What Are The Latest Treatment of Emphysema

Treatment of Emphysema/Emphysema is defined as a pathological permanent dilatation of distal airways (respiratory bronchioles, alveolar ducts, and alveolar sacs) due to the destruction of the walls of the airways without fibrotic changes. Emphysema destroys the essential ventilatory units and interrupts the gas exchange. Functionally, emphysema causes obstructive ventilatory defect evidenced in the spirometry and is included in the collective diseases of chronic obstructive pulmonary disease, commonly termed as COPD. [rx]

Emphysema is defined as “an anatomic alteration of the lung characterized by an abnormal airspace enlargement distal to the terminal bronchioles accompanied by destructive changes of the alveolar walls”[rx] and is a variable component of the syndrome COPD which is now understood to have also extrapulmonary systemic manifestations.[rx]

Pulmonary emphysema a progressive lung disease, is a form of chronic obstructive pulmonary disease (COPD). Global Initiative has defined COPD for chronic obstructive lung disease (GOLD) as “a common, preventable and treatable disease that is characterized by persistent respiratory symptoms and airflow limitation that is due to airway and/or alveolar abnormalities usually caused by significant exposure to noxious particles or gases. [rx][rx][rx]

Pathophysiology

Emphysema involves pathological destruction of alveolar walls and respiratory bronchioles, alveolar ducts, alveolar sacs causing permanent dilatation resulting in a decreased surface area of the ventilatory units. Ventilation or gas exchange requires an intact alveolar wall, interstitium, and capillaries with adequate blood flow. Hence emphysema interferes with gas exchange leading to extreme hypoxia and hypercapnia thus resulting in respiratory failure. Emphysema classifies into three subtypes namely- centriacinar, panacinar, and paraseptal. Paraseptal emphysema can occur in smokers as well as with alpha-1 antitrypsin (AAT) deficiency. Centriacinar is common in smokers, and panacinar is prevalent in AAT deficiency. With the exposure to smoke and other chemicals, inflammatory mediators such as macrophages, T lymphocytes, and neutrophils are activated, releasing cytokines. Also, proteinases are released, destroying the lung parenchymal connective tissue and ventilatory units causing, in advanced cases, severe hypoxia and hypercarbia. Another consequence is excessive mucus production. It is worth noting that AAT is an anti-proteinase that prevents lung destruction by counteracting the proteinase and due to their genetic deficiency, emphysema occurs due to the loss of this protection

Types of Emphysema

Pulmonary emphysema can be classified into three major subtypes based on the disease distribution within secondary pulmonary lobules [rx]:

Centriacinar emphysema,
Panacinar emphysema, and
Distal acinar emphysema [rx]. The relationships among these types of pulmonary emphysema and how each type is formed have yet to be clarified.

The GOLD Emphysema Staging System

Group A (GOLD 1 or 2) – Your symptoms are very mild. Your FEV₁ is 80% or more. You might have had no flare-ups over the past year, or perhaps just one. You weren’t hospitalized for your symptoms.
Group B (GOLD 1 or 2) – Your FEV₁ is between 50% and 80%. You have more symptoms than people in Group A. This is the stage where most people see their doctor for coughing, wheezing, and shortness of breath.
Group C (GOLD 3 or 4) – Airflow into and out of your lungs is severely limited. Your FEV1 is between 30% and 50%. You’ve had more than two flare-ups in the past year, or you’ve been admitted to the hospital at least once.
Group D (GOLD 3 or 4) – It’s extremely hard for you to breathe in or out. You’ve had at least two flare-ups in the past year, or you’ve been hospitalized at least once.

The BODE Index

This staging system measures how much emphysema impacts your daily life. It looks at four main areas:

Body mass index (B) – This describes how much body fat you have compared to your height and weight.
Airflow limitation (O for obstruction) – Your doctor can tell how damaged your lungs are by how well you do on pulmonary (lung) function tests.
Breathlessness (D – doctors call it dyspnea) – Your doctor will ask you a series of questions about how often you feel like you’re out of breath, and when.
Exercise capacity (E) – This measures how far you can walk in 6 minutes. Studies show that the BODE Index gives doctors a better idea about your outcome (what they call a prognosis) than FEV₁. And they can use those findings to see how well you’ll respond to medications, lung rehab therapy, and other treatments.

The stages are based on forced expiratory volume in 1 second (FEV1).

