Airway complications after pulmonary resection

Airway complications following pulmonary resection remain a challenging problem. A high degree of clinical suspicion, contrasted CT imaging, and early reoperation are crucial in preserving viable lung parenchyma following the anatomic compromise of lobar torsion. Likewise, early recognition and expeditious drainage of the pleural space in the setting of bronchial dehiscence may help prevent the aspiration pneumonia and consequent respiratory failure that is the leading cause of death in this patient population; A variety of interventions to manage stump dehiscence are possible, but successful management still remains difficult and requires an individualized approach. Attention to technical details and avoidance of extensive dissection and tension should yield acceptably low rates of postoperative stenosis following bronchoplastic resection. These common themes of precise surgical technique, vigilance in the perioperative period, and classic sound judgment in addressing problems effectively and expeditiously remain pivotal in the minimization of sequelae from morbid airway complications.     

Acute lung injury after pulmonary resection

Primary Acute Lung Injury (ALI) after lung resection (or "post-pneumonectomy pulmonary edema") is a rare form of acute respiratory failure characterized by dyspnea, hypoxemia, diffuse infiltrates on chest radiogram, and rapid evolution often unresponsive to therapy. ALI occurs almost exclusively following pneumonectomy, within 3 days from surgery and without a preceding cause. Factors implicated in its pathogenesis may include excessive fluid administration, alveolar injury during one-lung ventilation, pulmonary hypertension, and impaired lymph drainage. There is no specific therapy. Suggested measures in the perioperative care include the meticulous maintenance of physiological stability, judicious fluid restriction, and the limitation of ventilatory volumes and pressures.     

Rapid occurrence of pulmonary aspergillosis after pulmonary wedge resection

A 61-year-old man with diabetes mellitus undertook wedge resection of pulmonary tuberculoma in the left upper lobe. He was discharged uneventfully. However, he became febrile with productive cough five weeks after the discharge, and was readmitted. Imaging studies showed a cavitary lesion at the formerly resected site and multiple infiltrates in the other lobes. A diagnosis was rapidly deteriorating pulmonary aspergillosis. While medical treatments helped his general condition to improve, pulmonary shadows remained unchanged. Finally, we successfully treated him firstly, by performing left upper lobectomy and secondly, by treating multiple infiltrates with postoperative medical treatments. Multiple infiltrates improved gradually and diminished one month after surgery. He remains well without relapse for ten years after surgery.     

Natriuretic peptides and the dialysis patient

The natriuretic peptide family consists of four structurally similar, but genetically distinct molecules with pronounced cardiovascular and renal actions. They are counterregulatory hormones playing an important role in fluid volume homeostasis. Atrial natriuretic peptide (ANP) and B-type natriuretic peptide (BNP) cause diuresis, natriuresis, and vasodilatation. C-type natriuretic peptide (CNP) has antimitogenic effects and causes vascular smooth muscle relaxation. Dendroaspis natriuretic peptide (DNP) shares many of the actions of ANP and BNP, but its function in humans is not yet fully understood. Natriuretic peptides have been extensively investigated as biochemical markers of the fluid state. Levels are elevated in disease conditions characterized by fluid overload and are closely related to survival in various cardiac disease states. In the dialysis population, BNP correlates significantly with cardiac function, whereas ANP is sensitive to volume changes during dialysis. However, changes in concentration do not predict achievement of euvolemia, and short half-life, combined with complicated assay techniques, make ANP a less than satisfactory tool for assessing hydration. BNP is a superior prognosticator for risk stratification in dialysis patients, and serial estimations will help in the identification of occult cardiac disease.     

Successful thrombolysis for massive pulmonary embolism after pulmonary resection

We report the successful use of thrombolysis for acute massive pulmonary embolism 2 days after right lower lobectomy for bronchial adenocarcinoma. Pulmonary angiography revealed extensive clot unsuitable for surgical embolectomy. A bolus infusion of recombinant tissue plasminogen activator produced an immediate improvement in the patient’s hemodynamic state. There was substantial blood loss requiring the transfusion of 21 units of blood over the postoperative period. The patient made a successful recovery and remained well at 1 year.     

