Pulmonary

The Southwest Journal of Pulmonary and Critical Care publishes articles broadly related to pulmonary medicine including thoracic surgery, transplantation, airways disease, pediatric pulmonology, anesthesiolgy, pharmacology, nursing  and more. Manuscripts may be either basic or clinical original investigations or review articles. Potential authors of review articles are encouraged to contact the editors before submission, however, unsolicited review articles will be considered.

Rick Robbins, M.D. Rick Robbins, M.D.

December 2013 Pulmonary Case of the Month: Natural Progression

Robert W. Viggiano, MD

 

Department of Pulmonary Medicine

Mayo Clinic Arizona

Scottsdale, AZ

 

History of Present Illness

A 68 year old woman was seen for increased back pain in April 2012. In 2000 she had a right lower lobe lung resection for low grade adenocarcinoma, bronchoalveolar type, nonmucinous. Her mass was 2.6 cm in maximal dimension extending to but not invading the pleura. There were clear surgical margins but involvement of one bronchial node. Multiple mediastinal nodes were negative. She had back pain for many years and yearly CTs were negative for metastatic disease.

PMH, SH, FH

Other than the above there was no significant past medical history, social history or family history.

Medications

  • Non-steroidal anti-inflammatory drugs for pain
  • Nitrofurantoin for chronic urinary tract infections

Physical Examination

There was tenderness to palpation over the mid-thoracic spine and evidence of a previous thoracotomy.

Laboratory

Her complete blood count (CBC), urinanalysis, liver function tests, and calcium were all within normal limits.

Radiology

An x-ray of the chest is interpreted as unchanged from previous x-rays. 

At this point which of the following radiologic testing is not indicated?

  1. Bone scan
  2. CT scan of the chest
  3. Magnetic resonance imaging
  4. Serial chest x-rays
  5. Thoracic PET scan

Reference as: Viggiano RW. December 2013 pulmonary case of the month: natural progression. Southwest J Pulm Crit Care. 2013;7(6): . doi: http://dx.doi.org/10.13175/swjpcc155-13 PDF

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Rick Robbins, M.D. Rick Robbins, M.D.

December 2013 Pulmonary Case of the Month: Natural Progression

Robert W. Viggiano, MD 

 

Department of Pulmonary Medicine

Mayo Clinic Arizona

Scottsdale, AZ

  

History of Present Illness

A 68 year old woman was seen for increased back pain in April 2012. In 2000 she had a right lower lobe lung resection for low grade adenocarcinoma, bronchoalveolar type, nonmucinous. Her mass was 2.6 cm in maximal dimension extending to but not invading the pleura. There were clear surgical margins but involvement of one bronchial node. Multiple mediastinal nodes were negative. She had back pain for many years and yearly CTs were negative for metastatic disease.

PMH, SH, FH

Other than the above there was no significant past medical history, social history or family history.

Medications

  • Non-steroidal anti-inflammatory drugs for pain 
  • Nitrofurantoin for chronic urinary tract infections

Physical Examination

There was tenderness to palpation over the mid-thoracic spine and evidence of a previous thoracotomy.

Laboratory

Her complete blood count (CBC), urinanalysis, liver function tests, and calcium were all within normal limits.

Radiology

An x-ray of the chest is interpreted as unchanged from previous x-rays. 

At this point which of the following radiologic testing is not indicated? (click on correct answer to move to next panel)

  1. Bone scan
  2. CT scan of the chest
  3. Magnetic resonance imaging
  4. Serial chest x-rays
  5. Thoracic PET scan

Reference as: Viggiano RW. December 2013 pulmonary case of the month: natural progression. Southwest J Pulm Crit Care. 2013;7(6):318-27. doi: http://dx.doi.org/10.13175/swjpcc155-13 PDF

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Rick Robbins, M.D. Rick Robbins, M.D.

November 2013 Pulmonary Case of the Month: Dalmatian Lungs

Lewis J. Wesselius, MD 

Department of Pulmonary Medicine

Mayo Clinic Arizona

Scottsdale, AZ

  

History of Present Illness

A 36 year old woman was referred to the pulmonary clinic at Mayo Clinic Arizona. In early May 2013 she developed headache and blurred vision. She was referred to a neuroopthalmologist who diagnosed a 6th cranial nerve palsy. She had a brain MRI and lumbar puncture (LP). Both were reported as normal. She was treated with corticosteroids and improved.

She was tapered off prednisone in late May and developed discomfort in her left ear with hearing loss and tinnitus.  Some left facial asymmetry was noted.

She was treated with intra-tympanic steroid injections as well as oral steroids with some improvement. Her last dose of corticosteroids was 3 weeks prior to being seen.

At the beginning of August she developed speech and swallowing difficulties and was neurologically diagnosed with palsies in 4th, 6th, 8th, 9th, 10th and 11th cranial nerves. Other symptoms included photophobia and a non-productive cough. Two additional LPs were reported to be normal.

PMH, SH, FH

She had cervical cancer with a cone biopsy 2006 and right arthroscopic shoulder surgery. She is a nonsmoker who is a field engineer for a medical device company. She travels throughout the US extensively. There is no significant family history.

Medications

  • Zolpidem 
  • Vitamin B and D
  • Herbal remedy immunotox

Physical Examination

On neurologic exam she had blurred vision with left gaze and facial asymmetry.