Very mild or Stage 1 – FEV1 is about 80 percent of normal
Moderate or Stage 2 – FEV1 is between 50 and 80 percent of normal
Severe or Stage 3 – FEV1 is between 30 and 50 percent of normal
Very severe or Stage 4 – FEV1 is lower than in Stage 3, or the same as Stage 3 but with low blood oxygen levels

Causes of Emphysema

Injury to the parietal pleura that allows for the passage of air into the pleural and subcutaneous tissues
Air from the alveolus spreading into the endovascular sheath and lung hilum into the endothoracic fascia
The air in the mediastinum spreading into the cervical viscera and other connected tissue planes
Air originating from external sources
Gas generation locally by infections, specifically, necrotizing infections
Post infective (post pneumonia, whooping cough, measles, mycobacterial infection)
Mucociliary disorder (immotile cilia, Kartagener’s syndrome, Young’s syndrome)
Obstructive (foreign body, mycobacterial infection, obstructing cancer)
Immune disorder (hypogammaglobulinemia, HIV infection, cancer, allergic bronchopulmonary aspergillosis, transplant rejection)
Rheumatic/inflammatory disease (rheumatoid arthritis, inflammatory bowel disease)
Extremes of age
Malnutrition/socioeconomic disadvantage
Chronic obstructive pulmonary disease
Miscellaneous (yellow nail syndrome)
Alpha1-antitrypsin deficiency

Bacterial Infections

Mycobacterium: Tuberculosis and atypical
Haemophilus influenzae
Pseudomonas aeruginosa
Staphylococcus aureus
Mycoplasma and HIV

Viral Infections

Respiratory syncytial virus and measles

Fungal Infections with Bronchial obstruction

Foreign body
Mucus plug
Tumors
Hilar lymphadenopathy (right middle lobe syndrome: extrinsic compression from postinfectious adenopathy)

Postinflammatory pneumonitis

Chronic aspiration/gastroesophageal reflux disorder
Chronic sinusitis
Inhalational injury

Congenital/Genetic

Cystic fibrosis
Young syndrome
PCD: primary ciliary dyskinesia (Kartenger Syndrome)
immunodeficiency (hypogammaglobulinemia)
Alpha1-antitrypsin deficiency (AAT)
Mounier-Kuhn syndrome

Inflammatory diseases

Ulcerative colitis
Rheumatoid arthritis
Sjögren syndrome

Pulmonary Diseases

Asthma
Bronchomalacia
Cronic-obstructive pulmonary disease (COPD) (reported in up to 50% of patients with moderate-to-severe COPD)
Diffuse panbronchiolitis
Idiopathic pulmonary fibrosis (traction bronchiectasis)

Altered immune response

Allergic Bronchopulmonary Aspergillosis
Hypersensitivity pneumonitis

Others

Yellow nail syndrome (yellow nails, lymphedema, pleural effusion, bronchiectasis 40% first described in 1964)
Allergic bronchopulmonary aspergillosis (ABPA) is a rare but typical complication in bronchiectasis. The underlying pathophysiology is sensitization to Aspergillus fumigatus, which leads to a CD4+/TH2 mediated inflammatory reaction.
Typical symptoms include a raised body temperature, weight loss, a drop in FEV1, and pulmonary infiltrates on the radiograph. Bronchiectasis can be a sequela of ABPA, but it can also predispose to ABPA.

Symptoms of Emphysema

Cough – 98%, sputum: 78% (sputum is typically mucoid and relatively odorless), dyspnea: 62%, haemoptysis: 56% to 92%, and pleuritic chest pain: 20% (secondary to chronic coughing).
Some people with bronchiectasis – may have a cough productive of frequent green/yellow mucus (sputum), up to 240 ml (8 oz) daily.
Bronchiectasis – may also present with coughing up blood (hemoptysis) in the absence of sputum, called “dry bronchiectasis”. Sputum production may also occur without coloration. People with bronchiectasis may have bad breath indicative of active infection.
Frequent bronchial infections – and breathlessness are two possible indicators of bronchiectasis. Crepitations and expiratory rhonchi may be heard on auscultation. Nail clubbing is rare.^[rx]
Breathing difficulties during physical exercise – and while at rest in advanced COPD
Shortness of breath, especially during light exercise or climbing steps
The ongoing feeling of not being able to get enough air
Long-term cough or smoker’s cough
Wheezing
Long-term mucus production
Ongoing fatigue
Daily cough over a long period of time
Sputum (coughed-up phlegm)
Breathing sounds such as wheezing
Symptoms that get worse when you have a cold or flu
Chronic daily cough
Coughing up blood
Abnormal sounds or wheezing in the chest with breathing
Chest pain
Coughing up large amounts of thick mucus every day
Weight loss
Fatigue
Change in the structure of fingernails and toenails, known as clubbing
Frequent respiratory infections

Diagnosis of Emphysema

GOLD staging based on the severity of airflow limitation is as follows

[stextbox id=’info’]

GOLD grade^[rx]
Severity	FEV₁ % predicted
Mild (GOLD 1)	≥80
Moderate (GOLD 2)	50–79
Severe (GOLD 3)	30–49
Very severe (GOLD 4)	<30

MRC shortness of breath scale^[rx]
Grade	Activity affected
1	Only strenuous activity
2	Vigorous walking
3	With normal walking
4	After a few minutes of walking
5	With changing clothing

[/stextbox]

