Re-expansion pulmonary oedema

High-resolution CT findings of re-expansion pulmonary edema

Objective

To describe the high-resolution CT (HRCT) findings of re-expansion pulmonary edema (REPE) following a thoracentesis for a spontaneous pneumothorax.

Materials and Methods

HRCT scans from 43 patients who developed REPE immediately after a thoracentesis for treatment of pneumothorax were retrospectively analyzed. The study group consisted of 41 men and two women with a mean age of 34 years. The average time interval between insertion of the drainage tube and HRCT was 8.5 hours (range, 1-24 hours). The patterns and distribution of the lung lesions were analyzed and were assigned one of the following classifications: consolidation, ground-glass opacity (GGO), intralobular interstitial thickening, interlobular septal thickening, thickening of bronchovascular bundles, and nodules. The presence of pleural effusion and contralateral lung involvement was also assessed.

Results

Patchy areas of GGO were observed in all 43 patients examined. Consolidation was noted in 22 patients (51%). The geographic distribution of GGO and consolidation was noted in 25 patients (58%). Interlobular septal thickening and intralobular interstitial thickening was noted in 28 patients (65%), respectively. Bronchovascular bundle thickening was seen in 13 patients (30%), whereas ill-defined centrilobular GGO nodules were observed in five patients (12%). The lesions were predominantly peripheral in 38 patients (88%). Of these lesions, gravity-dependent distribution was noted in 23 cases (53%). Bilateral lung involvement was noted in four patients (9%), and a small amount of pleural effusion was seen in seven patients (16%).

Conclusion

The HRCT findings of REPE were peripheral patchy areas of GGO that were frequently combined with consolidation as well as interlobular septal and intralobular interstitial thickening.

Pleural manometry

The goals of therapeutic thoracentesis are to remove the maximum amount of pleural fluid to improve dyspnea and to facilitate the diagnostic evaluation of large pleural effusions. Pleural manometry may be useful for immediately detecting an unexpandable lung, which may coexist when any pleural fluid accumulates. Pleural manometry may improve patient safety when removing large amounts of pleural fluid. The basics of pleural space mechanics are discussed as they apply to the normal pleural space and to pleural effusion associated with expandable and unexpandable lung. This article also discusses the instrumentation required to perform bedside manometry, how manometry may decrease the risk of re-expansion pulmonary edema when large amounts of fluid are removed, and the diagnostic capabilities of manometry.

Reexpansion pulmonary edema following patent ductus arteriosus ligation in a preterm infant

Reexpansion pulmonary edema (RPE) is rare and usually follows rapid reexpansion of a collapsed lung. We report on a preterm infant who developed pulmonary edema within an hour of surgical ligation of patent ductus arteriosus (PDA). There were no other cardiac anomalies, fluid overload or airway obstruction to explain the change in clinical status. With supportive treatment the patient's condition became stable and was extubated within 48 hours. Lung retraction for better field exposure is often needed when performing PDA ligation in preterm infants. Reinflation of a retracted lung is thought to be the cause of our patient's pulmonary edema. We conclude that RPE, although uncommon, may occur following surgical ductal ligation and that clinicians should be aware of such a possible complication.

What size chest tube? What drainage system is ideal? And other chest tube management questions

Chest tubes and their accompanying pleural drainage units continue to present challenging questions regarding their optimal use. Appropriate chest tube size selection to accommodate the clinical situation is key, especially in the setting of large pleural air leaks lest a tension pneumothorax ensue. Connection of an appropriate pleural drainage unit to the chest tube is equally important to obviate impeding airflow after successful evacuation by the chest tube. Large-bore chest tubes are generally required for patients with pneumothoraces, regardless of etiology, if the patient is mechanically ventilated, or for patients requiring drainage of viscous pleural liquids such as blood. Smaller bore tubes may be adequate in patients with limited production of pleural air or of free-flowing pleural liquid. Chest tubes may be removed successfully at either end expiration or end inspiration, and potentially as soon as </=200 mL/fluid output per day is achieved. Additional prospective studies are needed to provide evidence-based answers to the many questions remaining regarding chest tube placement, ongoing management, and removal.