Otherwise, the physical exam was unremarkable.

Laboratory

Her complete blood count (CBC) and erythrocyte sedimentation rate (ESR) were within normal limits.

 

At this point which of the following are diagnostic tests that should be ordered?

  1. Anti-neutrophil cytoplasmic antibody (ANCA)
  2. Coccidiomycosis serology
  3. Lyme disease serology
  4. Serum angiotensin converting enzyme (ACE)
  5. All of the above

Reference as: Wesselius LJ. November 2013 pulmonary case of the month: dalmatian lungs. Southwest J Pulm Crit Care. 2013;7(5):271-8. doi: http://dx.doi.org/10.13175/swjpcc130-13 PDF

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Rick Robbins, M.D. Rick Robbins, M.D.

June 2013 Pulmonary Case of the Month: Diagnosis Makes a Difference

Lewis J. Wesselius, MD1

Henry D. Tazelaar, MD2

Departments of Pulmonary Medicine1 and Laboratory Medicine and Pathology2

Mayo Clinic Arizona

Scottsdale, AZ

  

History of Present Illness

A 64 year old man from Southern Arizona was referred for a second opinion on a diagnosis of chronic eosinophilic pneumonia that was poorly responsive to corticosteroid therapy. The patient first became ill February 2012 with cough and congestion.  His wife was ill at the same time. Both were treated with antibiotics. His wife improved but he never fully recovered with ongoing symptoms of cough and some dyspnea.

He was admitted to another hospital in August 2012 due to worsening shortness of breath and pulmonary infiltrates on chest x-ray. During this admission he underwent bronchoscopy with bronchoalveolar lavage (BAL) that demonstrated 78% eosinophils. A video-assisted thorascopic (VATs) lung biopsy was done and the patient was diagnosed with chronic eosinophilic pneumonia. He was begun on therapy with high dose prednisone (80 mg/day) but had only slight improvement in symptoms.

He was followed by a pulmonologist and continued on prednisone who questioned the possible development of pulmonary fibrosis. Earlier this year he was started on mycophenolate mofetil and the dose was increased to 1000 mg bid while the prednisone was tapered to 5 mg every other day. He was also being treated with fluticasone/salmeterol 250/50 twice a day. The patient continues to have dyspnea with limited activity. His last pulmonary function testing was done in December 2012. At that time his forced vital capacity (FVC) was 51% of predicted and his diffusing capacity for carbon monoxide (DLco) was 40% of predicted.

PMH, SH, FH

He had a history of obstructive sleep apnea (OSA) and had undergone an uvulopharyngoplasty (UPPP). There was also a history of gastroesophageal reflux disease (GERD) and he had a prior Nissen fundoplication. He had a history of osteoarthritis and had undergone a right shoulder replacement.

He had a remote smoking history, a history of modest alcohol use, but no history of using recreational drugs.  He worked as an airline pilot.

His present medications included mycophenolate mofetil 1000 mg twice a day, prednisone 5 mg every other day, voriconazole 200 mg daily (started after BAL showed a few colonies of Aspergillus), and fluticasone/salmeterol 250/50 twice a day.

Physical Examination

Blood pressure 134/88 mm Hg.  Resting oxygen saturation 96%.

Chest:  bibasilar crackles but no wheezes.

Cardiovascular: the heart had a regular rhythm but no murmur.

Extremities: no clubbing or edema.

The remainder of the physical examination was unremarkable.

Chest Radiography

His chest x-ray is shown in figure 1.

Figure 1. Initial chest x-ray.

Which of the following diseases has/have been associated with increased eosinophils in bronchoalveolar lavage fluid?

  1. Interstitial lung diseases
  2. Acquired immunodeficiency syndrome (AIDS)-associated pneumonia
  3. Idiopathic eosinophilic pneumonia
  4. Drug-induced lung disease
  5. All of the above

Reference as: Wesselius WJ, Tazelaar HD. June 2013 pulmonary case of the month: diagnosis makes a difference. Southwest J Pulm Crit Care. 2013;6(6):247-54. PDF 

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Rick Robbins, M.D. Rick Robbins, M.D.

September 2012 Pulmonary Case of the Month: The War on Drugs

Sudheer Penupolu, MD

Philip J. Lyng, MD

Lewis J. Wesselius, MD

 

Department of Pulmonary Medicine

Mayo Clinic Arizona

Scottsdale, AZ

 

History of Present Illness

A 69 year old woman was seen with a three day history of nonproductive cough and shortness of breath.

PMH, SH and FH

She has a past history of atrial fibrillation and hypothyroidism.

Her present medications include:

  • Diltiazem
  • Amiodarone
  • Aspirin
  • Levothyroxine
  • Multi vitamins

There is a 20 pack-year smoking history but she quit in 1998. She is employed as a law school professor.

Physical Examination

Her physical examination is normal.

Chest X-ray

Her admission chest x-ray is shown in Figure 1.

An electrocardiogram showed normal sinus rhythm.

Which of the following is the most likely cause of the patient’s clinical picture?

  1. Viral bronchitis
  2. Exacerbation of COPD
  3. Pneumonia
  4. Congestive heart failure
  5. Drug reaction

Reference as: Penupolu S, Lyng PJ, Wesselius LJ. September 2012 pulmonary case of the month: the war on drugs. Southwest J Pulm Crit Care 2012;5:107-14. (Click here for a PDF version of the article)

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Rick Robbins, M.D. Rick Robbins, M.D.

