1. Drugs for Asthma and Chronic Obstructive Pulmonary Disease
Chapter 76
Drugs for Asthma and Chronic Obstructive Pulmonary Disease

2. Asthma Chronic inflammatory disorder of the airway
Characteristic signs and symptoms
Sense of breathlessness
Tightening of the chest
Wheezing
Dyspnea
Cough
Cause: Immune-mediated airway inflammation

3. Pathophysiology
Symptoms of asthma result from a combination of inflammation and bronchoconstriction, so treatment must address both components

4. Chronic Obstructive Pulmonary Disease (COPD)
Chronic, progressive, largely irreversible disorder characterized by airflow restrictions and inflammation
Characteristic signs and symptoms
Chronic cough
Excessive sputum production
Wheezing
Dyspnea
Poor exercise tolerance
Cause: Smoking cigarettes

5. Pathophysiology
Symptoms of COPD result largely from two pathologic processes: Chronic bronchitis and emphysema
Both processes are caused by an exaggerated inflammatory reaction to cigarette smoke
Chronic bronchitis, which is defined by a chronic cough and excessive sputum production, results from hypertrophy of mucus-secreting glands in the epithelium of the larger airways

6. Pathophysiology
Emphysema is enlargement of the air space within the bronchioles and alveoli, brought on by deterioration of the walls of these air spaces
Among individuals with COPD, the relative contribution of these two processes can vary

7. Overview of Drugs for Asthma and COPD
Two main pharmacologic classes
Anti-inflammatory agents
Glucocorticoids (prednisone)
Bronchodilators
Beta2 agonists (albuterol)

8. Inhalation Drug Therapy
Three obvious advantages
Therapeutic effects are enhanced
Systemic effects are minimized
Relief of acute attacks is rapid
Three types
Metered-dose inhalers (MDIs)
Respimats
Dry-powder inhalers (DPIs)
Nebulizers

9. Anti-Inflammatory Drugs
Foundation of asthma therapy
Taken daily for long-term control
Principal anti-inflammatory drugs are the glucocorticoids (for example, budesonide, fluticasone)

10. Anti-Inflammatory Drugs: Glucocorticoids
Mechanism of action
Considered the most effective antiasthma drugs available
Decrease synthesis and release of inflammatory mediators
Reduce infiltration and activity of inflammatory cells
Decrease edema of the airway mucosa caused by beta2 agonists
Usually administered by inhalation, but IV and oral routes are also options

11. Anti-Inflammatory Drugs: Glucocorticoids
Mechanism of action = suppress inflammation
Reduce bronchial hyperreactivity and decrease airway mucus production
May increase the number of bronchial beta2 receptors and their responsiveness to beta2 agonists

12. Anti-Inflammatory Drugs: Glucocorticoids
Use
Prophylaxis of chronic asthma
Dosing must be on a fixed schedule, not as needed (PRN)
Not used to abort an ongoing attack because beneficial effects develop slowly

13. Anti-Inflammatory Drugs: Glucocorticoids
Inhaled use
First-line therapy for management of inflammatory component of asthma
Most patients with persistent asthma should use these drugs daily
Inhaled glucocorticoids are very effective and much safer than systemic glucocorticoids

14. Anti-Inflammatory Drugs: Glucocorticoids
Oral use
For patients with moderate to severe persistent asthma or for management of acute exacerbations of asthma or COPD
Potential for toxicity; should be used only when symptoms cannot be controlled with safer medications (inhaled glucocorticoids, inhaled beta2 agonists)
Treatment should be as brief as possible

15. Anti-Inflammatory Drugs: Glucocorticoids
Adverse effects of inhaled forms
Adrenal suppression
Oropharyngeal candidiasis
Dysphonia

16. Anti-Inflammatory Drugs: Glucocorticoids
Adverse effects of inhaled forms (Cont.)
Glucocorticoids can slow growth in children and adolescents; however, these drugs do not decrease adult height
Promotion of bone loss
Increased risk of cataracts
Increased risk of glaucoma

17. Anti-Inflammatory Drugs: Glucocorticoids
Adverse effects of oral forms
Short-term therapy
Long-term therapy
Adrenal suppression
Osteoporosis
Hyperglycemia
Peptic ulcer disease
In young patients: Growth suppression

