Chapter 22- The respiratory system

Question 1

Gas exchange

Answer 1

Body tissues must be supplied with oxygen, carbon dioxide waste must be disposed of. Gasses only move in one direction during gas exchange (might not be in the same direction for every gas)

Question 2

4 processes involved with gas exchange

Answer 2

1. Pulmonary ventilation
2. External respiration
3. Transport of respiratory gasses to/from tissues- does not occur in the respiratory system
4. Internal respiration- does not occur in the respiratory system

Question 3

External respiration

Answer 3

Gas exchange occurring in the lungs (alveoli)

Question 4

Internal respiration

Answer 4

Gas exchange occurring in the tissues (does not occur in the respiratory system). If PCO2 in tissues is greater than PCO2 in blood- carbon dioxide leaves tissues and enters blood. If PO2 in blood is greater than PO2 in tissues- oxygen leaves blood and enters tissue. Partial pressure and diffusion gradients are opposite to external respiration

Question 5

2 zones of the respiratory system

Answer 5

1. Conducting zone

2. Respiratory zone

Question 6

Conducting zone

Answer 6

Respiratory passages leading from the nose to the respiratory bronchioles. Transports air to/from the lungs- no gas exchange, just movement of air

Question 7

Respiratory zone

Answer 7

Actual site of gas exchange. Found in respiratory bronchioles, alveolar ducts, and alveoli

Question 8

Upper conducting zone (2 parts)

Answer 8

1. Nasal cavity

2. Pharynx

Question 9

Nasal cavity function

Answer 9

Air is warmed and humidified as it passes through this cavity. Inhaling cool/dry air slows down respiration overall- warming and humidifying ensures a normal respiratory rate

Question 10

Mucous membranes of the nasal cavity

Answer 10

Consists of the respiratory mucosa- contains 2 different types of cells. Nerve endings in membrane- invading debris triggers a sneezing reflex

Question 11

2 cell types of the respiratory mucosa

Answer 11

1. Goblet cells

2. Seromucous nasal glands

Question 12

Goblet cells

Answer 12

Mucus producing cells. We usually only notice mucus during a cold

Question 13

Seromucous nasal glands

Answer 13

“Mucus” portion traps particles and debris- immune function- clears pathogens. “Serous” portion secretes watery fluid containing lysozyme

Question 14

Vascularization of the mucous membranes of the nasal cavity

Answer 14

Capillaries and veins located superficially to help warm air as it passes through- they sit very close to the surface of the membrane. This is why damage to these vessels can cause severe nosebleeds

Question 15

3 regions of the pharynx

Answer 15

1. Nasopharynx
2. Oropharynx
3. Laryngopharynx

Question 16

Nasopharynx

Answer 16

Contains pharyngeal tonsils and tubal tonsil. Closes during swallowing by soft palate and uvula (dangling thing at back of throat)- stops food/liquid from getting in

Question 17

Oropharynx

Answer 17

Meets oral cavity at the isthmus of the fauces. Contains palatine tonsils and lingual tonsils

Question 18

Laryngopharynx

Answer 18

Where respiratory and digestive passages split. The lower conducting zone divides the laryngopharynx from the respiratory passages

Question 19

Parts of the lower conducting zone (4)

Answer 19

1. Epiglottis
2. Larynx
3. Trachea
4. Bronchi

Question 20

Epiglottis

Answer 20

Cartilage flap that closes off lower conducting zone. Function- separates food and air passageways

Question 21

Larynx composition

Answer 21

Composed of cartilage- provides an open airway. Consists of thyroid cartilage and cricoid cartilage- XY individuals tend to have an Adam’s apple (testosterone makes thyroid cartilage larger and thicker). The larynx contains vocal cords for sound production

Question 22

Glottis

Answer 22

Open passageway surrounded by vocal cords. Vocal cords are ligaments composed of elastic fibers, the fibers vibrate as we exhale to produce sound

Question 23

Sound pitch vs sound loudness of vocal cords

Answer 23

If chords are tense, they vibrate more quickly- higher pitch. Increased testosterone usually causes the chords to be longer and looser, causing a deeper voice. Loudness increases as air is passed across the cords with greater force. Many sound properties are created by other structures- tongue, lips, etc.

