View clinical trials related to Bronchiectasis.
Filter by:Qualified sputum samples from bronchiectasis patients were collected regularly every month for three consecutive years to analyze the microbiome changes of lower respiratory tract of bronchiectasis patients by metagenomic sequencing. Pseudomonas aeruginosa was isolated and the whole genome was sequenced to analyze the adaptive evolution,including virulence, quorum sensing and drug resistance under host pressure. The aim of the study is to clarify the rule of microflora colonization distribution and adaptive evolution in the lower respiratory tract of patients with bronchiectasis, to predict the acute attack and prognosis of patients with microbiome changes, and to find more new prevention and treatment methods by adjusting the microbiome of the lower respiratory tract.
This study uses a new breathing device called 'N-Tidal C' handset which measures breathing patterns. Investigators have found that people with cardiac and respiratory illnesses breathe out a gas, called carbon dioxide (CO2), in a different way to healthy people. The pattern of breathed out CO2 (the waveform) varies according to the underlying health of the user's lungs. Monitoring these changes may help doctors to more accurately diagnose and monitor the most common and serious respiratory conditions.
The present study will aim to find out whether a home treatment in people with bronchiectasis consisting of a single daily session to facilitate expectoration (combining nebulization of hypertonic saline (HS) at 6% followed by airway clearance techniques) is at least as effective as performing two sessions per day following the same process in each of the sessions, during a period of 6 months.
Prevalence of dynamic hyperinflation and its relationship with functional exercise capacity will be evaluated in children with bronchiectasis.
This is pilot study of the immunologic effects of intradermal Bacille Calmette-Guerin (BCG) vaccination of adults with cystic fibrosis (CF), non-CF bronchiectasis (NCFB), and healthy volunteers.
The overlap between chronic obstructive pulmonary disease (COPD) and bronchiectasis is a neglected area of research, and it is not covered by guidelines for clinical practice. COPD and bronchiectasis share common symptoms of cough with sputum production and susceptibility to recurrent exacerbations driven by new or persistent infection. Physiological criteria for the diagnosis of COPD and structural criteria for the diagnosis of bronchiectasis create the possibility for individual patients to fulfil both, resulting conceptually in either co-diagnosis or an overlap syndrome between the two conditions. The prevalence of this overlap will vary depending on the respective prevalence of COPD and bronchiectasis in the population under consideration. A recent study of 201 COPD patients with airway wall abnormalities typical of bronchiectasis confirmed an association with exacerbations and was predictive of mortality over 48 months. A further, single-centre study demonstrated a near three-fold increased mortality rate, with patients with bronchiectasis and associated COPD having a 5-year mortality of 55%, compared with 20% in those with bronchiectasis without COPD. Airflow obstruction is perhaps best considered one marker of disease severity in bronchiectasis. Disease-associated exacerbations have a major effect on patient healthcare costs as well as quality of life due to increased lung damage and mortality risk. Microorganisms such as Pseudomonas aeruginosa and, to a lesser extent, other Gram-negative and Gram-positive microorganisms identified in culture, have been linked to disease progression, poor clinical outcomes in bronchiectasis and driving airway neutrophil-mediated inflammation. The microbiome has the potential to provide valuable information regarding disease phenotype/endotype, treatment responses and targets for future therapy.
Patients with a respiratory disease are at higher risk of poor outcomes due to worsening of symptoms caused by Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) and other respiratory infections. New therapies are needed for treating high risk patients at early stages of an infection. This study will assess the safety, tolerability and feasibility of using an inhaled nitric oxide generating solution, RESP301, as a self-administered treatment following flare-up of symptoms. RESP301 is a liquid solution which produces nitric oxide in the lungs when inhaled using a nebuliser. The components of RESP301 are already used in clinical practice and inhaled nitric oxide is used as a treatment for newborns and patients with Chronic Obstructive Pulmonary Disease (COPD). In a laboratory setting, RESP301 has been shown to be effective against respiratory viruses, including SARS-CoV-2. This study will first determine the maximum tolerated dose of RESP301 in up to 48 adult patients with COPD or bronchiectasis in the United Kingdom (UK) (Part 1a; Dose Finding Phase). Once the Maximum Tolerated Dose (MTD) has been determined in Part 1a, a cohort of 8 patients will be recruited and RESP301 administered at the MTD but these patients will in addition receive a single dose of a short acting bronchodilator 10 minutes preceding administration of RESP301. After completion of Part 1, approximately 150 patients will be recruited into Part 2 of the trial (Expansion Phase). A minimum of 50 participants will receive a test dose of RESP301 during a screening visit. Response to the test dose will be monitored. Participants who tolerate the test dose will continue in the study and should contact the study team if they experience exacerbation symptoms in the next 52 weeks. Following a call with the site team to discuss symptoms, participants will receive RESP301 delivered to their home to self-administer for 7 days. The study duration for each participant will be at most 57 weeks, including the study visit and monthly calls. Participants who start the course of study treatment, will receive daily calls during the treatment period and will also be followed up after they complete the treatment.
