1. Chapter 23 Disorders of Ventilation and Gas Exchange
Essentials of Pathophsiology
Chapter 23 Disorders of Ventilation and Gas Exchange

2. Pre lecture quiz True/false
Pleural, musculoskeletal, and myocardial pain are similar in description and almost impossible to differentiate.
Extrinsic or atopic asthma is typically initiated by a type I hypersensitivity reaction induced by exposure to an extrinsic antigen or allergen, such as dust mite allergens, cockroach allergens, and animal dander.
Persons with emphysema are often labeled as “blue bloaters” because of the chronic hypoxemia and eventual right-sided heart failure with peripheral edema.
Cystic fibrosis is manifested by pancreatic exocrine deficiency and a noted decrease in levels of sodium chloride in the sweat.
Hypercapnia refers to an abnormal increase in oxygen levels.

3. Pre lecture quiz
Asthma
Effusion
Embolism
Right
Tension
A pleural __________ refers to an abnormal collection of fluid in the pleural cavity.
__________ is a leading cause of chronic illness in children and is responsible for a significant number of lost school days; it is also the most frequent admitting diagnosis in children’s hospitals.
A __________ pneumothorax, a life-threatening condition, occurs when the intrapleural pressure exceeds atmospheric pressure, permitting air to enter but not leave the pleural space.
A pulmonary __________ develops when a blood-borne substance lodges in a branch of the pulmonary artery and obstructs the flow.
Cor pulmonale refers to __________-sided heart failure resulting from primary lung disease and involves hypertrophy and eventual failure of that ventricle.

4. Causes of Respiratory Failure
Hypoventilation  hypercapnia, hypoxia
Depression of the respiratory center
Diseases of respiratory nerves or muscles
Thoracic cage disorders
Ventilation–perfusion mismatching
Impaired diffusion  hypoxemia but not hypercapnia
Interstitial lung disease
ARDS
Pulmonary edema
Pneumonia

5. Impaired function of vital centers
Hypoxemia
PO2 <60 mm Hg
Cyanosis
Impaired function of vital centers
Agitated or combative behavior, euphoria, impaired judgment, convulsions, delirium, stupor, coma
Retinal hemorrhage
Hypotension and bradycardia
Activation of compensatory mechanisms
Sympathetic system activation

6. PCO2 >50 mm Hg Respiratory acidosis Hypercapnia
Increased respiration
Decreased nerve firing
Carbon dioxide narcosis
Disorientation, somnolence, coma
Decreased muscle contraction
Vasodilation
Headache; conjunctival hyperemia; warm, flushed skin
CO2 + H2O H2CO3 H+ + HCO3-

7. Question
Tell whether the following statement is true or false. Both hypercapnia and hypoxemia will lead to respiratory failure if untreated.

8. Answer
True Rationale: In hypercapnia (PCO2 >50 mm Hg), tissues accumulate carbon dioxide; in hypoxemia (PO2 <60 mm Hg), less oxygen is delivered to the tissues. In both cases, gas exchange is impaired, and respiratory failure will result unless the conditions are corrected (with oxygen, mechanical ventilation, etc.).

9. Pleural Disorders Decrease Ventilation
Parietal pleura lines the thoracic wall and superior aspect of the diaphragm
Visceral pleura covers the lung
Pleural cavity or space between the two layers contains a thin layer of serous fluid

10. Scenario Mr. K presents himself with a stab wound
Now he is having breathing problems, and his breath sounds are diminished on the side with the wound
His trachea seems to be slanting toward the other side of his chest, and his heart sounds are displaced away from the wound
He has an increased respiration rate and blood pressure, is pale and sweating with bluish nail beds, and has no bowel sounds
Question:
Explain the effects of the wound

11. Air enters the pleural cavity
Pneumothorax
Air enters the pleural cavity
Air takes up space, restricting lung expansion
Partial or complete collapse of the affected lung
Spontaneous: an air-filled blister on the lung ruptures
Traumatic: air enters through chest injuries
Tension: air enters pleural cavity through the wound on inhalation but cannot leave on exhalation
Open: air enters pleural cavity through the wound on inhalation and leaves on exhalation

12. Open Pneumothorax
Air goes out
Air Comes in

13. Tension Pneumothorax
Air comes in
Air is trapped

14. Question
Tell whether the following statement is true or false. Open pneumothorax is more life-threatening than tension pneumothorax.