Mild with FEV1 greater or equal to 80% predicted
Moderate with FEV1 less than 80%predicted
Severe with FEV1 less than 50% predicted
Very severe with FEV1 less than 30 % predicted
Blood tests – to check how well your immune system is working and check for infectious agents, such as bacteria, viruses, and fungi.
Blood tests, including a complete blood count (CBC) – to see if you have anemia (when your body doesn’t make enough red blood cells) or infection and other tests to check for a blood clot or fluid in your lungs.
Phlegm (sputum) test – to check for bacteria or fungi
a sample of your sweat can be tested to see how much salt is in it – high levels of salt can be caused by cystic fibrosis (if this test is positive, a more detailed genetic test can be carried out.
Lung function test – a small, handheld device (a spirometer) that you blow into is used to measure how hard and how quickly you can expel air from your lungs; this can assess how well your lungs are working
Bronchoscopy – a flexible tube with a camera at one end is used to look into your lungs; this is usually only required if you think you have inhaled a foreign object
A chest x-ray – is only helpful in diagnosis if emphysema is severe, but it is usually the first step when suspecting COPD to rule out other causes. Destruction of alveoli and air trapping causes hyperinflation of lungs with flattening of diaphragm and heart appears elongated and tubular-shaped.
Arterial blood gases – are usually not required in mild to moderate COPD. It is done when oxygen saturation goes below 92%, or there is severe airflow obstruction to access for hypercapnia.
Spirometry – A test called spirometry can help show how well your lungs are working. You’ll be asked to breathe into a machine called a spirometer after inhaling a medication called a bronchodilator, which helps widen your airways. The spirometer takes two measurements: the volume of air you can breathe out in one second, and the total amount of air you breathe out. You may be asked to breathe out a few times to get a consistent reading.

Other tests you might have include

Pulse oximetry – a device is clipped to your finger or ear lobe, and a light on it measures how much oxygen is in your blood.
Chest X-ray or a computerized tomography (CT) scan – to see if you have pneumonia, blood clot in your lung, or another lung disease. A CT scan puts several X-rays taken from different angles together to make a more complete picture.
Electrocardiogram (ECG) – to measure the electrical signals from your heart to see if you’re having a heart attack and find out how fast your heart is beating and if it has a healthy rhythm.
Patients should be tested for electrolyte abnormalities – endocrine disorders (specifically hyperthyroid) drug-induced causes, infections, drug or chemical withdrawal, and echocardiography to check for structural heart disease. In patients presenting with ischemic stroke and with no prior history of AF, 72-hour Holter monitoring improves the detection rate of silent paroxysmal.[rx]
Screening spirometry – Can assess how much air you can breathe
Complete pulmonary function testing – Can evaluate your breathing capabilities in more detail than screening spirometry by measuring how much air you can breathe in and out, as well as how quickly
Arterial blood gas measurement – Provides a measure of the oxygen content of your blood, which alerts your doctors if you are becoming low in oxygen
Echocardiography – May be ordered if your EKG suggests that you have heart disease
Standard exercise treadmill testing – Evaluates your breathing when you have increased oxygen demands
Complete cardiopulmonary exercise testing – Evaluates your heart and lung function in detail.

Treatment Emphysema

There is no known, definitive treatment which can modify the disease process. However, risk-factor modification and management of symptoms have been proven effective in slowing the disease progression and optimizing the quality of living.[rx][rx][rx]

Based on the symptoms and number of exacerbations, we can divide the disease into 4 COPD GOLD stages and modify the treatment accordingly.

Antibiotics – If your doctor or healthcare provider suspects that you have a lung infection, he or she may order antibiotic pills or intravenous (IV), depending on how severe your illness is, and your overall health status. Commonly prescribed antibiotics for bronchitis, pneumonia and respiratory (breathing) problems include azithromycin and levofloxacin. If you are prescribed antibiotic pills, take the full prescription. Do not stop taking pills once you feel better.
Cough medications/Decongestants – may help you to be more comfortable if you are coughing a lot. Guaifenesin is an active ingredient in many cough medications, may be given alone, but is often combined with other drugs, such as codeine, to help your cough. Guaifenesin may also be combined with pseudoephedrine as a decongestant, or anyone of many medications, depending on your symptoms. Another common medication you may receive is Hydrocodone Bitartrate-Homatropine Methylbromide. This is a narcotic antitussive (anti-cough medication), which will help relieve your cough.
Antianxiety medications – If you are experiencing anxiety with your emphysema, depending on the cause, your healthcare provider may prescribe an anti-anxiety medication, called an anxiolytic. These medications will help you to relax. These may include lorazepam or alprazolam. It is important to take these medications only when you are feeling anxious. Do not operate heavy machinery, or drive an automobile while taking these. These medications must be used very cautiously if you have a severe pneumothorax. Discuss the risks and benefits of taking this medication with your doctor or healthcare provider.
Beclomethasone – an inhaled steroid, is useful in the treatment of chronic emphysema. Inhaled steroids act directly on the lung tissue, so there are fewer long-term side effects, compared with a pill or IV form. People who have an outbreak of severe shortness of breath and airway inflammation may be ordered a steroid pill, such as prednisone, for a short period of time. This is usually given with inhaled steroids. Patients with severe asthma may require IV administration of another steroid, methylprednisolone.
Diuretics – may be known as “water pills” as they work to prevent or treat lung congestion by making you urinate out extra fluid. Some examples of this medication may include furosemide and Hydrochlorothiazide. You may receive this medication alone or in combination with other medications.
Drugs that open up (dilate) the airways (bronchodilators) These drugs are typically inhaled as a powder to make it easier to breathe. They include beta-2 agonists, anticholinergics, and methylxanthines.
PDE4 inhibitors – These tablets also have an anti-inflammatory effect.
Medical therapy – includes using a bronchodilator alone or in combination with anti-inflammatory drugs (corticosteroids and phosphodiesterase four inhibitors).

