Anatomy, Physiology, and Disease An Interactive Journey for Health Professionals Second Edition CHAPTER 13 The Respiratory System: It's a Gas
Introduction Respiratory system's primary function: to transport oxygen from atmosphere to bloodstream to be utilized by cells, tissues, organs for process of cellular respiration, which is necessary to sustain life
Introduction Respiratory system moves 12,000 quarts of air per day in and out of lungs Respiratory system removes waste gas carbon dioxide so it doesn't build up in toxic levels
Learning Objectives List and state the basic functions of the components of the respiratory system Differentiate between respiration and ventilation Explain how the respiratory system warms and humidifies inhaled air State the purpose and function of the mucociliary escalator
Learning Objectives Differentiate between the upper and lower airways and their functions Discuss the process of gas exchange at the alveolar level Describe the various skeletal structures related to the respiratory system Explain the actual process of breathing Discuss several common respiratory system diseases
System Overview Cellular respiration depends on continuous supply of oxygen, found in abundance in air we breathe Using oxygen produces carbon dioxide, which would become toxic if allowed to build in bloodstream; must be removed
System Overview Respiratory system closely related to heart and circulatory system; they are sometimes grouped together as cardiopulmonary system
System Overview Components of respiratory system Two lungs that serve as vital organs Upper and lower airways that conduct gas in and out of the system Terminal air sacs called alveoli surrounded by network of capillaries that provide for gas exchange
System Overview Components of respiratory system Thoracic cage that houses, protects, facilitates function for the system Muscles of breathing that include the main muscle, the diaphragm, and accessory muscles
Figure 13-1 The various components of the respiratory system.
Ventilation versus Respiration Air contains many gases, predominantly nitrogen, which is a support gas that keeps lungs open with its constant volume and pressure Next highest concentration found in air is oxygen, essential to life; carbon dioxide is found in very small concentrations
Ventilation versus Respiration Ventilation: bulk movement of air into and out of lungs where gas exchange will takes place Respiration: process of gas exchange, where oxygen added to blood and carbon dioxide removed
Ventilation versus Respiration External respiration: gas exchange in lungs occurs between blood and air in the external atmosphere Internal respiration: oxygenated blood transported internally via cardiovascular system to cells and tissues; oxygen moves into cells as carbon dioxide removed
Table 13-1 Gases in the Atmosphere
Figure 13-2 Contrast of ventilation and external and internal respiration.
The Airways and Lungs We have reserve of oxygen to last 4 to 6 minutes; after that we will die if we don't get more oxygen Respiratory system is series of branching tubes called bronchi and bronchioles
The Airways and Lungs Transport atmospheric gas deep within lungs to small air sacs called alveoli, which represent terminal end of respiratory system
The Airways and Lungs Each alveolus is surrounded by capillaries; combination called alveolarcapillary membrane; represents connection between respiratory and cardiovascular systems
Upper Airways of Respiratory Tract Upper airways consists of nose, mouth, pharynx, and larynx Functions include: Heating or cooling inspired gases to body temperature Filtering Humidifying
Upper Airways of Respiratory Tract Upper airways consists of nose, mouth, pharynx, larynx Functions include: Sense of smell or olfaction Producing sounds or phonations Ventilation, or conducting gas to lower airways
Figure 13-3 The upper airway and vocal cords.
Upper Airways of Respiratory Tract While some people breathe through their mouths, we are meant to breathe through our noses Rigid structure made of cartilage and bone
Upper Airways of Respiratory Tract While some people breathe through their mouths, we are meant to breathe through our noses Nasal cavity: behind nose, divided into three main regions Vestibular Olfactory Respiratory
Figure 13-4 The nasal regions.