COPD Exacerbations: An Evidence-Based Review

Richard A. Robbins, MD

Phoenix Pulmonary and Critical Care Research and Education Foundation

Gilbert, AZ

Abstract

COPD exacerbations are a major source of COPD morbidity, mortality and cost. Exacerbations tend to become more frequent as COPD progresses with the cause assumed to be infectious in about 80% of patients. The mainstay of management is inhaled bronchodilators with judicious use of oxygen, antibiotics, corticosteroids and assisted ventilation. Recent studies have examined strategies to prevent exacerbations of COPD including use of macrolide antibiotics and self-management education.

Definition of COPD Exacerbations

There is no standard definition of COPD exacerbations. However, the workshop, “COPD: Working Towards a Greater Understanding”, proposed the following working definition in 2000: “A sustained worsening of the patient’s condition, from the stable state and beyond normal day-to-day variations, that is acute in onset and necessitates a change in regular medication in a patient with underlying COPD” (1). This seems to be the mostly commonly used definition today. Others have defined exacerbations specifically in terms of increased dyspnea, sputum production, or sputum purulence (2,3).  However, exacerbations of COPD comprise a range of symptoms making specific medical complaints difficult to include in a comprehensive definition (1).

Epidemiology of COPD Exacerbations

Exacerbations reduce quality of life, speed disease progression, and increase the risk of death (4,5). Furthermore, exacerbations resulting in hospitalization account for the major cost of COPD (6). The best predictor of future exacerbations is a history of frequent exacerbations (7). As many as 50% of exacerbations are not reported to physicians and 3-16% require hospitalization (8). Hospital mortality is 3-10% and mortality of ICU admission is 15-24%.  Half of the patients hospitalized will require readmission in the next 6 months (8).

Frequency of exacerbations increase with increasing severity of COPD. In a systematic review, patients with mild COPD had a mean of 0.82 exacerbations per year (9). The rates increased to 1.17, 1.61, and 2.01 in patients with moderate, severe, and very severe disease, respectively.

COPD is a lung disease that is frequently associated with other comorbid conditions. These comorbidities affect health outcomes, increase the risks of hospital admission, increase the risk of death, and account for more than 50% of use of health-care resources for COPD (10,11). The relationship of certain comorbidities with COPD is not surprising because of COPD’s connection with cigarette smoking and aging. Cigarette smoking is not only a major risk factor for COPD, but also for cardiovascular disease, osteoporosis, and lung cancer and all are more frequently seen in COPD patients (12). Aging is a major risk factor for most chronic diseases including COPD. Almost half of all COPD patients aged 65 years or over have at least three chronic medical disorders (13). Consistent with this concept, a cluster analysis indicated that age rather than FEV₁ accounted for most of the comorbidities and symptoms (14). Furthermore physical inactivity, which is frequently observed in COPD, has been linked to aging and to major comorbidities (15-17). The presence of comorbidities likely explains why clinical outcomes in COPD only weakly correlate with the FEV1 (18).

Another common denominator between COPD and its major comorbidities is systemic inflammation. Increased concentrations of circulating cytokines (tumor necrosis factor α and interleukins 6 and 8), adipokines (leptin, ghrelin), and acute-phase proteins (C-reactive protein, fibrinogen) are seen in COPD and its comorbid diseases (19). In several studies biomarkers of systemic inflammation have been observed in patients with COPD, particularly when disease is severe and during acute exacerbations (19,20).  Whether these systemic markers spill over from the lungs into the systemic circulation or merely reflect the proinflammatory state is unclear (21). However, none of these systemic inflammatory markers have received generalized acceptance in predicting or diagnosing exacerbations.

Etiology of COPD Exacerbations

Several causes of exacerbations have been suggested for patients with COPD, including heart failure, pneumonia, pulmonary embolism, non-adherence to inhaled medication, or inhalation of irritants, such as tobacco smoke or particles (19). However, the most frequent cause cited by most is viral or bacterial infection (19). In patients admitted to hospital with COPD exacerbations, viruses, bacteria or both, were detected in 78% of cases (22). The exacerbations associated with infection were more severe than those in patients with non-infectious causes (22). However, the 80% frequency of infectious causes may be an overestimation.  The accepted gold standard for the diagnosis of bacterial causes is the isolation of a potentially pathogenic bacterium by sputum culture. However, sputum cultures are neither sensitive nor specific. An additional difficulty is that a substantial proportion of patients with stable COPD have bacterial colonization (23). These include the organisms most commonly associated with exacerbations: H. influenzae, S. pneumoniae, and M. catarrhalis.

Viruses are thought to account for 15–25% of all infective exacerbations, particularly human rhinovirus, influenza, parainfluenza, and adenoviruses (19). Infection with both viruses and bacteria are seen in 25% of patients with exacerbations who are admitted to hospital (22).  Viral exacerbations are strongly correlated with colds at presentation, high frequency of exacerbations, and severe respiratory symptoms during exacerbations. Experimental evidence suggests that upper respiratory tract infections can lead to lower respiratory tract inflammation and symptoms. COPD patients experimentally infected in the upper respiratory tract with rhinovirus developed lower respiratory symptoms, airflow obstruction, systemic inflammation, and inflammation in their airways (24). In addition to inducing lower respiratory inflammation and symptoms, viral infections may facilitate subsequent bacterial infection. Although viral infections are usually self-limiting, secondary bacterial infection may prolong exacerbations (24).

