Long-term physiological consequences of pneumonectomy.

Ever since the first successful pneumonectomy for lung cancer was performed in 1933, a number of largely historical reports have attempted to look at the physiological consequences of this operation in order to define patient long-term functional status. The pertinence of these contributions is, however, limited because most were performed in patients who had their pneumonectomy for benign diseases or were carried out in small and heterogeneous populations. Thus, several surgical myths and beliefs such as phrenic nerve interruption at the time of operation might be desirable, marked hyperinflation of the residual lung is associated with reduced lung function, and patients develop pulmonary hypertension over time and have poor exercise tolerance have persisted over the years. Our findings based on a study of 100 patients evaluated 5 or more years after surgery (mean follow-up time, 9.1 ± 2.8 years [5.0-14.7 years]) show that most patients can adjust to living with only one lung and are thus able to live a near-normal life. Although diaphragmatic paralysis is characterized by significant alterations in respiratory function, hyperinflation of the residual lung is beneficial.

Adjustments in cardiorespiratory function after pneumonectomy: results of the pneumonectomy project.

OBJECTIVE: To assess lung function, gas exchange, exercise capacity, and right-sided heart hemodynamics, including pulmonary artery pressure, in patients long term after pneumonectomy. METHODS: Among 523 consecutive patients who underwent pneumonectomy for lung cancer between January 1992 and September 2001, 117 were alive in 2006 and 100 were included in the study. During a 1-day period, each patient had complete medical history, chest radiographs, pulmonary function studies, resting arterial blood gas analysis, 6-minute walk test, and Doppler echocardiography. RESULTS: Most patients (N = 73) had no or only minimal dyspnea. On the basis of predicted values, functional losses in forced expiratory volume in 1 second and forced vital capacity were 38% ± 18% and 31% ± 24%, respectively, and carbon monoxide diffusing capacity decreased by 31% ± 18%. There was a significant correlation between preoperative and postoperative forced expiratory volume in 1 second (P < .01), and more hyperinflation was associated with better lung function (P < .01 for forced expiratory volume in 1 second). Gas exchange was normal at rest (Pao(2) = 88 ± 10 mm Hg; Paco(2) = 42 ± 3 mm Hg), and exercise tolerance (6-minute walk) was also normal (83% ± 17% of predicted values). Thirty-two patients had some degree of pulmonary hypertension, but in most of those cases, it was mild to moderate (mean systolic pressure of 36 ± 9 mm Hg) and not associated with significant differences in lung function (P = .57 for forced expiratory volume in 1 second), gas exchange (P = .08), and exercise capacity (P = .66). CONCLUSIONS: These findings indicate that despite worsening of lung function by approximately 30% after pneumonectomy, most patients can adjust to living with only 1 lung. Pulmonary hypertension is uncommon and in most cases only mild to moderate.

Contrast-enhanced cardiovascular magnetic resonance in the hyperacute phase of ST-elevation myocardial infarction.

Cardiovascular magnetic resonance (CMR) very early after primary percutaneous coronary intervention (PPCI) may lead to instability or early stent complications. However, CMR in the hyperacute phase of STEMI may improve risk stratification. We investigated feasibility and safety of CMR in the hyperacute phase of STEMI immediately after PPCI. One hundred and twenty eight consecutive patients immediately after PPCI for STEMI. Sixty four underwent CMR <12 h after PPCI versus 64 matched controls. Outcomes were followed over 6 months. CMR in hyperacute STEMI was not associated with in-hospital death, infarct expansion, or urgent revascularization (P = NS). CMR (32 ml gadolinium contrast) immediately after PPCI (180 ml iodine contrast) did not increase nephropathy. CMR did not increase major adverse cardiac events (5 vs. 8%, P = 0.16) or recurrence of angina (6 vs. 8%, P = 0.73) at 6 months. CMR immediately after PPCI is feasible and safe, allowing very early risk stratification in STEMI.

Ipsilateral diaphragmatic motion and lung function in long-term pneumonectomy patients.

BACKGROUND: The physiologic advantages of preserving phrenic nerve integrity and normal diaphragmatic motion (DM) during the course of pnemonectomy are incompletely understood. This study was conducted to investigate potential benefits of this strategy on postoperative lung function. METHODS: Among 523 consecutive patients who underwent pneumonectomy for lung cancer between January 1992 and September 2001, 117 were alive at the time of study (March to December 2006) and thus had 5 years' minimum follow-up. Of those, 17 were excluded and 12 could not have magnetic resonance imaging (MRI), leaving 88 patients available for study. Diaphragmatic motion was assessed by MRI during deep breathing, and patients were classified as having normal and synchronous diaphragmatic motion (n = 44) or abnormal diaphragmatic motion (immobile or paradoxical, n = 44). These findings were correlated with expiratory volume measurements, gas exchange (arterial blood gases), and exercise tolerance (6-minute walk test). RESULTS: The mean follow-up time was 9.3 years. Patients with abnormal DM were younger than patients with normal DM and were more likely to have had a right or an extended pneumonectomy (p < 0.01). Despite comparable preoperative lung function, patients with abnormal DM had significantly worse postoperative lung volumes (forced expiratory voume in 1 second, forced vital capacity, lung diffusion capacity for carbon monoxide; p < 0.01) and exercise capacity (6-minute walk test, percent predicted, p < 0.05) than patients with normal DM. CONCLUSIONS: Because the long-term effects of a paralyzed hemidiaphragm in pneumonectomy patients are characterized by significant alterations in lung function, all surgeons doing this type of work should take every precaution to avoid technical errors that could lead to phrenic nerve injury or interruption.

Correlative anatomy for thoracic inlet; glottis and subglottis; trachea, carina, and main bronchi; lobes, fissures, and segments; hilum and pulmonary vascular system; bronchial arteries and lymphatics.

Because it is relatively inexpensive and universally available, standard radiographs of the thorax should still be viewed as the primary screening technique to look at the anatomy of intrathoracic structures and to investigate airway or pulmonary disorders. Modern trained thoracic surgeons must be able to correlate surgical anatomy with what is seen on more advanced imaging techniques, however, such as CT or MRI. More importantly, they must be able to recognize the indications, capabilities, limitations, and pitfalls of these imaging methods.