Question 24

Trachea composition

Answer 24

Windpipe. Composed of elastic fibers and cartilage rings. Elastic fibers provide flexibility- trachea can stretch/relax while breathing cartilage rings prevent the trachea from collapsing. Without the cartilage rings, the trachea and larynx would collapse between breaths. It would take a large amount of work to breathe

Question 25

Trachealis

Answer 25

Smooth muscle tissue of the trachea, innervated. Contraction leads to diameter of the trachea decreasing and air forced upward . Ex- coughing reflexes remove things from the lungs

Question 26

Bronchi

Answer 26

Allow air to reach the respiratory zone. The trachea branches to form 2 main bronchi, bronchi branch 20-25 times to eventually form bronchioles. Smallest of the bronchioles in the conducting zone are terminal bronchioles.

Question 27

Lungs

Answer 27

Organ where external gas exchange occurs. Lungs composed of air space and elastic connective tissue. Lungs are elastic in nature- ensures that the lungs don’t become permanently stretched out with breathing- you would need more and more air to fill them

Question 28

Hilum

Answer 28

Each lung has a hilum- point at which the bronchi and any blood/nerve supply enter/leave the lung

Question 29

Blood supply to lungs

Answer 29

Pulmonary artery brings oxygen poor blood to lungs- artery branches in a similar pattern as bronchi. The pulmonary vein moves oxygenated blood away from the lungs. The pulmonary capillary network immediately surrounds alveoli- where external gas exchange takes place

Question 30

Pulmonary plexus

Answer 30

Where nerve fibers enter the lungs

Question 31

Innervation of the lungs

Answer 31

Lungs have both parasympathetic and sympathetic fibers. Parasympathetic causes the air tubes to constrict- if resting, you don’t need to bring in a huge amount of air. Sympathetic causes the air tubes to dilate- using your skeletal muscle tissue more, use more oxygen

Question 32

Pleurae function

Answer 32

Thin, double layered serous membrane (visceral and parietal layers). Produces pleural fluid, which fills cavity between visceral and parietal layers. Also creates chambers for each lung.

Question 33

Parietal pleura

Answer 33

Covers the thoracic wall and the upper portion of the diaphragm

Question 34

Visceral pleura

Answer 34

Covers external lung features

Question 35

Importance of pleural fluid

Answer 35

Pleural fluid fills the cavity between visceral and parietal layers. Importance- lungs can “slide” over structures as they change in size. There is a very small amount of fluid between the layers- difficult to get the layers apart. Visceral and parietal pleura are “stuck” together.

Question 36

What are the benefits of having a chamber for each lung? (2)

Answer 36

1. As organs move/shift with breathing, etc.- organs cannot interfere with others
2. Prevents spread of infection from one organ to another- prevents spread to another lung or heart

Question 37

Branching pattern of respiratory bronchioles

Answer 37

Branch from the terminal bronchioles of the conducting zone, lead into alveolar sacs composed of multiple individual alveoli.

Question 38

Alveoli

Answer 38

Multiple alveoli are grouped into each alveolar sac. Alveoli are covered with capillary beds. Gas exchange occurs via diffusion- the walls of the alveoli are made of simple squamous epithelium, and are very thin to facilitate gas exchange. Individual alveoli connected to “neighbors” via alveolar pores- ensures that all alveoli in the sac are able to fill with air

Question 39

3 cell types of alveoli

Answer 39

1. Type 1 alveolar cells
2. Type 2 alveolar cells
3. Alveolar macrophage

Question 40

Type 1 alveolar cells

Answer 40

Squamous epithelial cells. Function- creates walls of alveoli- where gas exchange and diffusion occurs

Question 41

Type 2 alveolar cells functions (2)

Answer 41

Cuboidal cells scattered among type 1 cells, less common. Functions:

1. Secrete surfactant, a detergent like substance. Surfactant prevents alveoli from collapsing as air leaves during exhalation
2. Secrete antimicrobial proteins- innate immunity