Bronchodilator

The primary mechanisms of action can be divided into two categories

Beta2 agonists and anticholinergic medications – They are first-line drugs for COPD and are administered by inhalation. They are known to improve FEV1 by altering the smooth muscle tone of the airways and thus improve exercise tolerance. Bronchodilators are usually given regularly to prevent and to reduce symptoms, exacerbations, and hospitalizations.
Short-acting beta2 agonists (SABA) – and short-acting muscarinic antagonists (SAMA) are usually prescribed as needed for management of intermittent dyspnea. Long-acting beta2 agonists (LABA) and long-acting muscarinic antagonists (LAMA) are used especially with increasing dyspnea or more than occasional dyspnea. If the symptoms are persistent while on one bronchodilator, another bronchodilator should be added.
Beta2 agonists – cause relaxation of airway smooth muscles. SABA like albuterol can be used with or without anticholinergics. SABA is the mainstay in COPD exacerbation. LABA includes formoterol, salmeterol, indacaterol, olodaterol, vilanterol, among others. The side effects are arrhythmias, tremors, and hypokalemia. Caution should be taken in heart failure as tachycardia may precipitate heart failure.
Anti-muscarinic agents – such as tiotropium, ipratropium, and umeclidinium are beneficial as they dry secretions of goblet cells, decrease bronchoconstriction, and inhibit excessive fluid production in bronchi.
Long-acting beta-agonists – like salmeterol and formoterol can be added, but should never be monotherapy. Necessary vaccinations for patients include pneumococcal 13-valent conjugate vaccine given initially and pneumococcal vaccine polyvalent given one year later and a yearly inactivated influenza vaccine. Smoking cessation is beneficial to combat the progression of the disease and decrease mortality.
Anticholinergics inhibit acetyl-choline- induced bronchoconstriction. SAMA includes ipratropium and tiotropium. LAMA such as tiotropium can be given once daily.
Inhaled corticosteroid (ICS) is an add-on therapy to bronchodilator in a step-up therapy. ICS includes beclomethasone, budesonide, fluticasone, etc. The common side effects are local infection, cough, and pneumonia. Oral systemic corticosteroids are used for all patients with COPD exacerbation and avoided in stable patients due to more adverse effects.
Oral Phosphodiesterase-4 inhibitors like Roflumilast act by reducing inflammation and can be added if there is severe airflow obstruction with no improvement with the above medications.
Triple inhaled therapy – (LABA+ LAMA+ ICS) has been recently approved by the FDA and is taken only once a day.
Intravenous aloha1 antitrypsin augmentation therapy – for AATD patients. The high cost and lack of availability is the main limitation of this therapy.

Supportive Therapy

Supportive therapy includes oxygen therapy and ventilatory support, pulmonary rehabilitation, and palliative care.

Routine supplemental oxygen Therapy – does not improve the quality of life or clinical outcomes in stable patients. Continuous long-term, i.e., longer than 15 hours of supplemental oxygen is recommended in COPD patients with PaO2 less than 55 mmHg (or oxygen saturation less than 88%) or PaO2 less than 59 mm Hg in case of cor pulmonale. Oxygen therapy has shown to increase survival for these patients with severe resting hypoxemia. For those who desaturate with exercise, intermittent oxygen will help. The goal is to maintain oxygen saturation greater than 90%. A major cause of hypoxemia in COPD is due to ventilation-perfusion mismatch (V/Q Mismatch), particularly in low V/Q areas.
Hypoxic vasoconstriction – of pulmonary arteries is to improve overall gas exchange efficiency. Supplemental oxygen can successfully reach the alveoli in these lungs, which prevent this vasoconstriction and thereby increasing perfusion and improving gas exchange thus resulting in improvement of hypoxemia.
Noninvasive positive pressure ventilation (NPPV) – is known to decrease morbidity and mortality in patients with acute respiratory failure and hospitalized for COPD exacerbation. It should be tried as the first mode of ventilation in patients with COPD exacerbation with respiratory failure who otherwise have no absolute contraindication as it improves gas exchange, decreases hospitalization duration, reduces work of breathing, improves VQ matching, and improves survival. If NPPV doesn’t work in in a COPD patient in a hospital setting, then the patient should be intubated and put on a ventilator.
Pulmonary rehabilitation – for patients with severe symptoms and multiple exacerbations reduces dyspnea and hospitalizations and is recommended for GOLD stages B, C, and D. Although available from the time the person is diagnosed with COPD, palliative care is typically recommended for GOLD stage D.