15. Answer
False Rationale: In open pneumothorax, inhaled air compresses the affected side’s lung, but during exhalation, the lung reinflates somewhat. In tension pneumothorax, a sort of one-way valve exists: the air enters the affected side during inhalation, but is unable to leave when the patient exhales. Therefore, all of this air exerts increased pressure on the organs of the thoracic cage. Unless the pressure is relieved, tension pneumothorax is fatal.

16. Pleural Effusion—Fluid in the Pleural Cavity
Hydrothorax: serous fluid
Empyema(em-pī-ē-mə) : pus
Chylothorax: lymph
Hemothorax: blood
an accumulation of fluid in one or both pleural cavities, often resulting from disease of the heart or kidneys
fluid in the pleural space secondary to leakage from the thoracic duct

17. Obstructive Airway Disorders
Bronchial asthma
Chronic obstructive airway diseases
Chronic bronchitis
Emphysema
Bronchiectasis
Cystic fibrosis

18. Pathogenesis of Bronchial Asthma
Early Phase
Antigen
IgE
Cytokine Release
Muscle Spasm
Late Phase
Mast Cell Activation
Vascular porosity
Edema and WBC infiltration
Epithelial Damage
Muscle Spasm with edema

19. Extrinsic (Atopic) Asthma
Type I hypersensitivity
Mast cells’ inflammatory mediators cause acute response within 10–20 minutes
Treat with inhalers
Airway inflammation causes late-phase response in 4–8 hours
Treat with antiflamatory
Allergen
Mast cells release
inflammatory
mediators
WBCs enter region
and release more
inflammatory
mediators

20. Intrinsic (Nonatopic) Asthma
Respiratory infections
Epithelial damage, IgE production
Exercise, hyperventilation, cold air
Loss of heat and water may cause bronchospasm
Inhaled irritants
Inflammation, vagal reflex
Aspirin and other NSAIDs
Abnormal arachidonic acid metabolism

21. Airway Obstruction in Asthma
inflammatory
airway
mediators
inflammation
increased
epithelial
impaired
airway
injury
mucociliary
responsiveness
function
bronchospasm
edema
airflow limitation

22. Which of the following occurs in asthma? Airway inflammation
Question
Which of the following occurs in asthma?
Airway inflammation
Bronchospasm
Decreased ability to clear mucus
All of the above

23. Answer
All of the above
Rationale: Inflammatory mediators lead to airway inflammation, edema of the mucous lining of the airways, bronchospasm, and impaired ability to clear secretions. All of these things cause the airways to narrow during an asthma attack.

24. Chronic Obstructive Pulmonary Disorders
Emphysema
Enlargement of air spaces and destruction of lung tissue
Chronic obstructive bronchitis
Obstruction of small airways
Bronchiectasis
Infection and inflammation destroy smooth muscle in airways, causing permanent dilation
the bronchi are distended, characterized by sudden violent coughing and copious expectoration of sputum, and which often become infected

25. Mechanisms of COPD Inflammation and fibrosis of bronchial wall
Hypertrophied mucus glands  excess mucus
Obstructed airflow
Loss of alveolar tissue
Decreased surface area for gas exchange
Loss of elastic lung fibers
Airway collapse, obstructed exhalation, air trapping

26. Mechanism of COPD A) Inflammation, Fibrosis B) Hypersecretion of mucus
C) Destruction of elastic fibers that hold the airways open
Author: Please add title.

27. Emphysema Neutrophils in alveoli secrete trypsin
Increased neutrophil numbers due to inhaled irritants can damage alveoli
Alpha1-antitrypsin inactivates the trypsin before it can damage the alveoli
A genetic defect in alpha1-antitrypsin synthesis leads to alveolar damage

28. Types of Emphysema

29. Emphysemia Chest Wall Shape
Author: Please add title.

30. Chronic Bronchitis Chronic irritation of airways
Increased number of mucus cells
Mucus hypersecretion
Productive cough

31. Pink Puffers vs. Blue Bloaters
Pink puffers (usually emphysema)
Increase respiration to maintain oxygen levels
Dyspnea; increased ventilatory effort
Use accessory muscles; pursed-lip breathing
Blue bloaters (usually bronchitis)
Cannot increase respiration enough to maintain oxygen levels
Cyanosis and polycythemia
Cor pulmonale

32. Bronchiectasis (dilitation)
Question
Which chronic obstructive pulmonary disease primarily affects the alveoli?
Asthma
Emphysema
Chronic bronchitis
Bronchiectasis (dilitation)

33. Answer
Emphysema
Rationale: In emphysema, alveolar walls are destroyed. The other chronic pulmonary diseases listed primarily affect the airways.