Question 42

Alveolar macrophage

Answer 42

Mobile cells, travel through the lung tissue. Function- consume debris, pathogens, etc.- protect internal alveolar surfaces

Question 43

2 processes involved with respiratory physiology

Answer 43

1. Pulmonary ventilation

2. Gas exchange

Question 44

Pulmonary ventilation

Answer 44

The flow of air into and out of the lungs. Air flows according to a pressure gradient, from high pressure to low pressure

Question 45

Gas exchange

Answer 45

The exchange of respiratory gasses across the alveolar wall. Respiratory gasses can move from air space in lungs to blood, or from blood to air space in lungs. The same gas will always move in the same direction.

Question 46

3 gas laws influence the process of gas exchange and pulmonary ventilation

Answer 46

1. Boyle’s law
2. Dalton’s law of partial pressures
3. Henry’s law

Question 47

Boyle’s law

Answer 47

The volume of a gas is inversely proportional to the pressure exerted by the gas on the walls of its container. A gas always fills a container- as gas molecules move around and bump into each other, they create pressure. More moving around= more pressure. If you change the volume of a container filled with gas, the pressure within the container will change

Question 48

How is Boyle’s law important for pulmonary ventilation?

Answer 48

Inhalation and exhalation changes the volume of the lungs. Changing the volume of lungs changes the pressure of air in the lungs- air moves according to pressure gradient

Question 49

Pressure in the lungs always described relative to

Answer 49

Atmospheric pressure. At sea level, atmospheric pressure (Patm)= 760 mm Hg

Question 50

Intrapulmonary pressure (Ppul)

Answer 50

Pressure in the alveoli. Changes as you inhale or exhale, but always equalizes Patm at some point

Question 51

Which 2 muscles initiate inspiration?

Answer 51

1. Diaphragm

2. Intercostal muscles

Question 52

Diaphragm function during inspiration

Answer 52

During contraction, diaphragm flattens and is pulled down- thoracic cavity increases in size. Gives the lungs room to increase in size

Question 53

Intercostal muscles function during inspiration

Answer 53

During contraction, intercostal muscles pulls ribs outward- thoracic cavity increases in size

Question 54

How does air pressure in the lungs change during inspiration?

Answer 54

As thorax increases in size during inhalation, lungs are naturally pulled outward. Volume of the lungs increases- intrapulmonary pressure decreases, and Ppul is less than Patm. Then, air flows into lungs along the pressure gradient (high to low pressure). Inspiration ends when Ppul = Patm

Question 55

Damage to pleura can cause

Answer 55

A collapsed lung

Question 56

How does expiration occur?

Answer 56

Expiration mostly due to lung elasticity. Respiratory muscles relax, return to resting length. Elastic fibers of the lungs recoil- lungs become smaller in size

Question 57

How does pressure in the lungs change during expiration?

Answer 57

Lungs recoil, pull thorax walls with them- thoracic and intrapulmonary volume decrease. Decrease in intrapulmonary volume= increase in pressure in the lungs, and Ppul is greater than Patm. Air flows out of lungs along the pressure gradient. Expiration ends when Ppul= Patm

Question 58

Respiratory volumes

Answer 58

The amount of air that can be pushed into/out of lungs during ventilation

Question 59

Types of respiratory volumes (4)

Answer 59

1. Tidal volume (TV)
2. Inspiratory reserve volume (IRV)
3. Expiratory reserve volume (ERV)
4. Residual volume (RV)

Question 60

Tidal volume (TV)

Answer 60

Normal volume of air that moves into and out of lungs during normal breathing at rest. Restrictive respiratory diseases prevent the lungs from filling as they should. Causes by lack of elasticity in the lungs or by problems with the respiratory muscles

Question 61

TV normal value

Answer 61

In healthy individuals- 500 ml air

Question 62

Inspiratory reserve volume (IRV) and normal value

Answer 62

Amount of air that can be inspired forcibly past the tidal volume. 2100-3000 ml air