Management: GOLD Criteria – Low Risk

Low-risk criteria

Spirometry Mild to Moderate Severity (FEV1 >50% of predicted) AND
One or none COPD exacerbation per year AND
No hospitalizations

First-choice (intermittent symptom management)

Short-acting Beta Agonist (e.g. Albuterol) 2 puffs as needed up to every 6 hours OR
Short-acting Anticholinergic (e.g. Ipratropium) as needed up to every 6 hours

Second-choice

Long-acting Beta Agonist (e.g. Salmeterol) OR
Combined Short-acting Beta Agonist with short-acting Anticholinergic (e.g. Combivent) OR
Long-acting Anticholinergic, long-acting muscarinic (e.g. Tiotropium)
Consider as first-line agent (decreases exacerbations even in mild disease, NNT 10)
Theophylline

First-choice (long-acting symptom management)

Long-acting Beta Agonist (e.g. Salmeterol) OR
Long-acting Anticholinergic (e.g. Tiotropium)

Second-choice

Long-acting Beta Agonist (e.g. Salmeterol) AND Long-acting Anticholinergic (e.g. Tiotropium) OR
Anoro Ellipta (Umeclidinium and vilanterol) OR
Stiolto Respimat (Tiotropium and olodaterol)

Third-choice

Combined Short-acting Beta Agonist with short-acting Anticholinergic (e.g. Combivent) OR
Short-acting Beta Agonist (e.g. Albuterol) 2 puffs as needed up to every 6 hours AND/OR
Short-acting Anticholinergic (e.g. Ipratropium) as needed up to every 6 hours
Theophylline

Management: GOLD Criteria – High Risk

Spirometry Severe to Very Severe (FEV1 <50% of predicted) AND
Two or more COPD exacerbation per year or one or more hospitalizations

First-Choice (guidelines changing in 2017 to prefer the second choice, non-steroid combination)

Long-acting beta-agonist (e.g. Salmeterol) or Long-acting Anticholinergic (e.g. Tiotropium) AND
Inhaled Corticosteroid (e.g. fluticasone or Flovent)

Second-Choice

Long-acting Beta Agonist (e.g. Salmeterol) AND Long-acting Anticholinergic (e.g. Tiotropium) OR
Anoro Ellipta (Umeclidinium and vilanterol) OR
Stiolto Respimat (Tiotropium and olodaterol)

Third-Choice

Short-acting Beta Agonist (e.g. Albuterol) 2 puffs as needed up to every 6 hours OR
Short-acting Anticholinergic (e.g. Ipratropium) as needed up to every 6 hours

Other choices

Phosphodiesterase-4 Inhibitor (e.g. Roflumilast or Daliresp)
Theophylline

First-Choice (guidelines changing in 2017 to prefer the second choice, non-steroid combination)

Long-acting beta-agonist (e.g. Salmeterol) or Long-acting Anticholinergic (e.g. Tiotropium) AND
Inhaled Corticosteroid (e.g. fluticasone or Flovent)

Second-Choice

Inhaled Corticosteroid AND
Long-acting Beta Agonist (e.g. Salmeterol) AND Long-acting Anticholinergic (e.g. Tiotropium)
Alternative: Anoro Ellipta (Umeclidinium and vilanterol) once daily
Add Phosphodiesterase-4 Inhibitor (e.g. Roflumilast or Daliresp) to the first-choice regimen

Third-Choice

Short-acting Beta Agonist (e.g. Albuterol) 2 puffs as needed up to every 6 hours OR
Short-acting Anticholinergic (e.g. Ipratropium) as needed up to every 6 hours
Theophylline

Management: Stepped care of Dyspnea

Chronic intermittent symptoms
Eliminate exposures (e.g. Tobacco)

Mild: Stage I (FEV1/FVC <0.7, FEV1>80%) – Intermittent symptoms management

Short-acting Beta Agonist (e.g. Albuterol) 2 puffs as needed up to every 6 hours OR
Short-acting Anticholinergic (e.g. Ipratropium) as needed up to every 6 hours

Moderate: Stage II (FEV1/FVC <0.7, FEV1 50-80%)

Add to Stage I management
Long-acting beta-agonist (e.g. Salmeterol or Serevent) or Long-acting Anticholinergic (e.g. Tiotropium or Spiriva)
Patients benefit most during daytime active hours
1. Consider dosing only in the morning to save cost
2. However, sleep is improved

Severe: Stage III (FEV1/FVC <0.7, FEV1 30-50%)