18. Anti-Inflammatory Drugs: Glucocorticoids
Adrenal suppression
Prolonged glucocorticoid use can decrease the ability of the adrenal cortex to produce glucocorticoids of its own
Life-threatening at times of severe physiologic stress (for example, surgery, trauma, or systemic infection)
High levels of glucocorticoids are required to survive severe stress
Adrenal suppression prevents production of endogenous glucocorticoids
Patients must be given increased doses of oral or IV glucocorticoids at times of stress
Failure to do so can prove fatal

19. Anti-Inflammatory Drugs: Glucocorticoids
Adrenal suppression
Discontinuing treatment
Must be done slowly
Recovery of adrenocortical function takes several months
Dosage of exogenous sources must be reduced gradually
During this time, patients ‒ including those switched to inhaled glucocorticoids ‒ must be given supplemental oral or IV glucocorticoids at times of severe stress

20. Anti-Inflammatory Drugs: Leukotriene Modifiers
Suppress effects of leukotrienes
Leukotrienes: Promote smooth muscle constriction, blood vessel permeability, and inflammatory responses through direct action and recruitment of eosinophils and other inflammatory cells
In patients with asthma, leukotriene modifiers can reduce bronchoconstriction and inflammatory responses such as edema and mucus secretion

21. Anti-Inflammatory Drugs: Leukotriene Modifiers
Second-line agents
Generally well tolerated but can cause adverse neuropsychiatric effects, including depression, suicidal thinking, and suicidal behavior
Available agents
Zileuton [Zyflo]
Zafirlukast [Accolate]
Montelukast [Singulair]

22. Anti-Inflammatory Drugs: Leukotriene Modifiers
Zileuton [Zyflo]
Mechanism of action
Adverse effects

23. Anti-Inflammatory Drugs: Leukotriene Modifiers
Zafirlukast [Accolate]
Mechanism of action
Adverse effects

24. Anti-Inflammatory Drugs: Leukotriene Modifiers
Montelukast [Singulair]
Mechanism of action
Adverse effects

25. Anti-Inflammatory Drugs: Cromolyn
Used for prophylaxis, not for quick relief
Suppresses inflammation; not a bronchodilator

26. Anti-Inflammatory Drugs: Cromolyn
Mechanism of action: Stabilizes cytoplasmic membrane of mast cells, thereby preventing release of histamine and other mediators; in addition, inhibits eosinophils, macrophages, and other inflammatory cells

27. Anti-Inflammatory Drugs: Cromolyn
Route: Inhalation
Nebulizer
Therapeutic use
Chronic asthma
Exercise-induced bronchospasm (EIB)
Allergic rhinitis

28. Anti-Inflammatory Drugs: Cromolyn
Adverse effects
Safest of all antiasthma medications
Cough
Bronchospasm

29. Monoclonal Antibody: Omalizumab [Xolair]
Mechanism of action
Antagonism of immunoglobulin E (IgE), a type of antibody
Therapeutic use
Patients age 12 years or older with moderate to severe asthma that (1) is allergy related and (2) cannot be controlled with an inhaled glucocorticoid

30. Monoclonal Antibody: Omalizumab [Xolair]
Adverse effects
Injection-site reactions
Viral infection
Upper respiratory infection
Sinusitis
Headache
Pharyngitis
Cardiovascular events
Malignancy
Life-threatening anaphylaxis

31. Bronchodilators
Provide symptomatic relief but do not alter the underlying disease process (inflammation)
In almost all cases, patients taking a bronchodilator should also be taking a glucocorticoid for long-term suppression of inflammation
Principal bronchodilators are the beta2-adrenergic agonists

32. Bronchodilators: Beta2-Adrenergic Agonists
Mechanism of action
Through activation of beta2 receptors in the smooth muscle of the lung, these drugs promote bronchodilation, relieving bronchospasm
Beta2 agonists have a limited role in suppressing histamine release in the lung and increasing ciliary motility

33. Bronchodilators: Beta2-Adrenergic Agonists
Use in asthma and COPD
Inhaled short-acting beta2 agonists (SABAs)
Taken PRN to abort an ongoing attack
EIB: Taken before exercise to prevent an attack
Hospitalized patients undergoing a severe acute attack: Nebulized SABA is the traditional treatment of choice
Delivery with an MDI in the outpatient setting may be equally effective

34. Bronchodilators: Beta2-Adrenergic Agonists
Use in asthma and COPD
Inhaled long-acting beta2 agonists (LABAs)
Long-term control in patients who experience frequent attacks
Dosing is on a fixed schedule, not PRN
Effective in treating stable COPD
When used to treat asthma, must always be combined with a glucocorticoid
Use alone in asthma is contraindicated