Gastroesophageal reflux has been suggested to play an important role in a number of respiratory diseases and has been independently associated with increased frequency of COPD exacerbations (7). Similarly, sleep-apnea has also been shown to be an independent predictor of COPD exacerbations (25).

No serum marker of bacterial or viral infection in COPD exacerbations has gained general acceptance. However, measurements of procalcitonin and C-reactive protein have been suggested as predictors of bacterial infection since both have been shown to predict results to antibiotic therapy (26,27). Increased concentrations of serum interferon-γ-inducible protein10 were useful in identifying rhinovirus infection in one study (28).

A recent publication by Bafadhel et al. (29) measured biomarkers in sputum and serum from a total of 145 COPD patients. Four distinct biologic exacerbation clusters were identified. These were bacterial-, viral-, or eosinophilic-predominant, and a fourth associated with limited changes in the inflammatory profile termed “pauciinflammatory.” Of all exacerbations, 55%, 29%, and 28% were associated with bacteria, virus, or a sputum eosinophilia. The biomarkers that best identified these clinical phenotypes were sputum IL-1β, serum CXCL10, and percentage peripheral eosinophils. Future research may establish the usefulness of these as well as other biomarkers in predicting and diagnosing infectious causes of COPD exacerbations.

Diagnostic Interventions in COPD

Clinical judgment is necessary in evaluating the need for hospital admission and which diagnostic tests need to be performed. Patients with mild exacerbations may be managed as outpatients with no diagnostic testing. Patients with more severe exacerbations may need diagnostic testing and hospitalization when appropriate.

Chest x-rays have been found to be useful in evaluation of COPD exacerbations. Data from observational studies show that in 16% to 21% of the chest radiographs change patient management (30-32). Arterial blood gases are helpful in assessing the severity of an exacerbation and the degree of hypoxemia and hypercarbia. The later is particularly important in identifying patients that are likely to require hospitalization and additional ventilatory support (33). Although spirometry and peak flows may be useful in identifying an exacerbation, available evidence does not support their routine measurement to guide therapy during an exacerbation (33).

Treatment of COPD Exacerbations

Therapies for treatment of COPD exacerbations and their evidence basis are summarized in Table 1.  

Table 1. Therapies for COPD exacerbations.

Oxygen. In my practice inappropriate empiric use of high doses of oxygen was becoming increasingly problematic. High doses of oxygen can result in absorption atelectasis, increased ventilation-perfusion mismatch and increased hypercarbia. The British Thoracic Society (BTS) has published guidelines that oxygen is a treatment for hypoxemia, not breathlessness or dyspnea (34). Oxygen has not been shown to affect breathlessness in nonhypoxemic patients, and therefore, empirically increasing oxygen administration for breathlessness when the oxygen saturation is satisfactory is ineffective and potentially harmful. BTS suggests oxygen should be prescribed to achieve a target saturation of 94-98% for most acutely ill patients or 88-92% for those at risk for hypercapnic respiratory failure. Hypercapnic patients at high risk for respiratory failure may usually be safely managed with oxygen saturations as low as 85-88%.

In support of the concept that empiric use of high flow oxygen may do more harm than good, Austin et al. (35) compared nontitrated high flow oxygen with titrated oxygen in the prehospital setting in COPD patients with an acute exacerbation. Those administered oxygen to a titrated oxygen saturation of 88-92% had reduced mortality, hypercapnia and respiratory acidosis compared to those treated with nontitrated oxygen at 8-10 L/min.

It appears to make little difference if oxygen is administered by nasal cannula or Venturi mask. In a study comparing patients assigned to receive oxygen through a Venturi mask or nasal prongs oxygen saturation improved to the same extent without any significant effect upon arterial carbon dioxide tension or pH (36).

Bronchodilators. The first line of treatment for a COPD exacerbation is to increase the frequency of short-acting inhaled beta 2-agonists and/or anticholinergics. However, there are only four randomized, controlled trials comparing beta 2-agonists with anticholinergics and all analyzed short-term effects (37). Overall, the available data show similar FEV1 improvement with either bronchodilator. Although use of both in combination is common, there does not appear to be strong evidence to support this approach (37,38). There is very limited data on use of long-acting beta 2-agonists (formoterol and salmeterol) or long-acting anticholinergics (tiotropium) in treatment of exacerbations of COPD.  

Metered-dose inhaler (MDI) and small volume nebulizers appear to be equivalent in the acute treatment of adults with airflow obstruction (39). It is assumed that the cost of delivery is lower with MDIs due to decreased nursing or respiratory therapist time needed to administer the drugs. Spacer devices have been used with an MDI in most studies.

Thirty years ago methylxanthines, such as aminophylline, were the mainstay therapy for COPD exacerbations. However, these drugs have largely fallen out of favor. A meta-analysis on use of methylxanthines in acute COPD exacerbation did not find any evidence to support their use (40). Methylxanthines do not significantly improve FEV1 during COPD exacerbations and have a narrow therapeutic window with numerous potential side effects including nausea, vomiting, headache, arrhythmias, and seizures.