Add to Stage I and II management (short-acting beta-agonist and long-acting beta-agonist)
Inhaled Corticosteroid (e.g. fluticasone or Flovent)
Consider using both a long-acting beta-agonist and a long-acting Anticholinergic
Long-acting Beta Agonist (e.g. Salmeterol) AND Long-acting Anticholinergic (e.g. Tiotropium) OR
Anoro Ellipta (Umeclidinium and vilanterol) OR
Stiolto Respimat (Tiotropium and olodaterol)
Low-flow oxygen at night and with exertion
Pulmonary Rehabilitation
Consider Systemic Bronchodilator – Leukotriene Receptor Antagonist (e.g. Accolate) & Theophylline

Very severe: Stage IV (FEV1/FVC <0.7, FEV1 <30%)

Add to Stage I, II and III management (short-acting beta-agonist, long-acting beta-agonist, Inhaled Corticosteroid)
Continuous Low-flow oxygen
Consider adding Phosphodiesterase-4 Inhibitor (e.g. Roflumilast or Daliresp)
Consider using both a long-acting beta-agonist and a long-acting Anticholinergic
Long-acting Beta Agonist (e.g. Salmeterol) AND Long-acting Anticholinergic (e.g. Tiotropium) OR
Anoro Ellipta (Umeclidinium and vilanterol) OR
Stiolto Respimat (Tiotropium and olodaterol)

Consider less efficacious methods for Dyspnea

Buspirone as Anxiolytic agent
Sustained-release oral Morphine 20 mg daily
Use with caution, studies are preliminary
Abernethy (2003) BMJ 327:523-

Crisis Management

Beta agonist up to 6 to 8 puffs q1-2 hours
Ipratropium Bromide up to 6 to 8 puffs q3-4 hours
Systemic Corticosteroids for 5-10 days (see below)
Theophylline

Oxygen therapy: Do not limit FIO2 in CO2 retainers

Set O2 Sat goal of 88-91%
Anticipate CO2 rise of 12 points
Consider BiPap for pH < 7.25

Management: Protocols – Exacerbation Guidelines

Do not define exacerbation severity by Spirometry
Consider Chest XRay in hospitalized patients
Prednisone 40 mg orally daily (5-day course is typical)
1. A five-day course of 40 mg daily is sufficient for most COPD exacerbations
2. Ten-day course reduces relapse rate after COPD evaluation in ER

Avoid low efficacy therapies

Mucolytic medications are not shown helpful
Chest physiotherapy is not efficacious
Theophylline not helpful in exacerbations

Maintenance Guidelines

Before Intervention
Test Spirometry
Review Patient’s symptoms
Initiate Trial of Intervention
After Intervention
Recheck Spirometry
Were Patient’s symptoms improved?

Management: Surgical Interventions

Lung transplantation & Lung Volume reduction surgery

High-Risk Surgery (high mortality)
Indicated in severe upper lobe predominant Emphysema and low post-Pulmonary Rehabilitation Exercise capacity
Improves 5-year survival in severe COPD with heterogeneous distribution of Emphysema and upper lobe predominance
Improved quality of life if BODE Index >5
The worse prognosis (increased 30-day mortality) if FEV1 <20% predicted, low DLCO or homogenous Emphysema

Management: Other Interventions

Phosphodiesterase-4 Inhibitor (e.g. Roflumilast or Daliresp)
Indicated in severe, refractory COPD with frequent exacerbations
NNT: 24 severe COPD patients to prevent 1 hospitalization per year
Beta-Blockers
1. Despite prior relative contraindication in COPD, Cardioselective Beta Blockers (e.g. Metoprolol, bisoprolol) improve COPD status
2. Associated with decreased COPD exacerbations and increased survival
3. Farland (2013) Ann Pharmacother 47(5):651-6 [PubMed]

Management: Excessive upper airway secretions

Mucolytics (e.g. Guaifenesin)

Reduces days of illness per month by 1/2 day
Doubles chance of being free of exacerbations

N-Acetylcysteine (for thick secretions)

Dose: 600-1200 mg/day in divided dosing
Intranasal Steroid, Consider if considerable airway phlegm