Upper Airways of Respiratory Tract Vestibular region: located inside nostrils and contains coarse nasal hairs that act as first line of defense for respiratory system These hairs (vibrissae) covered with sebum, greasy substance secreted by sebaceous glands of nose Sebum helps trap particles; keeps hairs soft and pliable
Upper Airways of Respiratory Tract Olfactory region: located on roof of nasal cavity, allowing air to be held there so it can be sampled
Upper Airways of Respiratory Tract Respiratory region Air warmed to body temperature and moistened in this region inside nasal cavity, which is lined with mucous membranes and richly supplied with blood There are three scroll-like bones (turbinates) that split incoming air into three channels, providing more surface area
Upper Airways of Respiratory Tract Respiratory region Turbinates serve to make incoming air current more turbulent, bringing more air in contact with mucous membranes for warming and moisture, adding 650 to 1,000mLs of water each day to moisten air to 80% relative humidity
Pathology Connection: The Nose Allergic rhinitis Occurs when allergens (like pollen) trigger nasal mucosa to secrete excessive mucous Treatments: antihistamine medications; allergy injections that desensitize person to allergen
Pathology Connection: The Nose Nasal polyps Noncancerous growths within nasal cavity May be related to chronic inflammation Can be surgically removed if they become large enough to block nasal passageway
Upper Airways of Respiratory Tract Mucociliary escalator Cells in epithelial lining of airways of respiratory system are called pseudostratified ciliated columnar cells Consists of single layer of tall columnlike cells that have nuclei at different heights, giving appearance of two or more layers when there is only one Each columnar cell has 200 to 250 cilia on its surface
Upper Airways of Respiratory Tract Mucociliary escalator Goblet cells and submucosal glands are interspersed and produce about 100mLs of mucus per day Mucus resides as two layers: Cilia reside in sol layer; contains thin, watery fluid that allows them to beat freely Top layer is gel layer that is more viscous and sticky, trapping small particles
Upper Airways of Respiratory Tract Mucociliary escalator Cilia act as tiny "oars" resting in watery sol layer
Upper Airways of Respiratory Tract Mucociliary escalator Cilia beat 1,000 to 1,500 times per minute and propel gel layer and its trapped debris onward and upward about one inch per minute to be expelled In nose, debris-laden secretions pushed toward front of nasal cavity to be expelled through nose
Upper Airways of Respiratory Tract Mucociliary escalator Pseudostratified ciliated columnar epithelium propels gel layer toward oral cavity to be expectorated with cough or swallowed into stomach
Figure 13-5 The mucociliary escalator.
Upper Airways of Respiratory Tract Skull contains air-filled cavities called sinuses that connect to nasal cavity via small passageways Located around nose and sometimes referred to as paranasal sinuses Cavities help prolong and intensify sound produced with our voice and helps to lighten weight of head
Upper Airways of Respiratory Tract Skull contains air-filled cavities called sinuses that connect to nasal cavity via small passageways Sinuses do not exist at birth Develop as we grow; facial features changes influenced by sinuses as we mature Sinuses also help to warm and moisturize air
Figure 13-6 The paranasal sinuses.
Upper Airways of Respiratory Tract Pharynx, or throat, is hollow muscular structure beginning behind nasal cavity, lined with epithelial tissue Pharynx can be divided into three sections Nasopharynx Oropharynx Laryngopharynx
Figure 13-7 The nasopharynx, oropharynx, and laryngopharynx and related structures.
Upper Airways of Respiratory Tract Nasopharynx is uppermost section, beginning behind nasal cavity Section contains lymphatic tissue called adenoids; passageways into middle ear called Eustachian tubes Air from nasal cavity passes through nasopharynx
Upper Airways of Respiratory Tract Oropharynx is located behind oral, or buccal, cavity Conducts not only atmospheric gas but also food and liquid Air breathed through both nose and mouth passes through here, as does anything that is swallowed
Upper Airways of Respiratory Tract Tonsils are part of lymph system Palatine tonsils are located in oropharynx, as are lingual tonsils located at back of tongue During swallowing, uvula and soft palate move in posterior and superior position to protect nasopharynx and nasal cavity from entry of food or liquid; can be overcome by forceful laughing
Upper Airways of Respiratory Tract Laryngopharynx is lowermost portion of pharynx Air breathed and/or swallowed passes through laryngopharynx Swallowed materials pass through esophagus to get to stomach Air travels through larynx and trachea on its way to lungs
Upper Airways of Respiratory Tract Larynx (voice box) Semirigid structure composed of cartilage connected by muscles and ligaments that provide movement of vocal cords to control speech Adam's apple (thyroid cartilage) is largest of cartilages found in larynx
Upper Airways of Respiratory Tract Larynx (voice box) Cricoid cartilage lies beneath it, providing structure and support for airways so they do not collapse Glottis is opening that leads into larynx and eventually lungs
Upper Airways of Respiratory Tract Epiglottis Leaf-shaped flaplike fibrocartilage Closes over opening to larynx when you swallow; opens up when you breathe, as part of swallowing reflex (glottic or sphincter mechanism) Seals so food does not enter lungs
Upper Airways of Respiratory Tract Vocal cords act as dividing line between upper and lower airways Lower airway starts below vocal cords Upper airway ends at vocal cords
Pathology Connection: Common cold The Upper Airways Caused by over 200 different strains of viruses Causes acute inflammation of upper respiratory mucous membranes Treated by managing symptoms
Pathology Connection: Common cold The Upper Airways Can be prevented with good hand washing Should not be confused with colds, allergies or the flu (which are different diagnoses)
Table 13-2 Comparison of Asthma, Cold and Influenza
Sinusitis Pathology Connection: The Upper Airways Infection and inflammation of sinuses by viruses or bacteria Causes pressure, pain, headaches Tonsillitis Inflammation, swelling and pain of tonsils May require tonsillectomy if severe
Pathology Connection: Pharyngitis Sore throat The Upper Airways Strep throat caused by streptococcus bacteria
Laryngitis Pathology Connection: The Upper Airways Inflammation of voice box Characterized by hoarseness and loss of speech Caused by infection or excessive use of voice
Figure 13-8 The upper airway and related infections.