Corticosteroids. Corticosteroids significantly reduce the risk of treatment failure and length of hospital stay (41). Although the optimal dosage and length of therapy are unknown, the largest trial used methylprednisolone 125 mg intravenously every 6 hours for 72 hours (42). Two weeks of oral prednisone after intravenous therapy was as efficacious as 8 weeks (40). In a retrospective review among patients hospitalized with COPD exacerbations, oral therapy was not associated with worse outcomes compared to high-dose intravenous therapy (43).  

Antibiotics. As previously mentioned, infectious etiologies may account for as many as 80% of the acute COPD exacerbations (19,22). Therefore, it is reasonable to expect that antibiotics would be efficacious. Studies going back to the 1980’s show a significant benefit of antibiotic treatment, with a success rate of 68% for the antibiotic group compared to 55% for the placebo group (2). Subsequent meta-analyses have confirmed these findings (33,44,45). Patients with more severe exacerbations are more likely to benefit from antibiotics than those with milder exacerbations. The presence of purulent sputum may be predictive of the presence of active infection and identify those patients most likely to benefit from antibiotic therapy (46).       

Controversy exists regarding the choice of the newer, broad-spectrum antibiotics compared to the older, traditional antibiotics. Some studies have found significantly higher persistence or worsening of symptoms in patients treated with first-line agents (amoxicillin, cotrimoxazole, tetracyclines, or erythromycin) compared to second or third-line agents (amoxicillin/clavulanate, azithromycin, or ciprofloxacin) (47,48). On the other hand, other studies suggest that host factors rather than antibiotic choice are the primary determinants of treatment failure (49). It may be that the anti-inflammatory effects of certain antibiotics such as the macrolides or tetracyclines account for some of the variability (50,51). Recently a concern has been raised regarding macrolides causing QT prolongation and a very small, but significant, increase in cardiovascular death (52). Tetracyclines such as doxycycline may represent an alternative to the macrolides since they do not cause QT prolongation

The duration of antibiotic therapy is also controversial. However, a recent meta-analysis by El Moussaoui et al. (53) suggests that 5 days of therapy is as effective as longer durations of therapy.

Other Pharmacologic Agents. A variety of mucolytics, mucokinetics, expectorants, antiproteases, antioxidants and immunostimulants have been proposed to treat COPD exacerbations but do not have well established clinical efficacy (54). A review of mucolytic agents in acute exacerbations of COPD suggested there was no evidence that they shortened the duration of the exacerbations or improved the FEV1 (55). However, the analysis did suggest that mucolytics might improve symptoms compared to controls. In the nonacute COPD setting, a meta-analysis has found a small reduction in the number of acute exacerbations and days of illness when mucolytics were routinely used (55).

Chest Physiotherapy. During acute COPD exacerbations mechanical percussion of the chest as applied by physical/respiratory therapists is ineffective in improving symptoms or lung function, although it may increase the amount of sputum expectorated (38,56). Furthermore, there may be a transient worsening in FEV1 after chest percussion (38).

Noninvasive Positive-Pressure Ventilation (NIPPV). Noninvasive positive pressure ventilation (NIPPV) is probably the largest therapeutic advance in treating COPD exacerbations in the past 20 years. Meta-analysis has found not only a reduction in the need for intubation and mechanical ventilation with NIPPV, but also a reduction in the risk of death (57). Patients hospitalized for exacerbations of COPD with rapid clinical deterioration should be considered candidates for NIPPV. However, there are no standardized criteria to predict which patients will benefit. Therefore, careful observation, usually in the intensive care unit, is necessary should NIPPV fail.

Heliox. Helium is a low density inert gas that in combination with oxygen (heliox) has been used as an additive treatment in upper airway obstructions and other causes of respiratory failure. The rationale for its use during COPD exacerbations is to diminish respiratory effort, peak pressure, and intrinsic positive end expiratory pressure. A meta-analysis in 2002 evaluated the limited literature on the use of heliox in acute COPD exacerbations and concluded that there is insufficient data to support its use (58). A recent randomized trial failed to show heliox reduced intubation rates, duration of noninvasive ventilation, length of stay, complications or 28-day mortality (59). Furthermore, heliox has the disadvantage of coming in fixed concentrations of oxygen sometimes making its use problematic especially in hypercarbic patients.

Reduction of COPD Exacerbations

Continuous therapies for reduction of COPD exacerbations are shown in Table 2.

Table 2. Continuous therapies for reduction of COPD exacerbations.

Bronchodilators. Many of the therapies that treat COPD exacerbations have been tested to determine if chronic use might prevent exacerbations. The best evidence is for the long-acting bronchodilators. Two large randomized controlled trials have confirmed that a combination of a long-acting beta agonist (salmeterol) with an inhaled corticosteroid (fluticasone) or a long-acting anticholinergic (tiotropium) reduce exacerbations (60,61). Both appear to appear to be similarly efficacious in exacerbation reduction (62).

Research is being done with several new bronchodilators to treat COPD. Roflumilast, an oral specific phosphodiesterase 4 inhibitor, reduced the frequency of exacerbations by 17% in patients with severe or very severe COPD (63). Reductions are also seen with the addition of roflumilast to salmeterol or tiotropium (64). Several new, once-daily, long-acting beta-agonists and anticholinergics are under development and being tested alone or in combination. Indacaterol, a once daily beta-agonist, is the first of these once daily beta-agonists to become clinically available. It is anticipated that these will also reduce exacerbations similar to salmeterol/fluticasone or tiotropium.

