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Acute effects of indacaterol on lung hyperinflation in moderate COPD: A comparison with tiotropium

Publication year: 2011
Source: Respiratory Medicine, Available online 27 October 2011

Andrea Rossi, Stefano Centanni, Isa Cerveri, Carlo Gulotta, Antonio Foresi, ...

BackgroundEvidence has been provided that high-dose indacaterol (300 μg) can reduce lung hyperinflation in moderate-to-severe chronic obstructive pulmonary disease (COPD).AimTo study whether low-dose indacaterol (150 μg) also reduces lung hyperinflation in comparison with the recommended dose of tiotropium (18 μg) in moderate COPD.MethodsThis was a multicenter, randomized, blinded, 3-period cross-over, placebo-controlled study. Spirometry and lung volumes were measured before and 30, 60, 120, 180 and 240 min after the administration of single-doses of indacaterol, tiotropium, or placebo. The primary end-point was the change in peak inspiratory capacity (IC). The area under the 4-h curve (AUC0–4) for IC, 1-s forced expiratory volume (FEV1) and forced vital capacity (FVC) were secondary variables.Results49 patients completed the study. On average, peak IC and AUC0–4for IC were significantly greater after indacaterol than placebo by 177 mL (p = 0.007) and 142 mL (p = 0.001), respectively. Differences in peak IC and AUC0–4for IC between tiotropium and placebo were 120 mL (p = 0.07) and 85 mL (p = 0.052), respectively. Differences between indacaterol and tiotropium were statistically insignificant. Peak IC increased by >20% in 12 patients with indacaterol and 9 with tiotropium (p = 0.001), and by >30% in 8 patients with indacaterol and 3 with tiotropium (p = 0.001). The effects of indacaterol and tiotropium on FEV1and FVC were statistically significant vs placebo.ConclusionsLow-dose indacaterol has a bronchodilator effect that is similar to the recommended dose of tiotropium, but it is slightly superior in reducing lung hyperinflation.Trial registrationClinicalTrials.govnumber: NCT00999908.

Benefits of adding fluticasone propionate/salmeterol to tiotropium in moderate to severe COPD

Publication year: 2011
Source: Respiratory Medicine, Available online 29 October 2011

Nicola A. Hanania, Glenn D. Crater, Andrea N. Morris, Amanda H. Emmett, Dianne M. O’Dell, ...

BackgroundCombining maintenance medications with different mechanisms of action may improve outcomes in COPD. In this study we evaluated the efficacy and safety of fluticasone/salmeterol (FSC) (250/50 mcg twice daily) when added to tiotropium (18 mcg once daily) (TIO) in subjects with symptomatic moderate to severe COPD.MethodsThis was a 24-week, randomized, double-blind, parallel group, multi-center study. Subjects 40 years or older with cigarette smoking history ≥10 pack-years and with the diagnosis of COPD and post-bronchodilator FEV1≥40 to ≤ 80% of predicted normal and FEV1/FVC of ≤0.70 were enrolled. Following a 4-week treatment with open-label TIO 18 mcg once daily, subjects were randomized in a double-blind fashion to either the addition of FSC 250/50 DISKUS twice daily or matching placebo. The primary efficacy endpoint was AM pre-dose FEV1and secondary endpoints included other measures of lung function, rescue albuterol use, health status and exacerbations.ResultsThe addition of FSC to TIO significantly improved lung function indices including AM pre-dose FEV1, 2 h post-dose FEV1, AM pre-dose FVC, 2 h post-dose FVC and AM pre-dose IC compared with TIO alone. Furthermore, this combination was superior to TIO alone in reducing rescue albuterol use. However, there were no significant differences between the treatment groups in health status or COPD exacerbations. The incidence of adverse events was similar in both groups.ConclusionsThe addition of FSC to subjects with COPD treated with TIO significantly improves lung function without increasing the risk of adverse events. NCT00784550.

Post-traumatic pulmonary embolism in the intensive care unit.

To determine the predictive factors, clinical manifestations, and the outcome of patients with post-traumatic pulmonary embolism (PE) admitted in the intensive care unit (ICU).