Pathology Connection: The Upper Airways Acute epiglottitis Potential airway emergency infection that causes swelling of epiglottis and airway obstruction Typically caused by Haemophilus influenzae type B Most common in children ages 2 to 6 (incidence decreasing since introduction of Hib vaccine)
Pathology Connection: The Upper Airways Acute epiglottitis Symptoms: acute swelling of epiglottis, fever, sore throat Onset rapid; requires rapid treatment Treatments: maintain airway, antibiotics
Pathology Connection: The Upper Airways Laryngotracheobronchitis (LTB) Infection of laryngeal area characterized by noisy breathing, especially on inspiration Symptoms Barking cough Inspiratory stridor (high-pitched sound often heard without using stethoscope) Disease was previously called croup
Pathology Connection: Sleep apnea The Upper Airways Breathing stops during sleep Caused by soft tissue at back of throat relaxing and blocking airway Can cause fatigue during day Long-term, undiagnosed sleep apnea can cause other health problems (high blood pressure, weight gain, and headaches)
Pathology Connection: Sleep apnea The Upper Airways Diagnosed during sleep study, where patient monitored while sleeping Treatment: special pillows and positioning patient that help to keep airway open; weight loss may reduce severity More severe obstructive sleep apnea may be treated with oral appliances, breathing devices, or surgery
The Lower Respiratory Tract Resembles upside-down tree, sometimes called tracheobronchial tree From vocal cords, air enters trachea, or windpipe, 4½ long tube lined with ciliated mucous membrane Trachea extends from cricoid cartilage of larynx to sixth thoracic vertebrae
The Lower Respiratory Tract C-shaped cartilage found in anterior portion of trachea provide rigidity and protection for exposed airway in neck Esophagus lies in area where C opens up posteriorly; room for esophagus to expand when you swallow larger chunks of food
Figure 13-9 The tracheobronchial tree.
The Lower Respiratory Tract Trachea largest pipe; can be thought of as trunk of tree Trachea begins branching (bifurcating) at center of chest into left and right mainstem bronchi (bronchus is singular form) Mainstem bronchi (primary bronchi)
The Lower Respiratory Tract Site of bifurcation is called carina Next bronchi must branch into five lobular bronchi; correspond to five lobes of lungs
The Lower Respiratory Tract Each lung lobe further divided into specific segments; next branching of bronchi called segmental bronchi At point from trachea down to segmental bronchi, tissue layers of bronchi are all the same, only smaller, as they branch downward
The Lower Respiratory Tract Epithelial layer contains mucociliary escalator Middle is lamina propria layer which contains smooth muscle, lymph, and nerve tracts Third layer is protective and supportive cartilaginous layer
Figure 13-10 Tissue layers in the bronchi.
The Lower Respiratory Tract Branching becomes more numerous with tiny subsegmental bronchi that branch deep within each lung segment Cartilaginous rings become more irregular and eventually fade away As we move towards gas exchange regions airways simplify to make it easier for gas molecules to pass through
The Lower Respiratory Tract Bronchioles average 1 mm in diameter No cartilage layer; epithelial lining becomes ciliated cuboidal cells (short squat cells as opposed to large columns) Cilia, goblet cells, and submucosal glands are almost all gone There is no gas exchange yet
The Lower Respiratory Tract Terminal bronchioles have average diameter of 0.5 mm, no goblet cells, cartilage, cilia, or submucosal glands at this point Terminal bronchioles mark border between conducting and respiratory zones
The Lower Respiratory Tract Next airways beyond terminal bronchioles are respiratory bronchioles, because some gas exchange occurs here
The Lower Respiratory Tract Epithelial lining is simple cuboidal epithelium interspersed with alveolitype cells called simple squamous pneumocytes
The Lower Respiratory Tract Alveolar ducts originate from respiratory bronchioles, wherein walls of alveolar ducts are made up of simple squamous cells arranged in tubular configuration These give way to alveoli
Figure 13-11 Conduction and gas exchange structures and functions.
