Michael B Gotway MD¹ and Yasmeen M Butt MD²

¹Departments of Radiology and ²Laboratory Medicine, Division of Anatomic Pathology

Mayo Clinic-Arizona

Scottsdale, Arizona USA

History of Present Illness

A 50-year-old woman presents with a history of chronic dyspnea and cough, becoming particularly problematic following COVID-19 infection 4 months prior to presentation. While she did experience significant periodic oxygen desaturations during her COVID-19 infection, she was not hospitalized for this illness. The patient also reported wheezing in the previous few weeks. 

Past Medical History, Family History and Social History

The patient’s past medical history was also notable for gastroesophageal reflux disease as well as both Coombs positive and iron deficiency anemia. She reports a history of asthma, well controlled with inhaler use.

The patient’s past surgical history included adenoidectomy, cholecystectomy, and gastric laparoscopic band placement.

Her medications included prednisone (20 mg daily), dextroamphetamine-amphetamine, furosemide, omeprazole, fluoxetine, zolpidem (Ambien), daily Bactrim, occasional Loratadine (Claritin). She also utilized an albuterol inhaler and Fluticasone-based (both Flonase and Breo Ellipta) inhalers.

The patient is a former smoker, ½ pack-per day for 26 years, having quit 11 years prior to presentation. She also reported a history of vaping (agent inhaled unclear) for 8 years, quitting 3 years earlier. She has no known allergies. She drinks alcohol socially and denied illicit drug use.

Physical Examination

The patient’s physical examination showed her temperature to be 99°F with normal pulse and respiratory rate but her blood pressure elevated at 160/90 mmHg. She was obese (263 lbs., BMI= 41). Bilateral basal rales were noted at her examination, but no other abnormal physical examination findings were detected.

Laboratory Evaluation

The patient’s room air pulse oximetry was 85%. A complete blood count showed an upper normal white blood cell count at 1.9 x10⁹/L (normal, 4.5 – 11 x10⁹/L). Her hemoglobin and hematocrit values were 10.7 gm/dL (normal, 12 – 16 gm/dL) and 37.1% (normal, 36 – 46%). The patient’s serum chemistries and liver function studies were entirely normal. The patient had an elevated anti-nuclear antibody titer at 1:320. An echocardiogram noted diastolic dysfunction but normal left ventricular contractility.

Frontal chest radiography (Figure 1) was performed.

Figure 1. Frontal chest radiography.

Which of the following statements regarding this chest radiograph is accurate? (Click on the correct answer to be directed to the second of 11 pages)

1. Frontal chest radiography shows normal findings
2. Frontal chest radiography shows marked cardiomegaly
3. Frontal chest radiography shows mediastinal lymphadenopathy
4. Frontal chest radiography shows pleural effusion
5. Frontal chest radiography shows multifocal peribronchial consolidation

Figure 1. Two axial images from a thoracic CT angiogram with intravenous contrast upon admission demonstrates ground-glass opacities in the left upper and bilateral lower lobes.

Figure 2.  Axial images from noncontrast CT 19 days later show progression with necrosis and cavitation with areas of pleural dehiscence and loculated hydropneumothorax formation.

A 31-year-old man with a self-reported history significant for active methamphetamine and OxyContin use (last use of methamphetamine the same day with confirmation on urine drug screen) presented to the hospital with several hours of dyspnea. Having gone into cardiac arrest shortly after, he received several rounds of epinephrine and CPR and was intubated before spontaneous circulation returned. Bedside ultrasound revealed global hypokinesis with left ventricular ejection fraction of 10 to 15%, trivial pericardial effusion, and a moderate left pleural effusion. Chest CT (Figure 1) revealed segmental to subsegmental pulmonary emboli in the left lower lobe and ground-glass opacities in the left upper and bilateral lower lobes. He was treated as septic shock with Vancomycin and Cefepime, eventually speciating methicillin-sensitive Staphylococcus aureus in respiratory culture. Due to difficulty liberating the patient from the ventilator, he underwent tracheostomy tube placement. Chest x-ray on hospital day 18 showed a large left partially loculated hydropneumothorax, for which a left thoracostomy tube was placed. The next day repeat CT chest without contrast (Figure 2) showed persistent moderate left lung volume loss with tethering of the lateral and separate anterior margin of the left upper lobe to the costal pleural margin. A dense consolidation of the left lung base had progressed to developing irregular cavitary spaces with air-fluid level. There was a dehiscence of the cavitary space with the posterior left pleura.  The right upper lobe showed extensive tree-in-bud ground-glass opacities and consolidation. The right lower lobe showed necrosis with intrapulmonary cavitary spaces/air-fluid levels. There was associated focal dehiscence of the parenchyma along the posterior cavity with the pleura. Patient had developed bilateral cavitary lung lesions with persistent bilateral hydropneumothoraces.