Cardiac output increases prior to development of pulmonary edema after re-expansion of spontaneous pneumothorax

Pulmonary edema following reexpansion of spontaneous pneumothorax is an uncommon complication. The underlying mechanism of this condition is unclear. We report the hemodynamic characteristics in a series of 7 male patients with spontaneous large (>50%) pneumothoraces of > or = 24 h and correlate the changes with reexpansion pulmonary edema (REPE). A pulmonary artery floatation catheter was inserted and hemodynamic data were obtained before therapeutic chest tube insertion, 1 h after chest tube insertion and the following day. Four (57%) patients developed REPE. There was a tendency for larger pneumothorax to develop REPE. Capillary wedge pressure did not change significantly 1 h after the insertion of chest tube in all our patients. Cardiac output increased significantly in patients who developed REPE compared to those who did not (+ 1.06 l/min vs -0.27 l/min; P = 0.03) 1 h after insertion of chest tube. One patient did not develop pulmonary edema despite having a large (> 80%) pneumothorax. His cardiac output did not rise 1 h after chest tube insertion. REPE is not an uncommon complication following chest tube drainage in patients with large and long-standing pneumothorax. The increase in cardiac output after chest tube insertion may be associated with subsequent development of REPE.

Heliox therapy for pneumothorax: new indication for an old remedy

STUDY OBJECTIVE

To evaluate a new method of treating pneumothorax: having the subject breathe a helium/oxygen mixture (heliox).

METHODS

We conducted a prospective, randomized, controlled study of nine white rabbits weighing 2.5 to 3.5 kg. Experimental pneumothorax was induced in all rabbits with the injection of 20 mL of air into the pleural space. The rabbits then breathed heliox, oxygen, or room air for 2 hours. Chest radiography was performed 5 minutes after induction of pneumothorax, then at 1 and 2 hours. We determined pneumothorax size on the chest radiograph by measuring the interpleural distance and expressing it as a percentage of the hemithorax.

RESULTS

At 2 hours the pneumothoraces in the heliox group had diminished from 17.50% +/- .50% to .17% +/- .29%; in the oxygen-breathing group they had diminished from 17.83% +/- 2.25% to .50% +/- .50%; and in the air-breathing group they had diminished from 18.50% +/- 3.12% to 17.33% +/- .25%. The difference between the air-breathing and the oxygen-breathing or heliox-breathing animals was highly significant; no significant difference was found between the oxygen and heliox groups (P<.0001).

CONCLUSION

Heliox, a safe and convenient therapy, is as effective as oxygen in reducing the volume of an experimental pneumothorax in rabbits.

Reexpansion pulmonary edema occurring after thoracoscopic drainage of a pleural effusion

Video assisted thoracoscopic drainage and tale pleurodesis was used to treat a recurrent pleural effusion in a 60 year-old woman undergoing major gynecologic surgery. She developed reexpansion pulmonary edema immediately following surgery. Several important risk factors that were present in this patient are discussed. In addition to almost, complete collapse of the underlying lung for several weeks, thoracoscopy resulted in manipulations and rapid re-inflation of the underlying lung, which further increased the risk to the patient.

Catastrophic circulatory collapse following re-expansion pulmonary oedema

Re-expansion pulmonary oedema is a recognised but rare complication following the rapid drainage of a large pleural effusion or pneumothorax [1,2], usually occurring on the side of re-inflation. The pathogenesis of the pulmonary oedema is poorly understood but is thought to be due to micro-vascular shearing resulting in neutrophil activation and adhesion to the vascular endothelium resulting in increased micro-vascular permeability [3-7]. Few reports appear in the literature of invasive haemodynamic monitoring following this catastrophe. We describe a patient who sustained fatal pulmonary oedema arising in the contralateral lung, with pulmonary flow catheter data documenting the initial circulatory collapse following the aspiration of a massive pulmonary effusion.

Re-expansion pulmonary oedema following spontaneous pneumothorax

Re-expansion pulmonary oedema may occur after chest tube drainage of pneumothorax and can give rise to cardiopulmonary manifestations which range from the mild to the severe. In order to evaluate the prevalence and the clinical manifestations of this complication, all patients with spontaneous pneumothorax managed with chest tube drainage were evaluated over an 8-yr period (1986-1994). A chest radiograph was performed routinely in all patients within 4 h of tube insertion. Lung expansion and the appearance of infiltrates within the lungs were investigated specifically. Re-expansion oedema was noted in three of 320 episodes (0.9%). Two of the three patients needed rapid and extensive clinical treatment.

Bilateral reexpansion pulmonary edema following unilateral pleurocentesis

Acute ipsilateral pulmonary edema following reexpansion of the lung after pleurocentesis or pneumothorax is a well described entity. We report the unusual occurrence of bilateral pulmonary edema following unilateral pleurocentesis in a young male without heart disease. Various hypotheses regarding the mechanism of reexpansion pulmonary edema include increased capillary permeability due to hypoxic injury, decreased surfactant production, altered pulmonary perfusion and mechanical stretching of membranes. This case suggests that forces leading to ipsilateral reexpansion pulmonary edema also affect the contralateral lung.