The Lower Respiratory Tract Alveoli are terminal air sacs, surrounded by numerous pulmonary capillaries Together capillaries and alveoli make up functional unit of lung known as alveolar capillary membrane Adults have 300 600 million alveoli, with total of 80 square meters (m 2 ) surface area for oxygen molecule to diffuse across into capillaries
The Lower Respiratory Tract Blood from right heart entering pulmonary capillaries is high in carbon dioxide and low in oxygen Conversely, carbon dioxide is high concentration in blood in pulmonary capillaries and very low in lung
The Lower Respiratory Tract Gas exchange takes place and pulmonary capillary increases in oxygen concentration before traveling to left heart to be pumped around to tissues
Components of Alveolar Capillary Membrane Four distinct components of alveolar capillary membrane First layer is liquid surfactant layer that lines alveoli; this phospholipid helps lower surface tension in alveoli that would otherwise collapse
Components of Alveolar Capillary Membrane Second component is tissue layer, or alveolar epithelium, comprised of simple squamous cells: Majority (95%) of alveolar surface is flat, pancakelike cells called squamous pneumocytes (Type I cells); gas molecules easily pass through in gas exchange
Components of Alveolar Capillary Membrane Second component is tissue layer, or alveolar epithelium, comprised of simple squamous cells: Type II cells, or plump, granular pneumocytes, produce surfactant and aid in cellular repair
Components of Alveolar Capillary Membrane Second component is tissue layer, or alveolar epithelium, comprised of simple squamous cells: Type III cells, or wandering macrophages, ingest foreign particles as they wander through alveoli Pores of Kohn are small holes between alveoli to allow movement of macrophages between alveoli
Components of Alveolar Capillary Membrane Third component of alveolar capillary membrane is interstitial space Area separates basement membrane of alveolar epithelium from basement membrane of capillary endothelium and contains interstitial fluid
Components of Alveolar Capillary Membrane Third component of alveolar capillary membrane is interstitial space Space so small that membranes of alveoli and capillary appear fused If too much fluid gets into space (interstitial edema), it separates, making it harder for gas exchange to occur
Components of Alveolar Capillary Membrane Fourth component is capillary endothelium (simple squamous epithelium) that contains capillary blood and RBCs
Pulmonary Function Testing Measures lung function in terms of volumes and flows Measuring lung volumes Patient is instructed to First, breathe normally Then, take maximum deep breath followed by maximum exhalation Various volumes recorded
Figure 13-12 Normal lung volumes and capacities.
Pulmonary Function Testing Lung volumes Tidal volume (VT): amount of air that moves into or out of lungs in normal breath; normal volume is about 500mL (varies by age, sex, height, and general fitness)
Pulmonary Function Testing Lung volumes Functional residual capacity (FRC): volume of air remaining in lungs at end of a normal expiration Inspiratory reserve volume (IRV): amount of air that can be forcefully inhaled after normal inspiration
Pulmonary Function Testing Lung volumes Expiratory reserve volume (ERV): amount of air that can be forcefully exhaled after normal expiration Residual volume (RV): volume of air remaining in lungs after maximum expiration
Pulmonary Function Testing Lung volumes Vital capacity (VC): maximum amount of air that can be move into and out of respiratory system in single respiratory cycle
Pulmonary Function Testing Flow rates Measure flow rates coming out of lung at various points during forced (maximum patient effort) vital capacity (FVC)
Pulmonary Function Testing Flow rates FEV 1 : forced expiratory volume in 1 second Normal person can exhale 75 85% of their FVC in 1 second Someone with obstructive lung disease takes longer to exhale; can exhale less than 70% of their FVC in 1 second
Pulmonary Function Testing PEFR: peak expiratory flow rate Maximum flow rate or speed of air person can rapidly expel after taking deepest possible breath Measured in liters per minute; should fall within predicted range Good test to reflect how larger airways functioning; monitor diseases such as asthma
Pathology Connection: Atelectasis The Lower Airways Condition in which air sacs of lungs either partially or totally collapsed Cause may be patient who cannot or will not take deep breaths to fully expand lungs, keep passageways open, stimulate production of surfactant
Pathology Connection: Atelectasis The Lower Airways Surgery, pain, injury of thoracic cage often makes deep breathing painful Patients who cannot cough up secretions also at risk for atelectasis Buildup of secretions can lead to pneumonia within 72 hours
Pathology Connection: Pneumonia The Lower Airways Lung infection caused by virus, fungus, bacterium, aspiration, or chemical inhalation Results in inflammation of infected area with accumulation of cell debris and fluid
Pathology Connection: Pneumonia The Lower Airways Some pneumonias actually destroy lung tissue Severe pneumonia can result in death
Figure 13-13 General locations for pneumonias.