Therapy

Pulmonary rehabilitation. A pulmonary rehabilitation program can teach you breathing exercises and techniques that may help reduce your breathlessness and improve your ability to exercise.
Nutrition therapy. You’ll also receive advice about proper nutrition. In the early stages of emphysema, many people need to lose weight, while people with late-stage emphysema often need to gain weight.
Supplemental oxygen. If you have severe emphysema with low blood oxygen levels, using oxygen regularly at home and when you exercise may provide some relief. Many people use oxygen 24 hours a day. It’s usually administered via narrow tubing that fits into your nostrils.
Vitamin D – There is some evidence that people with emphysema can have insufficient levels of vitamin D, which is needed for healthy bones, teeth, and muscles. Your health care professional might test your vitamin D levels, especially as current government advice is that adults should have 10 micrograms of vitamin D every day.
Interventional Therapy – Lung volume reduction surgery reduces hyperinflation and improves elastic recoil, Lung transplantation when FEV1 and or DLCO is less than 20%.
Inhalers – If your COPD is affecting your breathing, you’ll usually be given an inhaler. This is a device that delivers medication directly into your lungs as you breathe in. Your doctor or nurse will advise how to use your inhaler correctly and how often to use it. If you have severe symptoms or experience a particularly bad flare-up, you may sometimes need additional treatment.
Nebulised medication – Nebulised medication may be used in severe cases of COPD if inhalers haven’t worked. This is where a machine is used to turn liquid medication into a fine mist that you breathe in through a mouthpiece or a face mask. It enables a large dose of medicine to be taken in one go. You’ll usually be given a nebulizer device to use at home after being shown how to use it.
Long-term oxygen therapy – If your COPD results in a low level of oxygen in your blood, you may be advised to have oxygen at home through nasal tubes or a mask. This can help stop the level of oxygen in your blood becoming dangerously low, although it’s not a treatment for the main symptoms of COPD, such as breathlessness. Long-term oxygen treatment should be used for at least 16 hours a day. The tubes from the machine are long, so you will be able to move around your home while you’re connected. Portable oxygen tanks are available if you need to use oxygen away from home. Don’t smoke when using oxygen. The increased level of oxygen is highly flammable and a lit cigarette could cause a fire or explosion.
Some people with COPD will benefit from ambulatory oxygen – oxygen used when you walk or are active in other ways. If your blood oxygen levels are normal while you’re resting but fall when you exercise, you may be able to have ambulatory oxygen therapy rather than long-term oxygen therapy.
Non-invasive ventilation (NIV) – If you’re taken to hospital because of a bad flare-up, you may have a treatment called non-invasive ventilation (NIV).This is where a portable machine connected to a mask covering your nose or face is used to support your lungs and make breathing easier.

Surgery

Surgery is usually only suitable for a small number of people with severe COPD whose symptoms aren’t controlled with medication.

There are three main operations that can be done:

Bullectomy – an operation to remove a pocket of air from one of the lungs, allowing the lungs to work better and make breathing more comfortable
Lung volume reduction surgery – an operation to remove a badly damaged section of the lung to allow the healthier parts to work better and make breathing more comfortable
Lung transplant – an operation to remove and replace a damaged lung with a healthy lung from a donor

These are major operations carried out under general anesthetic, where you’re asleep, and involve significant risks.

Physiotherapy Management of Emphysema

The key to management of Emphysema– is through education and systemic management. Currently, antibiotics are used at the first sign of change in sputum color ^[rx] and longterm use of antibiotics is recommended for people who experience 3 or more exacerbations a year^[rx].
Since antibiotics – do not help with the persistent inflammation in the airways, inhaled steroids are taken as an anti-inflammatory and to decrease sputum production^[rx]. Bronchodilators tend to help patients who also have co-existing COPD and asthma^[rx].
A review and a controlled study found that many people with bronchiectasis – also have a Vitamin D deficiency and prescribing Vitamin D may have an anti-inflammatory and anti-infective role^[rx]^[rx]. Physiotherapy has a very valuable role in aiding with symptoms. Since mucociliary clearance is reduced to about 15% of normal, patients tend to cough more^[rx]. Physiotherapy treatments are aimed at aiding secretion clearance, managing fatigue induced by the effort of ineffective clearance and increased coughing. The most common and effective treatments are
Active Cycle of Breathing Technique (ACBT)- is a commonly taught technique and is often used with Postural drainage and manual drainage^[rx]. Its purpose is to loosen and clear excess pulmonary secretions, improve the effectiveness of cough and to improve lung ventilation and function. It consists of 3 main stages:

- Breathing Control
- Deep Breathing Exercises or Thoracic Expansion Exercises
- Huffing or Forced Expiratory Technique (FET)^[rx]
Forced expiration technique – sometimes referred to as a huff. It is part of the ACBT but can be used alone. A huff is very effective at clearing secretions, especially when combined with other airway clearance techniques.^[rx]
Manual Therapy – is a popular treatment technique and is often used when the patient is fatigued or experiencing an exacerbation of symptoms. It describes techniques that involve external forces to the chest wall to loosen mucus and includes any combination of percussion, shaking, rib springing, vibrations and over pressure^[rx]. Because of the nature of the technique, it is contraindicated in patients that are taking anticoagulants or that have osteoporosis^[rx]. The aim of treatment is to
- Loosen secretions
- Reduce fatigue
- Increase the effectiveness of other treatment techniques

Postural Drainage (or modified postural drainage) – is an effective treatment that incorporates gravity-assisted techniques to help clear secretions from specific segments of the lungs and often requires tilting the head down to clear secretions from the middle and lower lobes.
PD is commonly used in conjunction with other techniques like ACBT percussion – coughing or huffing and studies have found using PD with these techniques produced a greater amount of sputum^[rx]^[rx]. Although PD is effective in secretion clearance it is time-consuming and often found to be less tolerated than techniques that are performed in a sitting^[rx].
Where tilting the head down is contraindicated – or not tolerated then modified postural drainage (MPD) positions can be used instead and in cases where gastroesophageal reflux disease GORD) is present and exacerbated even when using modified PD then it is suggested to use a technique that can be performed in sitting.
Autogenic Drainage is a technique – that utilizes breathing control to clear secretions from the airways. The aim is to vary the depth, rate, and location of lung volumes during respiration to move secretions from the smaller airways to the larger airways for easier expectoration. It consists of three phases:

Mobilizing (unstick) phase – involves breathing as much air out of the lungs as possible and resisting the urge to cough. During this phase, crackles may be heard.