Evaluation of reexpansion pulmonary edema following unilateral pneumothorax in rabbits and the effect of superoxide dismutase

We investigated the lung injury that occurs following reexpansion of a unilateral pneumothorax and determined the effect of superoxide dismutase (SOD) infused immediately prior to reexpansion on this injury. After 7 days of at least 80% right pneumothorax, rabbits received intravenous infusions of either SOD (n = 7), heat-inactivated SOD (n = 1), or vehicle (n = 7) immediately before lung reexpansion. Lung injury was assessed by measuring the systemic white cell counts, pulmonary blood volumes, extravascular albumin, extravascular lung water, wet/dry weight ratios, and histology 2 h after reexpansion. The reexpanded lung showed increased extravascular albumin, extravascular lung water and wet/dry weight ratios with decreased blood volumes compared to the uninjured lung. SOD delayed the onset of leukopenia and neutropenia at 3 and 7 min after reexpansion, but the white cell counts had decreased to the same level in both groups by 30 min. SOD had no effect on the degree of injury after 2 h. While a single bolus of SOD given immediately before reexpansion delayed the onset of this injury, it did not affect the injury that subsequently developed in the lung.

Changes in pulmonary microvascular permeability accompanying re-expansion oedema: evidence from dual isotope scintigraphy

The pathophysiological mechanism of pulmonary oedema following rapid re-expansion of a collapsed lung is poorly understood. It has been suggested that the period of collapse or subsequent reinflation produces an increase in pulmonary microvascular permeability. To investigate this, the pulmonary accumulation of the plasma protein transferrin was measured by radiolabelling it in vivo with indium-113m. Plasma protein accumulation was calculated after correcting the accumulation of transferrin for changes in intrathoracic blood distribution by simultaneously monitoring technetium-99m labelled red blood cells. Functional images of plasma protein accumulation were constructed for the lung fields on a pixel by pixel basis. Investigations were performed on 14 subjects after drainage of a pleural effusion (n = 9) or evacuation of a pneumothorax (n = 5), and on 11 control subjects. Plasma protein accumulation was greater over the regions of lung re-expansion (-0.1-9.6, mean 2.9 x 10(-3)/min) than over the corresponding region of the contralateral lung (-1.2-0.8, mean 0.01 x 10(-3)/min; p less than 0.001). Patients who had undergone re-expansion procedures also had significantly greater plasma protein accumulation than normal controls. Nine of the 14 patients in the re-expansion group had clearly identifiable areas of increased plasma protein accumulation that corresponded to the part of the lung that had been re-expanded; no regional abnormalities were recorded in the control group. These results suggest that the reinflated lung displays abnormal microvascular permeability.

Reexpansion pulmonary edema

Unilateral reexpansion pulmonary edema (RPE) is a rare complication of the treatment of lung collapse secondary to pneumothorax, pleural effusion, or atelectasis. Although RPE generally is believed to occur only when a chronically collapsed lung is rapidly reexpanded by evacuation of large amounts of air or fluid, in this review 15 of 47 cases of RPE available for assessment occurred when the pulmonary collapse was of short duration or when the lung was reexpanded without suction. The pathogenesis of RPE is unknown and is probably multifactorial. Implicated in the etiological process of RPE are chronicity of collapse, technique of reexpansion, increased pulmonary vascular permeability, airway obstruction, loss of surfactant, and pulmonary artery pressure changes. Since the outcome of RPE was fatal in 11 of 53 cases reviewed (20%), physicians treating lung collapse must be aware of the possible causes and endeavor to prevent the occurrence of this complication.

Diagnosis and treatment of malignant pleural effusion

Pleural effusion is a common and important complication of malignancy which may at times be difficult to diagnose or treat. Its well recognized association with numerous diseases plus the limitations of our usual diagnostic tests may occasionally cause difficulty. In the oncology patient there are a number of common medical problems associated with the development of pleural effusion which frequently coexist with the malignancy. Pleural effusion may be a presenting or late sign of cancer, and when recurrent can be a vexing symptomatic problem. Fortunately, an increasing number of effective diagnostic and therapeutic modalities are available which, when judiciously applied, facilitate our approach.