Question 63

Expiratory reserve volume (ERV)- normal value

Answer 63

Amount of air that can be forced from lungs after a normal tidal volume expiration. 1000-1200 ml air

Question 64

Residual volume (RV)- normal value

Answer 64

Amount of air left in the lungs after forced expiration, 1200 ml air. The lungs are never completely empty of air- ensures that they stay inflated

Question 65

Respiratory capacities

Answer 65

The sum of two or more respiratory volumes. Give an idea about the health of the lungs, whether a person is sufficiently ventilating

Question 66

Inspiratory capacity (IC)

Answer 66

Total amount of air that can be inspired after a normal tidal volume expiration. Restrictive lung diseases decrease inspiratory capacity-can’t get enough air into the lungs

Question 67

IC equation

Answer 67

IC= TV + IRV

Question 68

Functional residual capacity (FRC)

Answer 68

Amount of air remaining in the lungs after a normal tidal volume expiration. High FRC indicates a person can’t remove enough air from the lungs- can cause buildup of carbon dioxide. Can also be caused by loss of elasticity in the lung, not recoiling like they should means that air can’t get out

Question 69

FRC equation

Answer 69

FRC= RV + ERV

Question 70

Vital capacity (VC)

Answer 70

Total amount of exchangeable air, RV is not involved here. Increase in vital capacity means a person has more exchangeable air- is exchanging more oxygen and carbon dioxide.

Question 71

VC equation

Answer 71

VC= TV + IRV + ERV

Question 72

Total lung capacity (TLC)

Answer 72

The total amount of air the lungs can hold after a maximum inhalation. More based on lung size overall than health. The lungs can only get so big and the thoracic cavity can only expand so much- smaller people will generally have a smaller lung capacity

Question 73

TLC equation

Answer 73

TLC= IRV + TV + ERV + RV

Question 74

Dead space

Answer 74

The air that fills the conducting zone, but never contributes to gas exchange- larger conducting zone structures never contribute to gas exchange

Question 75

Anatomical dead space value

Answer 75

150 ml air for a healthy individual- 1 ml of air per pound of ideal body weight. Remember- TV is 500 ml, air used for gas exchange: 500 ml - 150 ml= 350 ml

Question 76

Alveolar dead space

Answer 76

Air reaches the alveoli, but no gas exchange occurs- don’t want to have this dead space. This is due to localized damage or collapse of alveoli, can be damaged by certain diseases. Example- blockage from mucus. Also, not being able to produce surfactant makes the alveoli collapse

Question 77

Total dead space

Answer 77

Anatomical dead space and alveolar dead space. These are considered “Non-useful volumes”

Question 78

Dalton’s Law of Partial Pressures

Answer 78

Atmospheric pressure is the sum of the pressures of the different gasses that make up air that we breathe. The pressure of each individual gas in the mixture is the partial pressure (PP). The PP of one gas is independent of the PP of a different gas in the mixture. Importance- if we know partial pressures of each gas, we can see pressure gradients that drive diffusion into and out of the blood

Question 79

Which gasses contribute to atmospheric pressure?

Answer 79

Nitrogen (79%) and oxygen (20.9%) account for about 99% of atmospheric pressure. Small amounts of carbon dioxide, water vapor, and other gasses make up remaining

Question 80

Henry’s law

Answer 80

A gas will dissolve in a liquid in proportion to its partial pressure. Higher PP= more gas dissolves in liquid. Gasses dissolve in liquid best under high pressure, low temperature, and high solubility. Ex- carbonated beverages

Question 81

Factors affecting rate at which gas exchange occurs between alveoli and capillaries (3)

Answer 81

1. Partial pressure gradients and gas solubility
2. Thickness and surface area of respiratory membrane
3. Ventilation-perfusion coupling

Question 82

How do partial pressure gradients and gas solubility affect rate of gas exchange?