35. Bronchodilators: Beta2-Adrenergic Agonists
Adverse effects
Inhaled preparations
Systemic effects: Tachycardia, angina, tremor
Oral preparations
Excessive dosage: Angina pectoris, tachydysrhythmias
Tremor

36. Bronchodilators: Methylxanthines
Theophylline
Other methylxanthines include aminophylline and dyphylline

37. Bronchodilators: Methylxanthines
Theophylline
Produces bronchodilation by relaxing smooth muscle of the bronchi
Narrow therapeutic index
Plasma level 10 to 20 mcg/mL
Toxicity is related to theophylline levels
The drug is usually administered by mouth but may also be administered intravenously

38. Bronchodilators: Methylxanthines
Use in asthma and COPD
Oral theophylline is used for maintenance therapy of chronic stable asthma
Theophylline is no longer recommended for treatment of COPD
Toxicity
Plasma levels below 20 mcg/mL: Adverse effects uncommon
Plasma levels of mcg/mL: Nausea, vomiting, diarrhea, insomnia, restlessness
Plasma levels above 30 mcg/mL: Severe dysrhythmias (for example, ventricular fibrillation) and convulsions
Death may result from cardiorespiratory collapse

39. Bronchodilators: Methylxanthines
Toxicity treatment
Stop theophylline
Activated charcoal together with a cathartic
Dysrhythmias respond to lidocaine
Intravenous diazepam may help control seizures
Interactions
Caffeine
Tobacco and marijuana
Cimetidine
Fluoroquinolone antibiotics

40. Anticholinergic Drugs: Ipratropium
Improves lung function by blocking muscarinic receptors in the bronchi, thereby reducing bronchoconstriction
Action and use
Administered by inhalation to relieve bronchospasm
Therapeutic effects begin within 30 seconds, reach 50% of maximum in 3 minutes, and persist about 6 hours
Adverse effects
Dry mouth and irritation of the pharynx
Glaucoma
Cardiovascular events

41. Anticholinergic Drugs: Tiotropium
Long-acting, inhaled anticholinergic agent approved for maintenance therapy of bronchospasm associated with COPD
Not approved for asthma
Relieves bronchospasm by blocking muscarinic receptors in the lung
Therapeutic effects begin about 30 minutes after inhalation, peak in 3 hours, and persist about 24 hours
With subsequent doses: Bronchodilation continues to improve, reaching a plateau after eight consecutive doses (8 days)

42. Anticholinergic Drugs: Tiotropium
Adverse effect: Dry mouth
Minimal anticholinergic effects

43. Anticholinergic Drugs: Aclidinium
Newest long-acting anticholinergic for management of bronchospasm associated with COPD
Relieves bronchospasm by blocking muscarinic receptors in the lung
Peak levels have occurred within 10 minutes of drug delivery
Intended only for maintenance therapy
Not for acute symptom relief

44. Anticholinergic Drugs: Aclidinium
Adverse effects
Headache
Nasopharyngitis
Cough

45. Glucocorticoid/LABA Combinations
Available combinations
Fluticasone/salmeterol [Advair]
Budesonide/formoterol [Symbicort]
Mometasone/formoterol [Dulera]
Indicated for long-term maintenance in adults and children
Not recommended for initial therapy

46. Management of Asthma Tests of lung function
Forced expiratory volume in 1 second (FEV1)
Forced vital capacity (FVC)
Peak expiratory flow (PEF)

47. Management of Asthma Four classes of asthma severity Intermittent
Mild persistent
Moderate persistent
Severe persistent

48. Management of Chronic Asthma
Treatment goals
Reducing impairment
Reducing risk

49. Management of Chronic Asthma
Long-term drug therapy
Agents for long-term control (for example, inhaled glucocorticoids)
Agents for quick relief of ongoing attack (for example, inhaled SABAs)

50. Management of Chronic Asthma
Stepwise therapy
Step chosen for initial therapy is based on pretreatment classification of asthma severity
Moving up or down a step is based on ongoing assessment of asthma control

51. Management of Chronic Asthma
Important to reduce exposure to allergens and triggers
Sources of allergens: House dust mites, pets, cockroaches, mold
Factors that can exacerbate asthma: Tobacco smoke, wood smoke, household sprays

