Active clinical trials for "Pneumonia"

Multicenter, randomized, placebo-controlled, parallel, blinded, interventional, treatment clinical trial with two arms. Population: 500 Hospitalized patients with pneumonia derived from COVID-19 (Coronavirus Disease-19), either confirmed by RT-PCR (Real Time polymerase chain reaction), or suggested by typical findings on the computed tomography scan symptomatic. Experimental group: nitazoxanide 500mg 8 / 8 hours for 5 days. Control group: placebo 8/8 hours for 5 days.

More than 17 million people have been infected and more than 677K lives have been lost since the COVID-19 pandemic. Unfortunately, there is neither an effective treatment nor is there a vaccination for this deadly virus. The moderate to severe COVID-19 patients suffer acute lung injury and need oxygen therapy, and even ventilators, to help them breathe. When a person gets a viral infection, certain body cells (inflammatory/immune cells) get activated and release a wide range of small molecules, also known as cytokines, to help combat the virus. But it is possible for the body to overreact to the virus and release an overabundance of cytokines, forming what is known as a "cytokine storm". When a cytokine storm is formed, these cytokines cause more damage to their own cells than to the invading COVID-19 that they're trying to fight. Recently, doctors and research scientists are becoming increasingly convinced that, in some cases, this is likely what is happening in the moderate to severe COVID-19 patients. The cytokine storm may be contributing to respiratory failure, which is the leading cause of mortality for severe COVID-19 patients. Therefore, being able to control the formation of cytokine storms will also help alleviate the symptoms and aid in the recovery of severe COVID-19 patients.

Pneumonia caused by coronavirus infection COVID-19 is characterized by a combination of several dangerous factors that consistently worsen the patient's condition: viral lung damage early in the disease; a sharp increase in inflammation on the background of an unbalanced immune response ("cytokine storm"); joining a bacterial infection. The condition of patients deteriorates significantly mostly at cytokine storm development. The damaging of a large volume of lung tissue leads to develops of respiratory failure, respiratory distress syndrome, or shock. Ventilatory support becomes ineffective and patients die. There are reports of the effectiveness of Human Normal Immunoglobulin for Intravenous Administration (IVIG) high doses when used as part of complex therapy in patients with pneumonia caused by coronavirus COVID-19. In particular, IVIG has a positive effect on survival rates, overall disease course, duration of stay in the intensive care unit, and ventilatory support duration. The probable mechanism of action of high-dose IVIG therapy is considered to be a regulatory effect on the immune system. Similar is the known and confirmed effectiveness of IVIG for autoimmune diseases (Kavasaky disease, Guillain Barre syndrome, Chronic inflammatory demyelinating polyradiculoneuropathy, Multifocal motor neuropathy). This trial to assesses the Efficacy of IVIG (medication trade name - Bioven, manufactured by Biopharma Plasma LLC) in the High Immunomodulatory Dose in Complex Treatment of Severe Pneumonia Caused by COVID-19 / SARS-CoV-2

This pilot study will evaluate study processes and feasibility of a future large-scale clinical trial that proposes to test whether low-risk children managed as outpatients with community-acquired pneumonia (CAP) and procalcitonin (PCT) levels <0.25 ng/mL treated with placebo have a similar clinical response to those treated with antibiotics and fewer adverse effects.

The study is a Randomized, Open-Label, Multi-Centre, Phase 2a Study to Evaluate the Safety and Effect of STC3141 Continuous Infusion in Subjects with Severe Corona Virus Disease 2019（COVID-19）Pneumonia.

Exercise intolerance and fatigue are the most common symptoms in patients with chronic COVID after hospital discharge. Muscle deconditioning, dysautonomia, and exercise hyperventilation have been proposed as potential mechanisms contributing to exercise functional capacity limitation in Long-COVID. Along this line, combined exercise training or inspiratory muscle training (IMT) alone have already been demonstrated to be feasible therapeutic options for Long-COVID patients. However, we do not have evidence about the effects of a home-based IMT program for 12-week on peak oxygen consumption (peakVO2). in patients chronic COVID (>3 months) after hospital discharge. This is a prospective study, blinded for the evaluator, randomized (1:1) to receive standard management alone or combined with a program of IMT that will be carried out in a single center. After randomization, patients will be clinically evaluated. The primary endpoint (peakVO2) will be assessed by cardiopulmonary exercise testing (CPET) at 12-week. Patients with chronic COVID (>3 months) after hospital discharge will be enrolled. A sample size estimation [alfa: 0.05, power: 80%, a 15% loss rate, and at least a delta change of mean peakVO2: +3 mL/kg/min (SD±2.5)] of 26 patients (13 per arm) would be necessary to test our hypothesis.

Prospective, double-blind, randomized assessment of the efficacy, safety and pharmacokinetic of Aerucin® as adjunct treatment (in addition to standard of care antibiotics) for pneumonia caused by P. aeruginosa.

The purpose of this study is to evaluate the safety and efficacy of omadacycline as compared to moxifloxacin in the treatment of adults with community-acquired bacterial pneumonia.

This study evaluates the safety and efficacy of lefamulin, a pleuromutilin, for the treatment of adults with moderate to severe community-acquired bacterial pneumonia.

Background: Hospital acquired pneumonia (HAP) is divided in two distinct groups, ventilator-associated pneumonia (VAP) and non-ventilator-associated HAP (nvHAP). Although nvHAP occurs more frequently than VAP and results in similar mortality and costs, prevention guidelines and prevention focus almost exclusively on VAP. Scientific evidence about nvHAP prevention is scarce. Therefore, we designed a mixed-methods study to investigate the effectiveness of a newly developed nvHAP prevention bundle and factors that influence its implementation. Methods: This single-centre project at the 950-bed University Hospital Zurich (UHZ) will engage the wards of nine departments with substantial nvHAP rates. The nvHAP bundle consists of five primary prevention measures: 1) oral care, 2) identification and treatment of patients with dysphagia, 3) mobilization, 4) stopping unnecessary proton pump inhibitors, and, 5) respiratory therapy. Implementation includes the engagement of department-level implementation teams, who sustain the 'core' intervention components of education, training, and environmental restructuring and adapt the implementation strategy to local needs. The effects of the implementation will be analysed by a mixed-method approach. As primary outcome, nvHAP incidence rates will be analysed by Poisson regression models to compare incidence rates before, during, and after the implementation phases (on the hospital and department level). In addition, the association between process indicators and nvHAP incidence rates will be analysed using longitudinal Poisson regression models. A longitudinal, qualitative study and formative evaluation based on interviews and focus groups identifies supporting or hindering factors for implementation success in participating departments dynamically over time. This accumulating implementation experience will be constantly fed back to the implementation teams and thus, represents an active implementation element. Discussion: This comprehensive mixed-methods study is designed to accomplish both, measure the effectiveness of a new prevention bundle against nvHAP and provide insights into how and why it worked or failed. The results of this study may contribute substantially to patient safety in the area of a rediscovered healthcare-associated infection - nvHAP.