Answer 82

PO2 in alveoli is greater than PO2 in capillaries- oxygen moves into alveoli and into the blood, while carbon dioxide moves in the opposite direction. Carbon dioxide diffuses at a slower rate than oxygen, but equal amounts are exchanged. This is because carbon dioxide is a more soluble gas than oxygen. Consider size of molecules in solubility- carbon dioxide is larger in size than oxygen, and therefore moves more slowly

Question 83

How does thickness and surface area of respiratory membrane affect the rate of gas exchange?

Answer 83

The respiratory membrane is exceptionally thin- gas exchange occurs quickly. The greater the surface area, the greater amount of gas that can diffuse in a given amount of time. Surface area of the lungs is large, but alveolar surface area is huge. Ex- in a healthy male, alveolar surface area is 40-50X greater than the surface area of his skin

Question 84

Ventilation-perfusion coupling

Answer 84

Optimal gas exchange results from equal amounts of gas reaching alveoli (via ventilation) and blood supply to pulmonary capillaries (via perfusion)

Question 85

Perfusion

Answer 85

Flow of fluid through blood vessels

Question 86

How does the partial pressure of oxygen influence perfusion (occurring at the lungs)?

Answer 86

If local PO2 is low- local arterioles to those alveoli constrict. Blood is redirected to respiratory areas with high PO2. Importance- ensures adequate oxygen uptake
If local PO2 is high- local arterioles to those alveoli dilate. Area is flooded with blood, takes up oxygen

Question 87

How does the partial pressure of oxygen influence ventilation?

Answer 87

If local PCO2 levels are high, bronchioles dilate. Carbon dioxide is eliminated by the body faster. Importance- increased carbon dioxide affects blood pH and makes it more acidic. If local PCO2 levels are low, bronchioles constrict. If too low, blood becomes basic

Question 88

Composition of alveolar gas

Answer 88

Atmospheric gasses mostly nitrogen and oxygen, but alveolar gasses are mostly carbon dioxide and water vapors

Question 89

Why is the composition of atmospheric gasses and alveolar gasses different? (3)

Answer 89

1. Gas exchange is occurring in alveoli- oxygen diffuses into blood, carbon dioxide diffuses into alveoli
2. Conducting passages humidify air- creates water vapor
3. Mixture of air in alveoli- inspiration brings in new gasses, but there is still gasses left over (reserve volume)

Question 90

How is oxygen transported in the blood?

Answer 90

Oxygen transported primarily by hemoglobin (4 oxygen molecules per hemoglobin molecule)

Question 91

How does hemoglobin work to bind oxygen?

Answer 91

Binding first oxygen molecule facilitates binding of other 3. Doesn’t take a lot of work, so oxygen binding can occur faster- as each oxygen binds, it’s easy for the next one to be added. Unloading first oxygen molecule facilitates unloading of remaining 3. Effect- loading and unloading of oxygen by hemoglobin is fast and efficient

Question 92

What is the oxygen saturation of arterial blood?

Answer 92

Arterial blood is 98% saturated. Typically drops with health issues with the blood or the lungs. We always have a small amount of older and less efficient blood cells that won’t bind oxygen

Question 93

What is the oxygen saturation of venous blood?

Answer 93

Venous blood is 75% saturated. This not 0% so we can have a venous reserve of oxygen- body can use it if needed. If ventilation decreases or you’re not exchanging enough air, you can use the venous reserve if needed

Question 94

3 ways of transporting carbon dioxide

Answer 94

1. Dissolved in plasma
2. Bound to hemoglobin
3. As bicarbonate ions (HCO3) in plasma

Question 95

How does hemoglobin transport carbon dioxide?

Answer 95

Carbon dioxide does not bind heme, it binds amino acids of globulin. Importance- oxygen and carbon dioxide do not compete with one another for a “spot”. Deoxygenated hemoglobin binds carbon dioxide more readily than oxygenated hemoglobin

Question 96

How does carbon dioxide form bicarbonate ions in plasma?

Answer 96

When carbon dioxide diffuses into erythrocyte- combines with water to form carbonic acid (H2CO3). Carbonic acid split to form hydrogen and bicarbonate ions (HCO3). This reaction is reversible- we don’t really do anything with bicarbonate, needs to be converted back to carbon dioxide

Question 97

How can carbon dioxide change blood pH?