Pathology Connection: The Lower Airways Tuberculosis (TB) Infectious disease that thrives in high oxygen areas such as lung Tubercles (lesions) form in lungs Bacteria can lay dormant for years
Pathology Connection: The Lower Airways Tuberculosis (TB) Unchecked, vast lung damage can occur Treated with medication; recent concern about form of tuberculosis very resistant to drugs normally used to treat TB; high mortality rate
Pathology Connection: The Lower Airways Chronic obstructive pulmonary disease (COPD) General term for conditions associated with Cough Sputum production Dyspnea Airflow obstruction Impaired gas exchange
Pathology Connection: The Lower Airways Chronic obstructive pulmonary disease (COPD) Fourth leading cause of death in the United States Group of diseases in which patients have difficulty getting all the air out of lungs; often have large amounts of secretions and lung damage Combination of emphysema and chronic bronchitis
Asthma Pathology Connection: The Lower Airways Chronic inflammatory illness of airways; 25 million people in the United States Most common chronic disease of childhood and younger adults; 80% of cases developing before age 45
Asthma Pathology Connection: The Lower Airways Potentially life-threatening lung condition Airways of lungs constrict (bronchospasm) often in reaction to allergy
Asthma Pathology Connection: The Lower Airways Difficult to get air in; even more difficult to get air out of lungs Gas trapping: inability to get air out of lungs Lowers amount of oxygen in blood and increases blood levels of carbon dioxide
Asthma Pathology Connection: The Lower Airways Controlled with use of medication Symptoms: episodic wheezing, shortness of breath, cough, and chest tightness
Asthma Pathology Connection: The Lower Airways Common triggers: allergens, inhalants, viruses, cold air, and exercise Chronic disease
Figure 13-14 Asthma and emphysema.
Table 13-3 Asthma and COPD Diseases
Table 13-4 Triggers for Asthmatic Attacks
Pathology Connection: Emphysema The Lower Airways Anatomically as the permanent, abnormal enlargement of distal airway spaces and destruction of alveolar walls Nonreversible lung condition; alveolar air sacs destroyed and lung itself becomes floppy
Pathology Connection: Emphysema The Lower Airways Becomes more difficult for gases to diffuse between lungs and blood Lung tissue becomes fragile; easily rupture
Pathology Connection: Emphysema The Lower Airways Two million persons in the United States; majority of cases caused by smoking 60,000 to 100,000 have a genetic deficiency of alpha1-antitrypsin (α1-at)
Table 13-5 Diagnostic Markers to Differentiate COPD and Asthma
Pathology Connection: The Lower Airways Chronic bronchitis Productive cough, enlargement of mucous glands, hypertrophy of airway smooth muscle Acute bronchitis: temporary and common lung condition; can affect people of any age Differs from chronic bronchitis; reversible and no permanent structural changes
Pathology Connection: The Lower Airways Chronic bronchitis Nine million persons in the United States; cigarette smoking major causative factor Increase in size and number of mucussecreting glands Narrowing and inflammation of small airways
Pathology Connection: The Lower Airways Chronic bronchitis Obstruction of airways caused by narrowing and mucus hypersecretion Bacterial colonization of airways
Pathology Connection: The Lower Airways Chronic bronchitis Acute episodes brought on by respiratory tract infection May undergo repeated episodes of respiratory failure; frequently develop right-sided heart failure
Pathology Connection: The Lower Airways Smoking major preventable cause of many respiratory diseases Primary etiology of COPD Smokers have more lung-function abnormalities Smokers show more respiratory symptoms Smokers experience all forms of COPD at much higher rate than nonsmokers
Pathology Connection: The Lower Airways Smoking major preventable cause of many respiratory diseases Age of starting, total pack-years, puff volume, current smoking status predictive of COPD mortality Passive smoking seems to increase risk Children of parents who smoke higher prevalence of respiratory symptoms and ear infections than children of nonsmokers
Pathology Connection: The Lower Airways Smoking major preventable cause of many respiratory diseases (cont'd) Air pollution, occupational exposure, asthma, and nonspecific airway hyperresponsiveness play role in development of COPD
Housing of the Lungs and Related Structures Lungs reside in thoracic cavity and are separated by region called mediastinum, which contains esophagus, heart, great vessels, and trachea Breathing in and out causes lungs to move within thoracic cavity
Housing of the Lungs and Related Structures To prevent irritation of lungs moving against thorax, each lung wrapped in sac or serous membrane called visceral pleura
Figure 13-15 Structures of the thoracic cavity.