Collecting phase – as the secretions get louder the rate and depth of the breaths change, the speed of breathing out is faster (but not too fast to stimulate a cough) and are felt more in the middle of the chest. This assists the movement of secretions from the smaller airways to the larger airways.
Clearing phase – as the secretions get louder the aim is now to take full, slow deep breaths in, followed by a fast breath out. Suppress the urge to cough and after three deep breaths huff to expel the secretions. Often the huff is enough to clear secretions but if they are ineffective this is the stage where a cough may be effective in clearing secretions.
Positive Expiratory Pressure (PEP) – is a technique that describes breathing against resistance, and can be performed either through a device or against pursed lips. It is a technique which is recommended when other techniques have not been effective or are contraindicated; it has been found to have no adverse effect of GORD.^[rx] The increase in pressure creates back pressure in the airways during expiration. This may cause a build-up of gas behind the mucus, temporarily increasing functional capacity, and improving mucus clearance.^[rx]
High-Frequency Chest Wall Oscillation – is achieved by wearing a vest that emulates chest physiotherapy. The vest applies positive pressure air pulses to the chest which causes vibrations that loosen and thin mucus, This along with an intermittent cough or huff assists with the clearance of secretions. This device allows people to perform therapy in their own time, allowing them some control and less dependence on other people.
Intrapulmonary Percussive Ventilation – is another technique that relies on a device to assist with the clearance of secretions. An intrapulmonary percussive ventilator (IPV) is a machine that delivers short bursts of air through a mouthpiece that vibrates the airway walls^[rx]. It is indicated for short-term use when other techniques are contraindicated or have proved ineffective.
Intermittent Positive Pressure Breathing(IPPB) – it is an expensive piece of equipment^[rx] and usually only used when all other clearance techniques have proved to be ineffective^[rx]. It is commonly seen in Intensive Care and gives positive pressure as the patient breathes in, and during expiration, it creates negative pressure making the cough stronger and more effective

Physical Exercise is recommended for respiratory conditions, including emphysema with the aim of improving aerobic capacity and, fitness and endurance. A study by Lee et al concluded that exercise resulted in short term improvements and had an impact on dyspnoea and fatigue, and resulted in fewer exacerbations over a 12 month period^[rx].

Complications

People who have emphysema are also more likely to develop:

Collapsed lung (pneumothorax) – A collapsed lung can be life-threatening in people who have severe emphysema, because the function of their lungs is already so compromised. This is uncommon but serious when it occurs.
Heart problems –Emphysema can increase the pressure in the arteries that connect the heart and lungs. This can cause a condition called cor pulmonale, in which a section of the heart expands and weakens.
Large holes in the lungs (bullae) – Some people with emphysema develop empty spaces in the lungs called bullae. They can be as large as half the lung. In addition to reducing the amount of space available for the lung to expand, giant bullae can increase your risk of pneumothorax.

Prevention

The best way to prevent or reduce further problems is to prevent respiratory infections by:

Practicing good handwashing methods
Brushing and flossing teeth daily, and using an antibacterial mouth rinse after meals
Keeping breathing equipment clean
Keeping your house clean and free of dust
Getting a flu shot every year
Following a doctor-prescribed exercise program
Avoiding irritants such as:
- Cigarette smoke
- Exhaust fumes
- Strong perfumes
- Cleaning products
- Paint/varnish
- Dust
- Pollen
- Pet dander
- Pollution

Additional Interventions

Chronic medical therapy includes several interventions. First, a short-acting beta-agonist such as albuterol is integral for acute shortness of breath and bronchodilation.
Long-term oxygen is a possible add-on therapy if the pO2 is < 55 or the oxygen saturation is < 88% on a six-minute walk test.
Identification and reduction of exposure to risk factors. Counseling about smoking cessation, as it is the single most important intervention that slows the progression of the disease Reduce the exposure to open cooking fires and promote efficient ventilation.
Daily oral opioids for severe COPD symptoms refractory to medical therapy. Nutritional supplementation in malnourished COPD patients
Pneumococcal vaccine 23 valent every 5 year years for COPD patients older than 65 or with other cardiopulmonary disease and Influenza vaccine for all COPD patients every year
Readmission rates can be reduced with counseling on the optimal use of metered-dose inhalers (MDI)
Exercise for all COPD patients

References

Treatment of Emphysema