Long-term pulmonary function after major lung resection

The function of the remaining lungs after major lung resection may be a determinant of the early postoperative outcome, as well as the late postoperative quality of life of the patient. Thus, extensive efforts have been made to accurately estimate the postoperative pulmonary function using a variety of methods: the segment counting method is utilized in patients without parenchymal diseases, while the functional lung imaging technique may be useful in patients with heterogeneous anatomical lung diseases. The postoperative pulmonary function is influenced not only by the extent of parenchymal resection, but also by various other factors, such as the site of resection, the mode of thoracotomy, the severity of pulmonary emphysema and/or the postoperative progression of pulmonary fibrosis. Although thoracoscopic surgery or segmental resection can lessen the extent of chest wall damage or the extent of parenchymal resection compared with conventional operations, the resulting functional benefits do not last. Interestingly, the postoperative pulmonary function continues to improve during the first postoperative year as if the remaining lungs grow, although the cause(s) of this compensatory response of the remaining lungs remains unclear. Such an ability of the remaining lung to compensate for the lost lung function may eventually determine the late postoperative pulmonary function.     

Management of air leak after pulmonary resection

Objective: We prospectively evaluated the efficacy of water seal in the management of air leak after pulmonary resection. Methods: Eighty-seven patients who underwent lobectomy were enrolled. Air leak was qualitatively described on each postoperative day using a six-grade scale. All chest tubes were continuously suctioned at a negative pressure of 12 cm H₂O until the morning of postoperative day (POD) 1. Switch was made to water seal if the air leak was graded as “minor at expiration” or lower. This procedure is referred to as “the water seal challenge”. Results: On POD 1, 58 patients had air leaks. The water seal challenge was attempted on POD 1.6±1.0. While 45 patients (78%) continued to receive the water seal, the remaining 13 patients were switched to suctioning at −5 cm H₂O followed by the successful second water seal challenge within 3 days from the first challenge. The air leak stopped 3.1±3.0 days after the application of the water seal in the 58 patients. None of the following correlated with the duration of air leak: preoperative pulmonary function tests, type of lobectomy, age, and gender. Only the leak grade on POD 0 correlated significantly with the duration of air leaks (p<0.0001). Conclusion: These results show that water seal is a safe and effective management option for air leak during the early postoperative period.     

Acute respiratory distress syndrome after pulmonary resection

Postoperative acute respiratory distress syndrome (ARDS) is a recognized complication of pulmonary resection. It is characterized by the acute onset of hypoxemia with radiographic infiltrates consistent with pulmonary edema, without elevations in the pulmonary capillary wedge pressure. Many studies suggest that around 2–5 % of patients develop some degree of lung injury, and the mortality from ARDS following pulmonary resection remains high. ARDS following thoracotomy and lung resection has a miserable prognosis, with overall hospital mortality rates over 25 %. The present review evaluates the evidence available in the literature tracking perioperative mortality and morbidity as well as the pathogenesis and management of ARDS in patients undergoing pulmonary resection.     

Initial chest tube management after pulmonary resection

Tube thoracostomy management with suction or water seal after anatomical pulmonary resection remains somewhat controversial. Initial chest tube management may influence the duration of pleural fluid drainage, duration of tube thoracostomy, and/or hospital length of stay following pulmonary resection. We hypothesized that initial chest tube management with water seal decreases time for chest tube removal and decreases time of hospital stay. A retrospective chart review was performed on 109 consecutive patients who underwent lobectomy or segmentectomy in Western Pennsylvania Hospital between December 1999 and December 2003. Comparison was made between chest tube management of water seal or suction in patients with and without air leak. Of the 109 patients, 78 (72%) had no air leak at the completion of surgery, and 31 (28%) had air leak. In the group without air leak (n = 78), water seal was used in 32 (41%) patients and suction in 46 (59%). In patients placed to water seal initially after surgery (n = 32), removal of chest tubes was on postoperative day (POD) 3.19 +/- 0.24 and hospital discharge was on POD 5.13 +/- 0.61. In patients placed to suction initially (n = 46), chest tubes were removed on POD 4.52 +/- 0.40. Hospital discharge was on POD 6.74 +/- 0.5. Both duration of chest tube (P < 0.007) and length of hospital stay (P < 0.04) were significantly lower in the water seal group. In the air leak group (n = 31), 7 (23%) patients were managed with water seal and 24 (77%) patients with suction. Both duration of chest tube (P = 0.001) and length of hospital stay (P < 0.05) were significantly lower in the water seal group. In patients without air leak, chest tubes should be managed with water seal following anatomical pulmonary resection, resulting in significantly shorter chest tube duration and hospital length of stay.