Housing of the Lungs and Related Structures Thoracic cavity and upper side of diaphragm lined with continuation of membrane called parietal pleura Between these two pleural layers is pleural space (intrapleural space), which contains slippery liquid called pleural fluid that reduces friction as individual breathes
Pathology Connection: Pleural Space Problems Pneumothorax Air inside thoracic cavity but outside lungs Air can enter thoracic cavity from two directions Stab wound or gunshot wound to chest would allow air to rush into thoracic cavity from outside Lung might develop leak as result of structural deformity or disease process
Pathology Connection: Pleural Space Problems Pneumothorax If air cannot escape, it fills space meant for lungs and prevents lung expansion required for breathing Can be life-threatening situation
Pathology Connection: Pleural Space Problems Pleural effusion Buildup of fluid in pleural space between parietal and visceral pleura Fluid may be pus (empyema), serum from blood (hydrothorax), or blood (hemothorax) Fluids affected by gravity; pleural effusions tend to move to lowest point in pleural space
Pathology Connection: Pleural Space Problems Pleural effusion If effusion large enough, it can have same effect as a large pneumothorax, restricting lung expansion Pleural effusions can be treated by inserting chest tube inserted into pleura space to allow drainage of fluid
Figure 13-16 Pneumothorax (sucking chest wound) and technique for performing thoracocentesis.
The Lungs Lungs Conical-shaped with rounded peaks (apex) extending 1 to 2 inches above clavicle Base of lungs rest on right and left hemidiaphragm with right lung base a bit higher to accommodate liver
The Lungs Lungs Medial surface of lung has deep, concave cavity that holds heart, called cardiac impression, and is deeper on left side
The Lungs Lungs Hilum is area where root of each lung is attached, containing mainstem bronchus, pulmonary artery and vein, nerve tracts, and lymph vessels
The Lungs Lungs Right lung has three lobes: upper, middle, lower lobes; divided by horizontal and oblique fissures Left lung has one fissure, oblique fissure, and therefore has only two lobes: upper and lower lobes Lingula is area of left lung that corresponds with right middle lobe
The Lungs Lungs Left lung has only two lobes because largest part of heart is located in left lung area Right lung is larger, with 60% of gas exchange occurring here
The Protective Bony Thorax Bony thorax Bony and cartilaginous frame providing freedom of movement Protects organs of chest Includes rib cage, sternum, and thoracic vertebrae to which each rib attaches Sternum, or breastbone, is centrally located; comprised of manubrium, body, and xiphoid process (important landmark for CPR)
The Protective Bony Thorax Bony thorax 12 pairs of ribs (thoracic cage) True ribs (pairs 1 7): called vertebrosternal; connect to sternum and vertebrae Pairs 8 10: called false ribs or vertebrocostal; connect to costal cartilage of superior rib and to thoracic vertebrae
The Protective Bony Thorax Bony thorax 12 pairs of ribs Ribs pairs 11 and 12: floating ribs, with no anterior attachment; only attach to vertebral column
Figure 13-17 The thoracic cage.
How We Breathe Respiratory control center is in medulla oblongata Inspiration: active process in which diaphragm is sent signal via phrenic nerve, causing it to contract and flatten downward, increasing thoracic cavity space
How We Breathe Increase in thoracic cavity volume decreases pressure, creating lower pressure in lungs than outside, allowing air to rush into lungs
Figure 13-18 How we breathe.
How We Breathe Ease of ventilation is called compliance High compliance: little effort required to expand lungs Low compliance: more difficult to expand lungs Emphysema can affect lung compliance Bronchioles become damaged and wider, allowing air into lungs, increasing compliance but making it much more difficult to breathe out
How We Breathe Exhalation: passive act; diaphragm relaxes, which decreases amount of space in thoracic cavity; pressure in lungs becomes greater than atmospheric pressure; air is pushed out of lungs While we can consciously influence breathing rate, our breathing rate is normally controlled by level of carbon dioxide in blood
How We Breathe If carbon dioxide levels rise, it means that not enough CO 2 is being ventilated When this occurs, chemoreceptors in medulla oblongata send signals to respiratory muscles to increase rate and depth of breathing
How We Breathe Other factors can change breathing rate Changes as we grow and mature into adults When we sleep, breathing rate slows down Rate increases with exercise or feel strong emotions Yawning
How We Breathe Accessory muscles include: Scalene muscles in neck Sternocleidomastoid Pectoralis major Pectoralis minor
How We Breathe While exhalation is usually passive, there are times when exhalation may need to be assisted, such as during certain diseases Accessory muscles of exhalation assist in more forceful and active exhalation by increasing abdominal pressure
How We Breathe Main accessory muscles of exhalation are abdominal muscles that push up diaphragm or the back muscles that pull down and compress thoracic cage
Figure 13-19 The accessory muscles of exhalation.