Answer 97

Conversion of carbon dioxide to bicarbonate causes release of hydrogen ions, which would decrease blood pH. Normally, this is buffered by red blood cells- maintains 7.35-7.45 pH of blood

Question 98

An increase in carbon dioxide in the blood causes blood pH to

Answer 98

Decrease. Respiratory acidosis, caused by slow, shallow breathing

Question 99

A decrease in carbon dioxide in the blood causes blood pH to

Answer 99

Increase. Respiratory alkalosis, caused by rapid, deep breathing

Question 100

Which areas of the CNS control the respiratory system? (2)

Answer 100

1. Medullary respiratory center- two areas that set the normal respiratory rhythm.
2. Pontine respiratory center (PRC)

Question 101

2 sets of neurons used by the medullary respiratory center?

Answer 101

1. Ventral respiratory group (VRG)

2. Dorsal respiratory group (DRG)

Question 102

Ventral respiratory group (VRG)

Answer 102

Part of medullary respiratory center. Some neurons in this group fire during inspiration, others fire during expiration- one set inhibits the other (they cannot fire at the same time). When the pressure in the lungs balances out, the inspiration neurons stop firing. During inspiration, impulses excite the diaphragm and external intercostals. During expiration, impulses stop and muscles relax

Question 103

Dorsal respiratory group (DRG)

Answer 103

Part of medullary respiratory center, modifies rhythm set by VRG. Smooths out the respiratory pattern, makes sure the transition is smooth between inspiration and expiration. Integrates information from other structures (chemoreceptors, etc), delivers it to VRG

Question 104

Pontine respiratory center (PRC)

Answer 104

Interact with medullary respiratory centers to “smooth” the respiratory pattern. Transition from inspiration to expiration (and vice versa)

Question 105

Which 2 factors does the CNS measure to determine breathing rate and depth?

Answer 105

1. Carbon dioxide is the most potent and most closely controlled
2. PO2 of arterial blood

Question 106

Hypercapnia

Answer 106

An increase in PCO2 levels in blood, causing respiratory acidosis. Depth and rate of breathing increase

Question 107

Hypocapnia

Answer 107

A decrease in PCO2 levels in the blood, causing respiratory alkalosis.

Question 108

How does PO2 affect ventilation?

Answer 108

PO2 must drop substantially to stimulate increased ventilation- therefore, carbon dioxide is most important in this situation. Venous reservoir of saturated hemoglobin (about 75%)- body can use this if PO2 drops slightly. If PO2 drops substantially, respiratory centers are stimulated. Ventilation increases- oxygen levels increase

Question 109

Higher brain centers influencing respiration (2)

Answer 109

1. Hypothalamic control

2. Cortical controls

Question 110

Hypothalamic control

Answer 110

Strong emotion (excited increases RR, anger decreases RR), pain send information from hypothalamus/limbic system to respiratory centers (decreases RR). Ex- excitation stimulates respiratory rate, anger suppresses it, substantial drop in temperature can cause apnea

Question 111

Cortical controls

Answer 111

We can override the respiratory centers to control our own breathing depth/rate. Cerebral motor cortex sends impulses to motor neurons that stimulate respiratory muscles. This only goes so far, since you can’t hold your breath forever. The respiratory centers will automatically initiate respiration due to rising carbon dioxide levels

Question 112

Which activities require alteration of the normal pattern of respiration? (2)

Answer 112

1. Exercise

2. High altitude

Question 113

How does exercise change the pattern of respiration?

