Figure 1. Venous contrast study demonstrating thrombosis and flow obstruction at the thoracic outlet (arrow). 

A 22-year-old right-handed man developed acute swelling of his right upper extremity following a weekend of vigorous physical military training. There was no associated pain or numbness. Physical examination demonstrated edema of the right arm. Radial and ulnar pulses were intact, and neurological exam was normal. Venous doppler examination demonstrated thrombus in the subclavian-axillary venous system. A confirmatory venous contrast study was performed (Figure 1), followed by catheter directed lysis.  Effort related thrombosis of the subclavian vein secondary to mechanical compression at the thoracic outlet is known as Paget-Schroetter Syndrome (1). Current treatment commonly includes catheter directed clot lysis and an arbitrary three-month period of systemic anticoagulation, followed by surgical resection of the first rib (2). Post-operative balloon angioplasty of the involved venous segment improves long-term results (3). This patient underwent successful lysis, was discharged on oral rivaroxaban, and has been referred to thoracic surgery for consideration of rib resection.

Charles Van Hook MD and Ken Hirasaki MD

Longmont United Hospital

Longmont, Colorado USA

References

1. Kucher N. Deep-vein thrombosis of the upper extremities. N Engl J Med. 2011;364:861-9.[CrossRef] [PubMed]
2. Engelberger RP, Kucher N. Management of deep vein thrombosis of the upper extremity. Circulation. 2012;126:768-73. [CrossRef] [PubMed]
3. Illif KA, Doyle AJ. A comprehensive review of Paget-Schroetter syndrome. J Vasc Surg. 2010;51:1538-47. [CrossRef] [PubMed]

Cite as: Van Hook C, Hirasaki K. Medical image of the week: Paget-Schroetter syndrome. Southwest J Pulm Crit Care. 2018;16(3):156. doi: https://doi.org/10.13175/swjpcc031-18 PDF 

Figure 1. Axial CT view shows the thrombus in the pulmonary vein (arrows) and collateral formation.

Figure 2. Coronal view of thoracic CT angiography  showing thrombus in the pulmonary vein (arrow).

A 71-year-old woman with chronic lymphocytic leukemia and remote left lower lobe pneumonectomy presented to the emergency department from an outpatient clinic with symptoms of cough, progressive shortness of breath, and fatigue for 2 weeks.  Pertinent physical examination findings included adequate oxygen saturation at room air, known II/VI systolic mitral murmur with radiation through the precordium, and a well-healed left lower lobe pneumonectomy scar.  Imaging was remarkable for acute pulmonary venous thrombosis (PVT) of the left inferior pulmonary vein with involvement of several tributary veins (Figures 1 and 2). Given the rarity of PVT, treatment guidelines have yet to be established (1); however, consensus appears to be systemic anticoagulation, thrombectomy, or resection (1-3).  Therefore, the patient was initially placed on a heparin drip upon admission and was discharged on an oral anticoagulant.

Pulmonary vein thrombosis (PVT) is a rare condition only described through case reports, that is potentially life threatening and presents with nonspecific symptoms. Common inciting events are lung transplantation, pneumonectomy (typically early after surgery and mainly left upper lobe pneumonectomy), radiofrequency ablation complication, malignancy (either lung or metastatic), idiopathic and atrial fibrillation (1-3). 

Close clinical follow up is necessary as life-threatening complications can occur, such as gangrene of the lung (which can occur if there is no collateral circulation from the intercostal veins) or embolic stroke (3). Current literature review suggests CT or MRI as imaging modality of choice for tracking regression or resolution of disease. TEE may also be used to assess for extension of thrombi into the left atrium (1,3).

Jessica Vondrak, MD and Bonnie Barbee, MD

Department of Internal Medicine

Banner University Medical Center

Tucson, AZ USA

References

1. Chaaya G, Vishnubhotia P. Pulmonary Vein Thrombosis: A Recent Systematic Review. Cureus. 2017 Jan 23;9(1):e993. [CrossRef] [PubMed]
2. Selvidge SD, Gavant ML. Idiopathic pulmonary vein thrombosis: detection by CT and MR imaging. AJR AM J Roentgenol. 1999 Jun;172(6):1639-41. [CrossRef] [PubMed]
3. Porres DV, Morenza OP, Pallisa E, Rogue A, Andreu J, Martinez M. Learning from the pulmonary veins. Radiograhpics. 2013 Jul-Aug;33(4):999-1022. [CrossRef] [PubMed]

Cite as: Vondrak J, Barbee B. Medical image of the week: pulmonary vein thrombosis. Southwest J Pulm Crit Care. 2017;14(5):228-9. doi: https://doi.org/10.13175/swjpcc048-17 PDF 

Michael B. Gotway, MD and John K. Sweeney, MD

Department of Radiology

Mayo Clinic Arizona

Scottsdale, Arizona USA

Clinical History: An 86-year-old man with a previous history of transcatheter aortic valve implantation 1 year earlier, coronary artery disease status-post coronary artery bypass grafting surgery 12 years earlier, atrial fibrillation on warfarin, and pacemaker placement 8 years earlier presented with altered mental status.