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Common Diseases of the Lung cancer Respiratory System Etiology: cause not known but linked to smoking and inhalation of carcinogenics Signs and symptoms: obstruction of airways interfering with ventilation, weight loss, weakness, cough, or change in cough
Common Diseases of the Lung cancer Respiratory System Diagnostic tests: bronchoscopy, imaging studies, biopsy, sputum, patient exam and history Treatments: radiation, chemotherapy, and surgery
Common Diseases of the Asbestosis Respiratory System Etiology: prolonged exposure to airborne asbestos particles Sign and symptoms: dyspnea, chest pain, productive cough in smokers, and decreased lung inflation
Common Diseases of the Asbestosis Respiratory System Diagnostic tests: chest x-rays fine irregular linear infiltrates; honeycomb appearance on x-ray; decreased pulmonary function tests and hypoxemia Treatments: No cure; goal is to relieve symptoms and treat any complications such as infections
Common Diseases of the Respiratory System Acute bronchitis Etiology: viral or bacterial Signs and symptoms: inflamed mucous membranes of trachea and bronchi; expectorating or dry cough, shortness of breath, fever, rales (raspy sound) Diagnostic tests: physical exam Treatment: antibiotics if bacterial
Common Diseases of the Common cold Respiratory System Etiology: viral Signs and symptoms: upper airway congestion, cough, and sore throat Diagnostic tests: history and physical exam Treatments: treat symptoms, pain meds, bed rest, drink fluids, and proper nutrition
Common Diseases of the Pharyngitis Respiratory System Etiology: viral or bacterial Signs and symptoms: red, sore swollen throat, and pus Diagnostic tests: history and physical exam, throat culture Treatments: if bacterial use antibiotics, antiseptic gargle
Common Diseases of the Laryingitis Respiratory System Etiology: viral or bacterial, allergies, and over-use of voice Signs and symptoms: dysphonia, sore throat, and trouble swallowing Diagnostic tests: history and physical exam Treatments: rest voice
Common Diseases of the Tonsillitis Respiratory System Etiology: viral or bacterial Signs and symptoms: sore throat, swollen tonsils and dysphagia Diagnostic tests: history and physical exam, culture Treatments: antibiotics for bacterial, and surgery if needed
Common Diseases of the Influenza Respiratory System Etiology: viral Signs and symptoms: fever, cough, body aches and headaches Diagnostic tests: history and physical exam Treatments: rest, fluids, pain meds, and treat symptoms
Common Diseases of the Pneumonia Respiratory System Etiology: viral, bacteria, or fungal Signs and symptoms: productive cough, chest pain, weakness, malaise, and dyspnea
Common Diseases of the Pneumonia Respiratory System Diagnostic tests: imaging, blood work, and sputum culture Treatments: antibiotics if confirmed bacterial infection; antifungal drugs if confirmed fungal infection
Common Diseases of the Respiratory System Pulmonary tuberculosis Etiology: bacterial Signs and symptoms: primary, may be asymptomatic; secondary, cough (may be blood tinged), fever (night sweats), weight loss Diagnostic tests: imaging, TB skin test, and sputum test Treatments: antibiotic agents
Common Diseases of the Respiratory System Seasonal allergic rhinitis (hay fever) Etiology: allergic agents Signs and symptoms: upper airway congestion, watery nose and eyes, sneezing Diagnostic tests: history and physical exam, allergy testing Treatments: antihistamines, and preventative allergy shots
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Common Diseases of the Asthma Respiratory System Etiology: many triggers such as allergens, food, exercise, cold air, inhaled irritants, smoking Signs and symptoms: dyspnea, wheezing, productive cough, and hypoxia
Common Diseases of the Asthma Respiratory System Diagnostic tests: history and physical exam, lung function tests Treatments: bronchodilators, steroids, anti-asthmatic agents; oxygen if needed
Common Diseases of the Respiratory System COPD chronic bronchitis Etiology: cigarette smoking and longterm exposure to air pollutants; middle or old age Signs and symptoms: dyspnea, wheezing, productive cough, and hypoxia
Common Diseases of the Respiratory System COPD chronic bronchitis Diagnostic tests: history and physical exam, lung function tests Treatments: antibiotics if bacterial, bronchodilators, and oxygen if needed
Common Diseases of the Respiratory System COPD emphysema Etiology: cause not fully known but associated with smoking and one genetic form from alpha 1-antitrypsin deficiency Signs and symptoms: dyspnea, tachypnea, wheezing, productive cough, and hypoxia
