchi branch into secondary bronchi, which branch into smaller tertiary bronchi. Left bronchus is narrower because the heart lies to the left side of chest. Right bronchus is shorter and wider and extends downward in a vertical direction. The bronchi divide repeatedly into smaller tubes called bronchioles. Regulate the flow of air to the alveoli. Contraction of the bronchiolar smooth muscle causes the bronchioles to constrict, this decreases the bronchiolar lumen and decreases the flow of air. Relaxation causes the lumen to increase, thereby increasing the flow of air. Small grape-like structures, tiny air sacs that form at the ends of the respiratory passages. Function is to exchange oxygen and carbon dioxide across the alveolarpulmonary capillary membrane. Certain respiratory diseases cause thickening of the alveolar wall. Results in slow exchange of gases. Results in hypoxia, retained carbon dioxide, this results in acidosis ( disturbance in acidbase balance). Ex. Emphysema, this may result in clubbing of the fingers and toes. Amazing Facts: 10,000 liters of air per day goes through our lungs - that’s 2650 gallons There Have are about 300 million alveoli (300,000,000) the surface area of a tennis court - that’s about 2800 square feet. Clubbing: Enlarged fingertips and toes. Changes in thickness and shape of the nails. Due to formation of additional capillaries in attempt to deliver oxygen. Two lungs: Located in the pleural cavity. Extend from area above the clavicles to the diaphragm. Soft, cone-shaped, occupy most of the space in the thoracic cavity. Subdivided into lobes: Right lung has three lobes: superior middle inferior Left lung: superior inferior Upper, rounded part is called , the apex. The base rests on the diaphragm. Amount of air lungs can hold depends on build, age, and physical condition. Pleura-lining of the inner chest wall, continuous serous membrane. Visceral-inner layer. Parietal pleuraouter layer. Expanded lungs normally fill the thoracic cavity. Tendency of the lungs to collapse is due to two factors: Elastic recoil Alveolar surface tension Negative intrapleural pressure is eliminated, lungs collapse. Lungs need to be expanded to function properly. Elastic recoil opposes lung expansion. Negative intrapleural pressure must exceed the elastic recoil and surface tension. Ex. balloon High surface tension within the alveoli is favorable for a collapsed lung. Surfactant Problem decreases surface tension. with preterm infants, not enough surfactant is secreted so they have difficulty breathing. Rx. Steroids. Intrapleural pressure remains negative when no holes exist in the chest wall. When the lungs expand, the diaphragm contracts, the pull causes negative pressure. Anything that collects in the intrapleural space can collapse the lung. Ex. blood, air, and drainage. A knife wound would eliminate intrapleural pressure. Respiration includes: (1)-ventilation (2)-exchange or breathing of oxygen and carbon dioxide (3)-transport of oxygen and carbon dioxide by the blood Ventilation-movement of air into and out of the lungs. Two phases: Inhalation-breathing-in phase Exhalation-breathing-out phase Respiratory cycle-one inhalation and one exhalation . Dependent on Boyle’s law, “As volume increases, pressure decreases; as volume decreases, pressure increases.” Thoracic pressure decrease causes air to move through the nose and into the lungs. Thoracic pressure increase causes air to move out of the lungs. When respiratory muscles relax, they decrease thoracic volume. Change in thoracic volume is due to the contraction and relaxation of the respiratory muscles. On inhalation-respiratory muscles, (the diaphragm and intercostal muscles) contract. Diaphragm Accessory is the chief muscle of inspiration. muscles of respiration-muscles of the abdominal wall and internal intercostal muscles. Exchange of gases occurs at two sites: (1)lungs (2)cells In lungs, oxygen diffuses from the alveoli into the pulmonary capillaries. Carbon dioxide diffuses from the pulmonary capillaries into the alveoli. In the cell, oxygen diffuses from the capillaries into the cells, carbon dioxide diffuses from the cells into the capillaries. Blood transports oxygen and carbon dioxide. Different names. volumes of air we breathe have Four pulmonary volumes: (1)-tidal volume (2)-inspiratory reserve volume (3)-expiratory reserve volume (4)-residual volume A spirometer is used to measure pulmonary volumes. Tidal volume-the amount of air moved in and out of the lungs with each breath. Usually about 500ml. Inspiratory reserve volume-in addition to the normal volume, any extra air that you can breathe in. Approximately 3000ml. Expiratory reserve volume-the normal amount of air you exhale plus any extra, usually about 1100ml. Residual volume-after forced exhalation, about 1100ml of air remains in the lungs. The remaining air is the residual volume. Residual air remains in the lungs at all times, even between breaths. Anatomical dead space-some air that you inhale never reaches the alveoli, it is not available for gas exchange. Normal breathing is rhythmic and involuntary. Normal respiratory rate is 12 to 20 breaths per minute in an adult. In a child, normal respiratory rate is 20 to 40 breaths per minute. Medullary respiratory control center-main control center for breathing, located in the medulla, sets the basic breathing rhythm. Pneumotaxic center and apneustic center-located in the pons, modify and help control breathing patterns Opioids, such as morphine, depress respiratory function, do not administer without checking respirations. Hering-Breurer Reflex-reflex that prevents overinflation of the lungs. Hyperventilation-increase in the rate and depth of respirations. Causes excess exhaling of carbon dioxide and produces hypocapnia (diminished carbon dioxide in the blood). Hypoventilation: Decrease in the amount of air entering the alveoli. Causes insufficient amount of oxygen and excessive amount of carbon dioxide in the blood. Causes are respiratory obstruction - lung disease, deformity of the chest, mucous plug. Exhalation: Occurs when the respiratory muscles relax, allowing the thorax to return to smaller, resting thoracic volume. Muscles of respiration contract in response to stimulation of the phrenic and intercostal nerves. Inhalation delivers fresh oxygen-rich air to the alveoli, and exhalation removes carbon dioxidelaiden air from the alveoli. The exchange of gases occurs at two sites: The lungs The cells Gas exchange occurs in the lungs, specifically across the membranes of the alveolus and the pulmonary capillary. Three conditions make alveoli suited for exchange: (1) Large surface area, (2)Thin alveolar and capillary walls, (3)Closeness of the alveoli to the pulmonary capillaries. Lung capacity decreases. Protective mechanisms of respiratory disease decline. Number of alveoli diminishes resulting in decreased oxygenation. Decreased oxygenation decreases the amount of physical activity that the person is capable of. Lungs show wear and tear from a lifetime of inhaling harmful substances such as pollens, pollutants, cigarette smoke. apnea-temporary cessation of breathing. Dyspnea-difficult or labored breathing. Tachypnea-rapid Eupnea-normal, breathing. quiet breathing. Orthopnea-difficult breathing that is relieved by sitting-up position. Usually dyspnea is relieved with two pillows. Cheyne-Stokes respirations-an irregular breathing pattern characterized by a series of shallow breaths that gradually increase in depth and rate. A period of apnea lasting 10 to 60 seconds follows, the cycle then repeats.