Answer 113

Adjustments are made based on intensity and duration of physical exertion. Active muscles need large amounts of oxygen and produce large amounts of carbon dioxide waste. Ventilation and perfusion during exercise are still balanced. Respiration increases at the beginning of exercise, then plateaus. This is most likely due to rate of carbon dioxide delivery to the lungs

Question 114

Hyperpnea

Answer 114

Ventilation increases 10-20 times during exercise

Question 115

Acute mountain sickness

Answer 115

If you move up in elevation fast, acute mountain sickness can occur. Symptoms- headache, shortness of breath, nausea, dizziness. Your body has no time to make an adjustment and you become short on oxygen

Question 116

What adjustments are made during acclimatization? (3)

Answer 116

1. Increased ventilation- decrease carbon dioxide in blood to “match” lower oxygen availability
2. Lower hemoglobin saturation rates- less oxygen to bind hemoglobin. Arterial blood is less oxygen saturated compared to lower elevations, but the body still receives what it needs
3. Kidneys produce more erythropoietin (EPO)- increase in erythrocyte production/number. Long term adaptation to high altitude living

Question 117

How does high altitude change the pattern of respiration?

Answer 117

With increases in elevation, atmospheric pressure and PO2 drop. If you move up in elevation slowly, acclimatization occurs and the body makes respiratory and hematopoietic adjustments

Question 118

Types of COPD (2)

Answer 118

1. Emphysema

2. Chronic bronchitis

Question 119

Chronic obstructive pulmonary disease (COPD)

Answer 119

Group of conditions characterized by a physiological inability to expel air from the lungs- makes normal ventilation difficult. This condition is irreversible. Features/shared characteristics- caused by smoking, labored breathing, coughing, pulmonary infection etc. Coughing can damage the alveoli and cause them to become infected

Question 120

Emphysema

Answer 120

Permanent enlargement of the alveoli and eventual destruction of their walls. Lungs lose elasticity, and the accessory muscles used to enhance breathing. Bronchioles collapse during expiration- trap air in alveoli. Hyperinflation leads to “barrel chest”- diaphragm flattens. Damage to alveoli results in damage to pulmonary capillaries. Right side of heart has to work harder to move blood to the lungs- right ventricle enlarges and can lead to heart failure

Question 121

Chronic bronchitis

Answer 121

Chronic production of excess mucus from inhaled irritants. Lower respiratory passages become inflamed over time and eventually fibrose, so ventilation decreases. This mucus is not removed from the lungs. Bacteria and microorganisms thrive in stagnant mucus, so infection is frequent

Question 122

Asthma

Answer 122

Some similarities to COPD, but asthma is temporary bronchospasm attacks followed by symptom free periods. Allergic asthma is most common form- allergen causes inflammation of airways. Inflammation caused by IgE antibodies and persists between attacks- airways become hypersensitive. Subsequent attacks can be very severe

Question 123

Asthma treatment

Answer 123

Treatment- inhaled corticosteroids, bronchodilators

Question 124

Tuberculosis

Answer 124

Bacterial disease spreads (primarily) by inhaled air. Mostly affects lungs, but can spread to other organs- uses lymphatic system to transport. 33% of world population if infected, but it’s not active in most. When inactive, bacteria enters the lungs, but the immune system forms a wall around the bacteria. Forms hardened nodules in the lungs, so the bacteria can’t cause infection

Question 125

Symptoms of active tuberculosis

Answer 125

If active, symptoms include fever, night sweats, weight loss, racking cough, and coughing up blood (due to lung damage from the cough). The immune system can’t trap the bacteria

Question 126

Sleep apnea definition

Answer 126

Characterized by temporary cessation of breathing during sleep. People with sleep apnea wake themselves up due to this condition, can be as high as 30 times per hour. Constant fatigue usually results- increased susceptibility to hypertension, heart disease, stroke, etc. Also causes very loud snoring

Question 127

Forms of sleep apnea (2)

Answer 127

1. Obstructive sleep apnea

2. Central sleep apnea

Question 128

Obstructive sleep apnea

Answer 128

Occurs when upper airways collapse. Muscles associated with pharynx release during sleep, and the airway sags and closes. Most common in men, made worse by obesity. Treatment- CPAP machine- blows air into passages constantly to prevent collapse of pharynx and trachea

Question 129

Central sleep apnea

Answer 129

Respiratory centers of the brain “slack” during sleep- breathing rhythm/rate not maintained. Also controls heart rate and blood pressure, but these are mostly unaffected. Since the airways are still working, CPAP machines don’t help here