The patient’s white blood cell count was borderline elevated at 10.3 x 10³/mcl (normal, 4.8 – 10.8 x 10³/mcl)  and hyponatremia was noted (serum sodium = 129 mEq/L, normal =  136 – 145 mEq/L). The patient’s anticoagulation profile was within the therapeutic range (INR = 1.4), and the platelet count was normal. Oxygen saturation on room air was normal. The patient’s medication list included warfarin, digoxin, aspirin, metoprolol, montelukast, and atorvastatin.

Frontal chest radiography (Figure 1) was performed.

Figure 1. Frontal (A) and lateral (B) chest radiography.

Which of the following statements regarding the chest radiograph is most accurate? (Click on the correct answer to proceed to the second of eight pages)

1. Frontal chest radiography shows a cavitary lung mass
2. Frontal chest radiography shows focal consolidation suggesting aspiration pneumonia
3. Frontal chest radiography shows increased pressure edema
4. Frontal chest radiography shows malposition of the patient’s left subclavian pacemaker
5. Frontal chest radiography shows rib fractures

Cite as: Gotway MB, Sweeney JK. April 2017 imaging case of the month. Southwest J Pulm Crit Care. 2017;14(4):141-52. doi: https://doi.org/10.13175/swjpcc042-17 PDF

Figure 1. Panels A & B: thoracic CT scan showing multiple pulmonary emboli (arrows). Panel C: frontal chest radiograph showed extensive left lung opacification most dense in the left upper lobe. Panel D: frontal chest radiograph taken 3 weeks later showing mild volume loss of the left upper lobe with a large lucency suggestive of cavitation (arrow). Panel E: thoracic CT scan confirming the cavitation.

A 49 year old man with a history of COPD presented to the ER with the sudden onset of chest pain at 3:30 AM waking him from sleep. His pain was left sided, felt like broken ribs, and was worse with deep inspiration. He acknowledged some shortness of breath which was worse over baseline for the past couple days without cough or hemoptysis. The patient was tachycardic but comfortable with SpO2 saturation 98% on 2 liters. He had trace edema and pleurisy. Laboratory evaluation was unremarkable except for a WBC count 13,000 X 10⁶ cells/L. Chest x-ray was unremarkable but thoracic CT scan showed pulmonary emboli (PE) involving left upper and lower lobar arteries (Figure 1A and 1B, arrows). Anticoagulation was started and the patient experienced increasing shortness of breath, worsening oxygenation and fever to 102ºF. On Day 2, frontal chest radiograph showed extensive left lung opacification most dense in the left upper lobe (Figure 1C). Hemoglobin dropped from 12 to 9.8 g/dL suggesting alveolar hemorrhage. He improved over the next week but low grade fevers persisted and a chest x-ray taken 3 weeks later showed mild volume loss of the left upper lobe with a large lucency suggestive of cavitation (Figure 1D, Arrow). Thoracic CT confirmed a cavitary lesion in the left apex in the region of prior thrombus with adjacent consolidated atelectasis within a background of emphysema (Figure 1E).  The patient was lost to follow up after 6 months of anticoagulation.

Pulmonary infarction is relatively uncommon, occurring in less than 10% of PE, due to dual and collateral blood supply to the lung. Cavitary infarcts are even less common (4% in autopsy studies) and are more likely in those with pulmonary venous hypertension (1). Cavitary infarcts are more likely to occur when the infarct size in larger than 4 cm and most often occurs in the mid and upper lung zones. Despite alveolar hemorrhage, anticoagulation should be continued.

Kenneth S. Knox, MD and Veronica A. Arteaga, MD

Divisions of Pulmonary and Critical Care Medicine and Thoracic Imaging

University of Arizona

Tucson, AZ

Reference 

1. Libby LS, King TE, LaForce FM, Schwarz MI. Pulmonary cavitation following pulmonary infarction. Medicine (Baltimore). 1985;64(5):342-8. [CrossRef] [PubMed]

Reference as: Knox KS, Arteaga VA. Medical image of the week: PE with infarct and pulmonary cavitation. Southwest J Pulm Crit Care. 2014;9(6):333-4. doi: http://dx.doi.org/10.13175/swjpcc158-14 PDF