Since both long-acting anticholinergics and long-acting beta-agonists/inhaled corticosteroids reduce exacerbations, it is logical that a combination might be additive in reducing exacerbations of COPD. However, a recent study suggests that addition of salmeterol/fluticasone to tiotropium was ineffective compared to tiotropium alone in reducing exacerbations although FEV1 and albuterol use were improved (65).

Inhaled corticosteroids. Addition of inhaled corticosteroids to long-acting bronchodilators in COPD is controversial. A recent meta-analysis by Spencer et al. (66) suggests that there was no reduction in exacerbations with addition of an inhaled corticosteroid to a long-acting beta-agonist. Furthermore, addition of corticosteroids was associated with a higher incidence of pneumonia. On the other hand, a retrospective, observational study suggested that the use of inhaled corticosteroids prior to a COPD exacerbation resulted in reduced mortality (67). In elderly COPD patients without a history of an exacerbation addition of inhaled corticosteroids was not associated with improved outcomes (68). This suggests that if inhaled corticosteroids are efficacious, they may only be efficacious in patients with a history of exacerbations.

Antibiotics. Continuous treatment with some antibiotics, particularly macrolides, reduces exacerbations. A randomized controlled trial with erythromycin reduced exacerbations by 35% compared to placebo (69). In a more recent study, treatment with azithromycin for one year lowered exacerbations by 27% (70). Although the mechanism(s) accounting for the reduction in exacerbations is unknown, current concepts suggest the reduction is likely secondary to the macrolides’ anti-inflammatory properties. However, concern has been raised about a very small, but significant, increase in QT prolongation and cardiovascular deaths with azithromycin (52). In addition, the recent trial with azithromycin raised the concern of hearing loss which occurred in 25% of patients treated with azithromycin compared to 20% of control (70). An alternative to the macrolides may be tetracyclines such as doxycycline, which also possess anti-inflammatory properties but do not lengthen QT intervals nor cause hearing loss (50).

Immunizations. Until recently, the only pneumococcal vaccine approved for use in adults in the United States and Europe was the 23-valent pneumococcal polysaccharide vaccine (PPSV23). This is despite no randomized, controlled trial of the vaccine showing a reduction in clinical outcomes (71). Recently a 7-valent diphtheria-conjugated pneumococcal vaccine has been approved for use in adults. This conjugated vaccine induces greater serotype-specific immunoglobulin G (IgG) and functional antibody than does PPSV23 for up to 2 years after vaccination (72). Whether these increases in surrogate markers will translate into lower rates of COPD exacerbations is unknown.

It appears, from the limited number of studies performed, that influenza vaccine reduces exacerbations in COPD patients (73). The effect appears to be due to a reduction in exacerbations occurring three or more weeks after vaccination due to influenza. There is a mild increase in transient local adverse effects with influenza vaccination, but no evidence that vaccination increases exacerbations immediately after administration.

Other approaches. Pulmonary rehabilitation and self-management education programs reduce hospitalization for COPD exacerbations (74, 75).  A recent study found increased mortality with COPD self-management education (76) but this was not confirmed by meta-analysis (75). Lung volume reduction surgery, an approach to severe COPD, was surprisingly found to reduce exacerbation frequency (77). The cause of the reduction is unknown but may reflect the benefits of reducing hyperinflation. A specific effect of long-term oxygen in appropriate patients on reducing exacerbations has not been demonstrated. However, there is evidence that underuse of long-term oxygen therapy results in increased hospital admissions (78).  Vitamin D levels have been found to be reduced in some patients with COPD. However, treatment with vitamin D did not improve exacerbation rates except those with severe vitamin D deficiency (serum 25-[OH]D levels <10 ng/mL) (79).

Clinical Approaches

Outpatient. Based on the available evidence, my approach was to prescribe antibiotics and prednisone for home use during an exacerbation to most patients with severe or very severe COPD (FEV1 < 50% predicted) and patients with moderate COPD who had been hospitalized or had frequent exacerbations. Most severe and very severe COPD patients were also treated with long-acting bronchodilators and an albuterol rescue inhaler. Many were treated with a combination of both a long-acting beta agonist (salmeterol or formoterol) with an inhaled corticosteroid and a long-acting anticholinergic. Patients with mild exacerbations were treated as outpatients with antibiotics (usually doxycycline) and oral prednisone. Prednisone was given as a fixed dose (usually 15 mg/day) for 7-14 days since tapering with short-term use is unnecessary (80). Some patients with frequent exacerbations were prescribed chronic doxycycline therapy in hopes of reducing exacerbations. Most received pulmonary rehabilitation and therapy for smoking cessation if needed.

It is usually appropriate to initiate discussions about end of life planning with a COPD patient as an outpatient (81). Autonomy of the patient is the predominant ethical principle that drives end-of-life care. These discussions should prepare patients with advanced COPD for a life-threatening exacerbation of their chronic disease. Discussions should include ICU admission and intubation and mechanical ventilation using data where appropriate to assist in the decision. Pulmonary rehabilitation provides an important opportunity to assist advance care planning for patients with moderate-to-severe COPD. Patients with COPD sometimes qualify for formal hospice services, especially when they are having repeated exacerbations and poor clinical function. Opportunities for hospice care are frequently neglected for patients coming to the end of life with COPD. Morphine is the drug of choice for the relief of dyspnea and in selected patients chronic positive pressure ventilation may be used (82).