34. Normal when stabilized & down to 7.3 unstabilized
COPD and Blood pH
Discussion:
In what range will a COPD client’s blood pH fall?
Why?
Normal when stabilized & down to 7.3 unstabilized
CO2 +H2O H2CO H+ + HCO3-
Venous blood gas
Respiratory acidosis(lung induced): Low pH, High CO2, Low HCO3-
Metabolic (tissue induced): Low pH, High CO2, Normal HCO3-

35. Consequences of COPD
COPD
Which step in this flow chart will cause the central chemoreceptors to increase respiration?
Which will cause the peripheral chemoreceptors to increase respiration?
decreased
ability to
exhale
stale air in
lungs
low O2
high
levels
CO2
levels
hypoxia
hypercapnia

36. Scenario
A client with chronic bronchitis has a barrel chest and cyanosis. His pulse oximeter reads 86% oxygenation. His PO2 is 54 mm Hg. His PCO2 is 56 mm Hg.
He is put on low-flow oxygen but complains of shortness of breath. Somebody turns the O2 flow up. He is found in a coma with a PCO2 of 59 mm Hg and a blood pH of 7.2.
Question:
What was the cause of the coma? Why?

37. Cystic Fibrosis Recessive disorder in chloride transport proteins
High concentrations of NaCl in the sweat
Less Na+ and water in respiratory mucus and in pancreatic secretions
Mucus is thicker
Obstructs airways
Obstructs pancreatic and biliary ducts

38. Pathogenesis of Cystic Fibrosis
Cystic Fibrosis Transmembrane Regulator Gene Failure

39. Cystic Fibrosis Manifestations
Discussion:
A client with cystic fibrosis is having respiratory problems and:
Digestive problems
Flatulence
Steatorrhea
Weight loss
Question:
He does not understand why a respiratory disease would cause these problems. How would this be explained to the client?
Steatorrhea is the presence of excess fat in feces. Stools may also float due to excess lipid, have an oily appearance and be especially foul smelling.

40. Pulmonary Blood Flow
In a COPD client, exhalation is inefficient and O2 levels in the lungs decrease
If blood goes through the lungs filled with stale air, it will not pick up much oxygen; it might even pick up CO2
Discussion:
What will the pulmonary arterioles do?
Which side of the heart will be affected? Why?

41. Disorders of Pulmonary Blood Flow
Pulmonary embolism
Pulmonary hypertension
Primary
Blood vessel walls thicken and constrict
Secondary
Elevation of pulmonary venous pressure
Increased pulmonary blood flow
Pulmonary vascular obstruction
Hypoxemia

42. Pulmonary Embolism

43. Results of Pulmonary Hypertension
Author: Please add title.
Occluded pulmonary artery

44. Right-sided heart failure secondary to respiratory disease
Cor Pulmonale
Right-sided heart failure secondary to respiratory disease
Decreased lung ventilation
Pulmonary vasoconstriction
Increased workload on right heart
Decreased oxygenation
Kidney releases erythropoietin  more RBCs made
Polycythemia makes blood more viscous
Increased workload on heart

45. Acute Respiratory Distress Syndrome (ARDS)
Exudate enters alveoli
Blocks gas exchange
Makes inhalation more difficult
Neutrophils enter alveoli
Release inflammatory mediators
Release proteolytic enzymes

46. Mechanisms of Lung Changes in ARDS

47. Question
Tell whether the following statement is true or false. Patients suffering from ARDS will be not necessarily be hypoxemic.

48. Answer
False Rationale: In ARDS the alveoli are filled with exudate, decreasing the available surface area for gas exchange. If gas exchange decreases, poorly oxygenated or unoxygenated blood is sent to the tissues (hypoxemia).