METHODS: During a four-year prospective study, a medical committee of six ICU physicians prospectively examined all available data for each trauma patient in order to classify patients according to the level of clinical suspicion of pulmonary thromboembolism. During the study period, all trauma patients admitted to our ICU were classified into two groups. The first group included all patients with confirmed PE; the second group included patients without clinical manifestations of PE. The diagnosis of PE was confirmed either by a high-probability ventilation/perfusion (V/Q) scan or by a spiral computed tomography (CT) scan showing one or more filling defects in the pulmonary artery or its branches.

RESULTS: During the study period, 1067 trauma patients were admitted in our ICU. The diagnosis of PE was confirmed in 34 patients (3.2%). The mean delay of development of PE was 11.3 ± 9.3 days. Eight patients (24%) developed this complication within five days of ICU admission. On the day of PE diagnosis, the clinical examination showed that 13 patients (38.2%) were hypotensive, 23 (67.7%) had systemic inflammatory response syndrome (SIRS), three (8.8%) had clinical manifestations of deep venous thrombosis (DVT), and 32 (94%) had respiratory distress requiring mechanical ventilation. In our study, intravenous unfractionated heparin was used in 32 cases (94%) and low molecular weight heparin was used in two cases (4%). The mean ICU stay was 31.6 ± 35.7 days and the mean hospital stay was 32.7 ± 35.3 days. The mortality rate in the ICU was 38.2% and the in-hospital mortality rate was 41%. The multivariate analysis showed that factors associated with poor prognosis in the ICU were the presence of circulatory failure (Shock) (Odds ratio (OR) = 9.96) and thrombocytopenia (OR = 32.5).Moreover, comparison between patients with and without PE showed that the predictive factors of PE were: Age > 40 years, a SAPS II score > 25, hypoxemia with PaO(2)/FiO(2) < 200 mmHg, the presence of spine fracture, and the presence of meningeal hemorrhage.

CONCLUSION: Despite the high frequency of DVT in post-traumatic critically ill patients, symptomatic PE remains, although not frequently observed, because systematic screening is not performed. Factors associated with poor prognosis in the ICU are the presence of circulatory failure (shock) and thrombocytopenia. Predictive factors of PE are: Age > 40 years, a SAPS II score > 25, hypoxemia with PaO(2)/FiO(2) < 200, the presence of a spine fracture, and the presence of meningeal hemorrhage. Prevention is highly warranted.

Comparison of 1.5 and 3.0 T for Contrast-Enhanced Pulmonary Magnetic Resonance Angiography.

In a recent multi-center trial of gadolinium contrast-enhanced magnetic resonance angiography (Gd-MRA) for diagnosis of acute pulmonary embolism (PE), two centers utilized a common MRI platform though at different field strengths (1.5T and 3T) and realized a signal-to-noise gain with the 3T platform.

This retrospective analysis investigates this gain in signal-to-noise of pulmonary vascular targets.

Methods: Thirty consecutive pulmonary MRA examinations acquired on a 1.5T system at one institution were compared to 30 consecutive pulmonary MRA examinations acquired on a 3T system at a different institution. Both systems were from the same MRI manufacturer and both used the same Gd-MRA pulse sequence, although there were some protocol adjustments made due to field strength differences. Region-of-interests were manually defined on the main pulmonary artery, 4 pulmonary veins, thoracic aorta, and background lung for objective measurement of signal-to-noise, contrast-to-noise, and bolus timing bias between centers.

Results: The 3T pulmonary MRA protocol achieved higher spatial resolution yet maintained significantly higher signal-to-noise ratio (≥13%, p = 0.03) in the main pulmonary vessels relative to 1.5T. There was no evidence of operator bias in bolus timing or patient hemodynamic differences between groups.

Conclusion: Relative to 1.5T, higher spatial resolution Gd-MRA can be achieved at 3T with a sustained or greater signal-to-noise ratio of enhanced vasculature.

Chemoprevention for Brain Metastases.

With the advent of effective therapies for systemic disease control, the prevalence of brain metastases (BMs) has been increasing.

Relapses in the brain are a major barrier to cure in many patients with lung cancer and other malignancies. Effective agents are needed to prophylactically treat micrometastatic disease in patients at high risk for BMs, thereby reducing the incidence.

In this report, we review the pathogenesis of and clinical risk factors for BMs, obstacles to BM treatment, and BM chemoprevention in lung cancer, breast cancer, melanoma, and renal cell carcinoma.

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