Inpatient. My rationale was that if a patient was sick enough to be in the hospital, he was sick enough to receive bronchodilators, antibiotics, and corticosteroids. Chest x-rays and arterial blood gases were routinely performed on hospitalized patients. Those with hypercarbia and respiratory acidosis were usually admitted to the ICU and especially those with an exacerbation sufficiently severe to require noninvasive positive pressure ventilation. Oxygen was titrated to maintain the SpO2 at 88-92%, and if severe respiratory acidosis was present, oxygen was titrated to a SpO2 of 85-88%.  Albuterol by MDI was used as often as needed to control symptoms, sometimes as often as every 1-2 hours with careful monitoring. Ipratropium by MDI was added if the patients were not receiving tiotropium. If the patients were taking long-acting bronchodilators as outpatients, these were continued during inpatient hospitalization. Doxycycline was used as an antibiotic in the absence of culture evidence or x-ray evidence to choose an alternative. Corticosteroids were given as methylprednisolone 125 mg IV every 6 hours for 3 days and then oral prednisone for another 2 weeks. Rarely, methylxanthines were added in those very severe patients who failed to clinically improve in 1-3 days. Those who were not on long-acting bronchodilators were started on one or both prior to discharge to reduce the number of future exacerbations. Patients were followed up in the outpatient clinic about 2-3 weeks after hospital discharge.

Conclusions

COPD exacerbations are common and can often be managed as outpatients with careful planning and education in self-management. Communication between the patient and physician regarding end of life planning is useful in planning future care during a severe exacerbation. Most patients can be managed with inhaled bronchodilators, antibiotics and corticosteroids. Titration of oxygen or administration of NIPPV usually requires hospitalization, especially in hypercarbic patients.

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Reference as: Robbins RA. COPD exacerbations: an evidence-based review. Southwest J Pulm Crit Care 2012;5:36-51. (Click here for a PDF version of the manuscript)

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Rick Robbins, M.D. Rick Robbins, M.D.

Treatment of Coccidioidomycosis-associated Eosinophilic Pneumonia with Corticosteroids

Joshua Malo, MD

Yuval Raz, MD 

Linda Snyder, MD

Kenneth Knox, MD

 

University of Arizona Medical Center

Department of Medicine

Section of Pulmonary, Allergy, Critical Care, and Sleep Medicine

Tucson, AZ 85724

 

Abstract

Pulmonary coccidioidomycosis is a common cause of community-acquired pneumonia in endemic areas of the southwestern United States. The clinical spectrum of this disease ranges from an asymptomatic presentation to severe disease with ARDS and hypoxemic respiratory failure. Despite evidence supporting the use of corticosteroids for severe pulmonary disease in other fungal infections, there is currently no established role for this therapy in coccidioidomycosis infections. Peripheral eosinophilia is a common feature of coccidioidomycosis; however, pulmonary eosinophilia is rarely reported. In the setting of pulmonary eosinophilia of other etiologies, corticosteroid therapy has been demonstrated to have a role in reducing the inflammatory response and leading to a more rapid resolution of hypoxemic respiratory failure. We report a case of a patient with primary pulmonary coccidioidomycosis complicated by severe pulmonary eosinophilia that demonstrated rapid improvement after the initiation of corticosteroid therapy.

Case Report

A 71-year-old man presented to the emergency room in Tucson, Arizona with a one-week history of fever, cough, and malaise. The patient’s symptoms began while returning from a trip to northern California. A chest radiograph ordered by the primary care physician demonstrated a right upper lobe consolidation (Figure 1) and azithromycin was prescribed. Fevers persisted along with worsening cough over the next three days, and the patient presented for further evaluation.

Figure 1. Admission radiograph demonstrating right upper lobe airspace disease

Medical history was remarkable for viral cardiomyopathy requiring placement of an ICD after an episode of sudden cardiac death in 2006. An episode of S. bovis bacteremia occurred 4 months prior to the current presentation and was treated with a course of cefazolin. There is no known personal or family history of atopic disease. There is no history of tobacco use or significant occupational exposures. The patient had been living in Arizona during the preceding year and had no other recent travel history, dust, or environmental exposures.

On physical exam, temperature was 38.8°C and pulse oximetry saturation was 90 percent on room air. The patient was in moderate respiratory distress with rales auscultated in the right upper lung zone. Subsequent laboratory examination revealed a PaO2 of 69 mmHg on 4 liters-per-minute of oxygen via nasal cannula. A metabolic panel showed elevated transaminases and his initial leukocyte count was 11.8 x 103/mL with differential including 5% eosinophils.

The patient was admitted to the medical ward and treated with vancomycin, cefepime, and moxifloxacin for pneumonia caused by a potentially resistant organism. Fluconazole was started on the third hospital day for empiric treatment of primary pulmonary coccidioidomycosis. A CT angiogram of the chest showed bilateral multilobar pneumonia (Figure 2).