Common Diseases of the Respiratory System COPD emphysema Diagnostic tests: history and physical exam, lung function tests Treatments: oxygen therapy, bronchodilators, and alpha 1-antitrypsin replacement
Common Diseases of the Respiratory System Acute respiratory distress syndrome (ARDS) Etiology: form of pulmonary edema; high mortality rate and very noncompliant (stiff) lungs; many causes; most often caused by shock, sepsis, and trauma
Common Diseases of the Respiratory System Acute respiratory distress syndrome (ARDS) Signs and symptoms: rapid shallow breathing with dyspnea; hypoxemia and fluid accumulation in lungs; rhonchi and crackles
Common Diseases of the Respiratory System Acute respiratory distress syndrome (ARDS) Diagnostic tests: arterial blood gases showing respiratory acidosis and severe hypoxemia, bilateral infiltrates on x-rays with white outs in lung fields Treatment: intubation and mechanical ventilation; sedatives and diuretics and in some cases high doses of corticosteroids
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Common Diseases of the Cystic fibrosis Respiratory System Etiology: hereditary disease transmitted via recessive gene Signs and symptoms: excessive thick mucus secretion, repeated infections, large salt losses, and difficult digestion
Common Diseases of the Cystic fibrosis Respiratory System Diagnostic tests: sweat test, and genetic testing Treatments: respiratory hygiene therapy, mucus thinning agents, antibiotics, and pancreatic enzyme supplements
Pharmacology Corner Oxygen Can be administered as medical treatment for respiratory and cardiovascular diseases Benefits of oxygen therapy Reduces work of breathing Increases oxygen content of blood Reduces work of heart
Pharmacology Corner Drugs for airway narrowing Aerosolized bronchodilators: rapid relief of acute situation of airway narrowing Inhaled steroids: long-term treatment of chronic airway inflammation; less systemic effects than oral or injectable steroids
Pharmacology Corner Smoking cessation Only method known to prevent or slow progression of COPD is stop smoking or eliminate occupational source Tobacco dependence is powerful addiction Most smokers require four to six attempts before successfully quitting Even after quitting, some patients have lifelong cigarette craving
Pharmacology Corner Many patients require require behavioral counseling and encouragement in addition to pharmacological therapy to quit Nicotine replacement therapy Forms of nicotine replacement include gum, skin patches, or inhaled forms Drugs can be given to decrease desire such as Chantix or Wellbutrin
Pharmacology Corner Surfactant Administered to premature infants whose lungs are underdeveloped and cannot produce their own surfactant Instilled into lungs Buys time for infant's lungs to complete development
Pharmacology Corner Systemic antibiotics: used for bacterial lung infections Inhaled insulin: can be used to treat diabetes Antiviral medications: reduce length and severity of viral infection (cold or flu)
Figure 13-20 Classes of drugs used to treat respiratory disorders.
Snapshots from the Journey Moving approximately 12,000 quarts of air each day, respiratory system is responsible for oxygenating blood; carries oxygen to tissue and removes carbon dioxide, waste product of cell metabolism Ventilation is movement of gas into alveoli, respiration is gas exchange that takes place in alveoli
Snapshots from the Journey Lungs contain ever-branching airways called bronchi and bronchioles At end of each bronchiole are alveolar sacs Each alveolar sac is surrounded by capillaries where gas exchange occurs
Snapshots from the Journey Purpose of upper airways is to filter, warm, and humidify air Olfaction (sense of smell) and phonation (speech) also occurs in upper airways
Snapshots from the Journey Mucociliary escalator captures foreign particles and hairlike cilia constantly move layer of mucus up to upper airway to be swallowed or expelled Adenoids and tonsils aid in preventing pathogens from entering body Epiglottis protects airway to lungs from accidental aspiration of food and liquids
Snapshots from the Journey Vocal cords are gateway between upper and lower airway Tracheobronchial tree is like upsidedown tree with ever-branching airways where trunk of tree is trachea and leaves are alveoli Alveolar capillary membrane is where external respiration, or gas exchange, occurs
Snapshots from the Journey Bony thorax provides support and protection for the respiratory system Main muscle of breathing is diaphragm, while accessory muscles assist in times of need such as exercise or disease Medulla oblongata is control center for breathing and sends impulses via the phrenic nerve to the diaphragm