52. Drugs for Acute Severe Exacerbation
This condition requires immediate attention
Goals: Relieve airway obstruction and hypoxemia, and normalize lung function as quickly as possible
Initial therapy consists of administering:
Oxygen ‒ To relieve hypoxemia
A systemic glucocorticoid ‒ To reduce airway inflammation
A nebulized, high-dose SABA ‒ To relieve airflow obstruction
Nebulized ipratropium ‒ To further reduce airflow obstruction

53. Drugs for Exercise-Induced Asthma
Cause: Bronchospasm secondary to loss of heat and/or water from the lung
Starts either during or immediately after exercise, peaks in 5 to 10 minutes, and resolves 20 to 30 minutes later
SABA or cromolyn administered prophylactically
Inhaled SABAs generally preferred over cromolyn
Beta2 agonists should be inhaled immediately before exercise
Cromolyn should be inhaled 15 minutes before exercise

54. Reducing Exposure to Allergens and Triggers
Measures to control or avoid dust mites and their feces
Encase the patient’s pillow, mattress, and box spring in covers impermeable to allergens
Wash all bedding and stuffed animals weekly in a hot-water wash cycle (130º F)
Remove carpeting or rugs from bedroom
Avoid sleeping or lying on upholstered furniture
Keep indoor humidity below 50%

55. Management of COPD Measurement of lung function
Classification of COPD severity
Mild
Moderate
Severe
Very severe

56. Management of COPD Treatment goals
Reduce symptoms, thereby improving the patient’s health status and exercise tolerance
Reduce risks and mortality by preventing progression of COPD and by preventing and managing exacerbations

57. Management of COPD Patient classification
Group A: Few symptoms; low risk
Group B: Increased symptoms; low risk
Group C: Few symptoms; high risk
Group D: Increased symptoms; high risk

58. Management of Stable COPD
Pharmacologic management
Bronchodilators
Glucocorticoids
Phosphodiesterase-4 inhibitors

59. Management of COPD Exacerbations
Pharmacologic management
SABAs (specifically inhaled, either alone or in combination with inhaled anticholinergics) are preferred for bronchodilation during COPD exacerbations
Systemic glucocorticoids
Antibiotics
Supplemental oxygen to maintain an oxygen saturation of 88% to 92%

60. Question 1
A patient with asthma is prescribed albuterol [Proventil], two puffs 3 times per day. The nurse should teach the patient to do what?
A. Rinse the mouth after taking the prescribed dose.
B. Take an extra dose if breathing is compromised.
C. Wait 1 minute between puffs from the inhaler.
D. Take adequate amounts of calcium and vitamin D.
Answer: C
Rationale: Patients should be taught to wait at least 1 minute between puffs. Extra doses should not be taken unless prescribed by the health care provider. Glucocorticoid inhalation requires oral rinses to prevent the development of dysphonia and oropharyngeal candidiasis. Patients should take adequate amounts of calcium and vitamin D with glucocorticoid therapy.

61. Question 2 A patient with asthma is prescribed triamcinolone acetonide
[Azmacort]. What should the nurse do?
A. Take the patient’s pulse before administering the medication.
B. Teach the patient to use a spacer to prevent a fungal infection.
C. Instruct the patient to use this drug to treat an acute attack.
D. Encourage the patient to avoid weight-bearing activity.
Answer: B
Rationale: Acetonide is an inhaled glucocorticoid. Spacers disperse the medication into the lungs, leaving less in the oropharyngeal mucosa; this reduces the incidence of fungal infection. Beta2-adrenergic agonists may cause tachycardia and are used to abort acute asthma attacks. Patients taking glucocorticoids should engage in weight-bearing activities to prevent osteoporosis. This drug should not be used to treat an acute attack.

62. Question 3
Which information should the nurse include when teaching a patient about inhaled glucocorticoids?
A. Inhaled glucocorticoids have many significant adverse effects.
B. The principal side effects of inhaled glucocorticoids include hypertension and weight gain.
C. Use of a spacer can minimize side effects.
D. Patients should rinse the mouth and gargle before administering inhaled glucocorticoids.
Answer: C
Rationale: Inhaled glucocorticoids are generally very safe. Their principal side effects are oropharyngeal candidiasis and dysphonia, which can be minimized by using a spacer device during administration and by rinsing the mouth and gargling after use.

63. Question 4
Which of the following is NOT a serious adverse effect of long-term oral glucocorticoid therapy?
A. Adrenal suppression
B. Osteoporosis
C. Hypoglycemia
D. Peptic ulcer disease
Answer: C
Rationale: Serious adverse effects include adrenal suppression, osteoporosis, hyperglycemia, peptic ulcer disease, and growth suppression.