Lung diseases are one of the most common causes of emergency room visits. There are very few tools that are able to predict which patients will have a worsening or increasing severity of their condition. There are also limited ways to check the health of patients with respiratory conditions at home and during the time between medical appointments. The ADAMM-RSMTM device records heart rate, breathing rate, temperature, cough and activity while wearing it. This study will test participants willingness to wear the device and perform ongoing monitoring to assess the possibility to predict the onset and increases in severity of their lung conditions.
Lung involvement in Sjögren's syndrome is common and causes reduced quality of life and increased mortality. Sjögren's syndrome-related lung diseases (SS-RLD) are classified and treated as the primary lung diseases they resemble. Whether this approach is optimal has not been evaluated thoroughly. A critical gap in knowledge is knowing whether SS-RLDs have a unique clinical course and response to therapy. Given the underlying immune system dysfunction in Sjögren's syndrome, the investigators hypothesize that patients with SS-RLD will be more likely to respond to immunosuppressive therapy than patients with the matching primary lung disease. To address this hypothesis, the investigators will prospectively screen for Sjogren's syndrome in patients presenting to pulmonary clinics and compare the clinical course and response to therapy in Sjogren's syndrome positive and negative patients.
Exacerbations, in particular during chronic Pseudomonas aeruginosa (PA) infection, are very important in the prognosis of patients with non-cystic fibrosis bronchiectasis (BE). In Cystic Fibrosis patients, PA biofilms are associated with chronic respiratory infections and are the primary cause of their increased morbidity and mortality. However, the presence and role in exacerbations of PA biofilms, microbiome dysbiosis and inflammatory biomarkers has not been studied in depth in BE patients. Our aim is to determine the association between PA chronic infection and its biofilms with the number of exacerbations in the next year (primary outcome), time until next exacerbation, quality of life, FEV1 and inflammatory biomarkers (secondary outcomes) in BE patients with or without chronic obstructive pulmonary disease (COPD). The investigators will include and follow up during 12 months post study inclusion, 48 patients with BE and 48 with BE-COPD, with a positive sputum culture of PA. During stability and follow up (and in each exacerbation) The investigators will collect 4 sputum, 4 serum samples, perform spirometry, and quality of life tests every three months. For the biomarkers subproject, 4 additional serum samples will be collected at: exacerbation, 3-5 days after treatment, at 30 days and three months post-exacerbation. Biomarkers will be measured by commercial kits and Luminex. The investigators will quantify PA colony forming units (CFU)/mL, their resistance pattern, their mutation frequency and isolate mucoid and non-mucoid colonies. In each sputum, the investigators will analyze by Confocal Laser Scanning Microscopy (CLSM) and Fluorescent in situ Hybridizatrion (FISH) PA biofilms, their size, bacterial density and their in situ growth rate. Specific serum antibodies against PA will be determined through Crossed Immunoelectrophoresis. In addition, the investigators will indentify potential respiratory microbiome and gene expression patterns predictive for exacerbations, or with a protective role against chronic PA infection, as well as their association with biofilms. Microbiome analysis will be performed through the Illumina Miseq platform. Finally, the investigators will explore the antimicrobial activity of novel combinations of antibiotics against PA, both in in vitro planktonic cultures and in a biofilm model, and will include testing of antibiotic-containing alginate nanoparticles.