Figure 2. CT angiogram of the chest demonstrating multilobar consolidation of the right lung

The patient deteriorated and required intubation for severe hypoxemia two days later. A bronchoalveolar lavage revealed Coccidioides spherules on cytological examination. Liposomal amphotericin B was initiated, which led to the development of oliguric renal failure necessitating hemodialysis. Initial Coccidioides serology was negative, however sputum and BAL cultures demonstrated C. immitis. Despite antifungal therapy his pulmonary status worsened with progressive bilateral pulmonary infiltrates and worsening hypoxemic respiratory failure (Figure 3).

Figure 3. CXR demonstrating progressive bilateral alveolar opacities consistent with ARDS.

In addition, he had a steadily increasing peripheral eosinophilia reaching a maximum of 40 percent with a leukocyte count of 14.8 x 103/mL despite the absence of any signs of disseminated coccidioidomycosis. A repeat BAL again showed Coccidioides spherules and eosinophils of 40 and 56 percent from the right middle lobe and lingula, respectively. Methylprednisolone 40mg IV three times daily was started with a decline in blood eosinophils to one percent within 24 hours. Chest radiographs and A-a gradient rapidly improved over the next 3 days leading to successful extubation. The patient was transitioned to oral fluconazole and prednisone and discharged from the hospital in good condition two weeks later.

At the follow-up six weeks after initial presentation, he remains on fluconazole and prednisone 15mg daily with no signs of disseminated coccidioidomycosis and is continuing a gradual reduction of prednisone dosage.

Discussion

Coccidioidomycosis is caused by either of 2 species of the dimorphic fungus Coccidioides. Endemic regions are present in North and South America, with the majority of cases within the United States arising in Arizona and California. Although peripheral eosinophilia is a commonly reported finding (1), pulmonary eosinophilia has rarely been described.

Acute eosinophilic pneumonias may be idiopathic or a secondary inflammatory response to various infections or environmental exposures. In regions where endemic fungal infections are common, differentiating between eosinophilic pneumonias of idiopathic versus infectious etiology is vital in order to avoid inappropriate therapy and its adverse consequences. A review of the literature concerning pulmonary coccidioidomycosis and concurrent pulmonary eosinophilia demonstrates only 9 prior case reports. Corticosteroid therapy was used for treatment of the pulmonary eosinophilia in only 3 of these cases, 2 of which resulted in death from disseminated coccidioidal infection (1-3). One case ended in spontaneous resolution of disease without antifungals or corticosteroids leading the authors to suggest a conservative approach with corticosteroids due to the risk for dissemination (4).

In our case, there was progressive clinical deterioration despite ten days of treatment with appropriate antifungal regimen, leading to our decision to treat with corticosteroids. The immediate decrease in peripheral eosinophilia in conjunction with the rapid clinical improvement leads us to the conclusion that corticosteroids were beneficial in the resolution of his acute respiratory failure. The clinical response observed is similar to that expected in idiopathic acute eosinophilic pneumonia which supports the notion that the eosinophilic response, as opposed to the primary infection, was primarily responsible for our patient’s severe hypoxemia.

There remains a risk for disseminated disease. In the cases cited in which patients died of dissemination, antifungal therapy preceding corticosteroid therapy was not described. Due to the risk of underlying pulmonary coccidioidomycosis in endemic regions, corticosteroid therapy for eosinophilic pneumonia should only be considered in the setting of severe hypoxemic respiratory failure and once adequate antifungal therapy has been initiated.

According to recent guidelines there is no role for corticosteroid therapy in the treatment of coccidioidomycosis due to a lack of convincing data for efficacy and safety (5). There is precedent for treating severe pulmonary disease caused by other fungal infections, such as histoplasmosis and blastomycosis, with corticosteroids. We suggest that there is a role for the use of corticosteroid therapy in the setting of progressive respiratory failure due to coccidioidomycosis with associated pulmonary eosinophilia that has failed conventional antifungal therapy.

References

  1. Echols RM, Palmer DL, Long GW. Tissue eosinophilia in human coccidioidomycosis. Rev Infect Dis 1982;4:656–664.
  2. Lombard CM, Tazelaar HD, Krasne DL. Pulmonary eosinophilia in coccidioidal infections. Chest 1987;5:734–736
  3. Swartz J, Stoller JK. Acute Eosinophilic Pneumonia Complicating Coccidioides immitis Pneumonia: A Case Report and Literature Review. Respiration 2009;77:102–106
  4. Whitlock WL, Dietrich RA, Tenholder MF. Acute eosinophilic pneumonia (letter). N Engl J Med 1990;322:635
  5. Limper AH, Knox KS, Sarosi GA, et al. Treatment of fungal infections in adult pulmonary and critical care patients. Am J Respir Crit Care Med 2011;183:96–128

The authors report no conflicts of interest

Address correspondence to:     Joshua Malo, MD

                                             University of Arizona Medical Center

                                             Department of Medicine    

                                             Section of Pulmonary, Allergy, Critical

                                             Care and Sleep Medicine

                                             Tucson, AZ 85724

                                             E-mail: jmalo@deptofmed.arizona.edu

 

Reference as: Malo J, Raz Y, Snyder L, Knox K. Treatment of coccidioidomycosis-associated eosinophilic pneumonia with corticosteroids. Southwest J Pulm Crit Care 2012;4:61-66. (Click here for a PDF version of the manuscript) 

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