Typical findings of amphetamine induced lung injury can include ground-glass opacities as seen here. Worldwide prevalence of amphetamine use ranged between 0.3-1.3% for those aged 15-64 in 2009 (1). Crystal meth refers to the pure form of d-methamphetamine hydrochloride that can be smoked and inhaled as heated vapor as well. It can also be administered intravenously. Other amphetamines include MDMA, methyl methcathinone (commonly referred to as bath salts), and methylenedioxyamphetamine. Neural catecholamine reuptake is blocked, and neurotransmitter is expunged into the synaptic cleft. Additionally, serotonin and dopamine reuptake blockade and increased release take place.

With inhalation, there is higher percentage uptake, faster peak time, and slower clearance in the lungs compared to other organs as evidence by data from positron emission tomography. Time to peak concentration is the same between inhalation and intravenous use. Laboratories that produce amphetamines in the United States of America reduce L-ephedrine or D-pseudoephedrine either over red phosphorous with hydrochloric acid or with liquid ammonia and lithium. Therefore, they pose risks of contamination. Red phosphorous is flammable and causes smoke inhalation injury. Other solvents used also contribute to respiratory illness including pulmonary edema and mucous membranes irritation (1).

Typical respiratory symptoms from illicit drug use, including amphetamine use, include dyspnea, cough, dark sputum, and chest pain. Mechanisms include toxic effects on the respiratory system, coronary artery constriction, and impaired coronary artery oxygen delivery leading to chest pain. Dyspnea is a primarily a result of ventilation-perfusion mismatch from vasospasm. Bronchospasm is precipitated by airway mucosal irritation. Mucosal ulceration and burns as well as subsequent diffuse alveolar capillary injury lead to hemoptysis.  Cardiogenic pulmonary edema stems from the same causes of chest pain as well as acute hypertension and myocardial ischemia. Noncardiogenic pulmonary edema is a result of alveolar epithelial and endothelial damage.

As compared to cocaine, amphetamines have lower rates of barotrauma including pneumothorax, pneumopericardium, and pneumomediastinum, however these are still significant. There have been reports of MDMA-related epidural pneumatosis and retropharyngeal emphysema (1). Air dissects along fascial planes when alveoli are injured and travels up the pulmonary vascular sheath into the mediastinum, pericardium, and between the parietal and visceral layers.  When inhaled, coughing, and performing a Valsalva maneuver predispose the patient to this complication (2). Additionally, pneumothorax is more common with exertion shortly after consumption. Attempts at intravenous administration along the chest, supraclavicular regions, and internal jugular veins increase risk of pneumothorax (3). Hemothorax and pseudoaneurysm have been documented as well (2).

Kia Ghiassi DO¹, Colin Jenkins MD¹, Prateek Juneja DO²

^1,2University of California Riverside, Riverside, CA USA

²Inspira Health, Vineland, NJ USA

References

1. Tseng W, Sutter ME, Albertson TE. Stimulants and the lung : review of literature. Clin Rev Allergy Immunol. 2014 Feb;46(1):82-100. [CrossRef] [PubMed]
2. Nguyen ET, Silva CI, Souza CA, Müller NL. Pulmonary complications of illicit drug use: differential diagnosis based on CT findings. J Thorac Imaging. 2007 May;22(2):199-206. [CrossRef] [PubMed]
3. Gotway MB, Marder SR, Hanks DK, et al. Thoracic complications of illicit drug use: an organ system approach. Radiographics. 2002 Oct;22 Spec No:S119-35. [CrossRef] [PubMed]