Reexpansion hypotension. A complication of rapid evacuation of prolonged pneumothorax

Three cases of hypotension are described that followed rapid evacuation of persistent unilateral pneumothorax. Common features included the presence of a pneumothorax for approximately one week before treatment commenced and profuse unilateral reexpansion edema, a rising hematocrit reading, hypotension, and anuria after evacuation of the pneumothorax in spite of a relatively normal pulmonary capillary wedge pressure. In one case, cardiac output was measured and found to be low (1.54 and 1.65 L/min/sq m), with a pulmonary capillary wedge pressure of 10 to 14 mm Hg. Death due to cardiovascular collapse occurred in one patient; ischemic colitis, acute renal failure, disseminated intravascular coagulation, and ischemic necrosis of both humeral heads occurred in another. The cases presented and the literature reviewed suggest that cardiovascular compromise was the end result of the combined effects of intravascular volume depletion and myocardial depression.

Re-expansion pulmonary oedema: a potentially serious complication of delayed diagnosis of pneumothorax

Re-expansion pulmonary oedema may develop if diagnosis and treatment of pneumothorax are delayed. This condition may be fatal if inappropriately managed.

Unilateral pulmonary edema after drainage of a spontaneous pneumothorax: case report and review of the world literature

Unilateral pulmonary edema has been associated with a variety of clinical disorders including post re-expansion of a pneumothorax. We present a case of unilateral pulmonary edema following chest tube drainage of a spontaneous pneumothorax. A literature review of this complication is reported, the pathophysiology explored and therapeutic measures examined.

Pulmonary edema as a presenting feature of sleep apnea syndrome

Patients with sleep apnea syndrome may present with many types of cardiopulmonary abnormalities. Acute pulmonary edema, however, either as a part, or as the presenting feature, of the sleep apnea syndrome has not been reported to our knowledge. A 20-year-old obese woman with no history of cardiopulmonary disease presented twice to the emergency room because of sudden onset of shortness of breath. Each time her chest roentgenogram showed bilateral pulmonary edema. On nocturnal polysomnographic recording, the patient had obstructive apneic episodes; the longest apneic episode lasted 132 seconds. Complete resolution to her symptoms occurred following tracheostomy.

Re-expansion pulmonary edema: evidence for increased capillary permeability

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Unilateral pulmonary oedema: a case report

We have presented a case of unilateral pulmonary oedema which we feel is secondary to obstruction of the right main bronchus during spontaneous respiration. An anode tracheal tube was introduced through a tracheostomy during operation in a man with pre-existing pulmonary and cardiac disease. At the end of the anaesthetic, acute obstruction to ventilation of the right main bronchus developed with the tube still in place and the patient breathing spontaneously. The obstruction was relieved, by repositioning of the tracheal tube, but not before the patient developed right unilateral pulmonary oedema.

Two unexpected deaths from pneumothorax

Two patients with primary spontaneous pneumothorax died despite intensive treatment. In the first the pneumothorax had been present for 10 days, and, after insertion of a chest drain, pulmonary oedema developed unilaterally, followed by cardiac arrest. She was resuscitated, but later died of a tension pneumothorax on the other side, probably due to cardiac massage and artificial ventilation. In the second patient, after insertion of a chest drain, mediastinal emphysema spread to the head and neck, causing fatal obstruction of the hypopharynx.

Experimental evaluation of reexpansion pulmonary edema

Reexpansion pulmonary edema following pneumothorax is clinically uncommon but occasionally life threatening. This study documents the functional and anatomical abnormalities that occur when a collapsed lung is reexpanded. Right pneumothorax was created through open tube thoracostomy in 30 goats. The animals were divided into six groups by duration of pneumothorax (24, 48, or 72 hours) and technique of reexpansion (waterseal vs 10 cm H2O suction). Arterial blood gases and alveolar-arterial oxygen tension difference (A-aDO2) were analyzed before pneumothorax and after reexpansion. Each lung was reexpanded for 2 hours, chest roentgenograms were obtained, and both lungs were removed. The left lung served as the control. Both lungs were checked for surfactant activity and pulmonary extravascular water volume (PEWY). Light and electron microscopy were also performed. Anatomical and functional changes were present in the reexpanded lung after relief of pneumothorax. Both increased time of collapse and suction reexpansion tended to correlate with increased PEWV, decreased surfactant and arterial PO2, and increased A-aDO2.

Unilateral pulmonary oedema after bilateral pneumothorax

A case history of unilateral pulmonary oedema which occurred in a patient who had recently re-expanded bilateral pneumothoraces is presented.