View clinical trials related to Cystic Fibrosis.
Filter by:Cystic fibrosis (CF) results in the thickening of mucus in the lungs and other organs due to dysfunction of a transmembrane conductance protein. This allows buildup of bacteria that results in inflammation, leading to tissue breakdown and loss of function. In the lungs, this process causes loss of air exchange structures progressing to diminished lung function. The exchange of oxygen in the lungs depends on both the integrity of air conduits and vasculature. Most clinical assessments, however, focus on ventilatory function, with the assumption that any vascular compromise is secondary. Nevertheless, there is evidence, some from the investigator's lab, to suggest that perfusion anomalies in the lung occur before signs of ventilatory dysfunction. Thus, the inflammatory processes of CF may impact pulmonary microvasculature specifically and concurrently or prior to damage to ventilatory structures. This study aims to apply a new MRI method to serially measure regional lung perfusion, without the use of contrast agent, in children with CF and to associate it with regional assessments of ventilation and to serum cytokines or proteomic markers of angiogenesis and inflammatory processes. The investigator's lab has recently developed a noninvasive, non-contrast, method of labeling blood flowing into the lungs and generating a map of perfusion. The investigator aims to couple this technique to existing methods using hyperpolarized Xenon to map ventilation. The investigator will apply these methods over time in CF patients, monitoring the relationship between regional perfusion and ventilation defects. This pilot work will provide the foundation for larger studies to establish the essential etiological role of perfusion deficits in CF.
Cystic fibrosis (CF) is the most common lethal inherited disease in Caucasian populations. To improve survival, it is essential to understand the development, progression and treatment of CF lung disease throughout early childhood. Therefore the overall objective is to prospectively assess the clinical utility of novel and non-invasive measuring methods, namely Multiple Breath Washout and functional lung MRI in the longitudinal clinical surveillance of patients with CF and compare the results to those of healthy controls.
Cystic Fibrosis (CF) is a disease that affects salt and water transport in multiple organs. Many CF patients suffer from abdominal pain and this could be due to intestinal inflammation. However, so far we do not know how many of the CF patients actually do have intestinal inflammation when looking at intestinal specimens. There is a proven connection between chronic inflammation and developing colorectal cancer and over the years more CF patients are developing colorectal cancer. Thus, it becomes increasingly important to look for the presence of intestinal inflammation in CF patients since early treatment may improve their symptoms and reduce the risk for colorectal cancer.
Cystic fibrosis pulmonary exacerbations (CF PEx) vary greatly in their severity, their pathogens, and their treatment responses. A failure to return to baseline lung function after treatment may be due to persistent infection or chronic inflammation or both. This constant infection and inflammation are believed to be tightly connected, making it difficult to know the exact reason why some patients fail to respond to treatment. The purpose of this study is to evaluate both infection and inflammation during CF PEx to allow for more personalized approaches to improve lung function responses and better CF PEx outcomes. Subjects will be asked to be in the study if they have CF, are 18 years of age or older, and are starting on IV antibiotics due to worsening lung infection. Subjects will stay in the study for up to 5 years, with visits occurring once a year if hospitalized for a CF PEx. Each visit will have blood, sputum, and urine collected and analyzed for changes in expression of certain genes and proteins. These changes may relate to improvements felt by people living with CF and determine what treatments are most helpful.
CF patients enrolled in this protocol will be recruited from patients followed by the Adult CF Program at National Jewish Health. Patients will be selected based on planned use of a CFTR modulator by their primary physician. No patient will be started on (or will switch) CFTR modulator agents for the purpose of the study. After enrollment, biological samples may be collected at two different time points prior to treatment initiation. One set of samples will be collected at baseline health prior to CFTR modulator initiation or change. A second set of samples will be obtained in subjects at the time of acute pulmonary exacerbation, if one occurs prior to CFTR modulator initiation or change. Post CFTR modulator initiation study assessments will be obtained at least one month after starting treatment and continue up to 2 times a year (including during pulmonary exacerbations), in order to document longitudinal effects of therapies and changes in inflammatory biology over time. At the time of each biological sampling, blood, sputum sample, urine, and a quality of life assessment will be acquired in all enrolled subjects. In addition to demographic data, clinical data, such as quantitative microbiology and simple spirometry will be recorded at the time of sample collection.
The introduction of triple combination CFTR modulator therapy for patients with Cystic Fibrosis (CF) with at least one copy of the deltaF508 mutation is expected to provide major health benefits, but will also require novel outcome measures that can detect CF lung disease at an early stage, capture the efficacy of new therapies when disease manifestations are limited, as well as determine whether stopping existing chronic maintenance therapies does not have negative effects. In the past decade, research has focused on the multiple breath washout (MBW) test, as a sensitive outcome measure, especially if highly-effective modulator therapies are initiated in early childhood. Even LCI, however, may not adequately capture early lung function changes, thus warranting investigation of even more sensitive outcome measures. Magnetic resonance imaging (MRI) has the advantage of being a radiation-free modality, making it more suitable for assessing response to therapy in a shorter time frame with repeated imaging. Inhalation of a hyperpolarized gas enables the visualization and quantification of regional ventilation in the lung and can be combined with structural MRI to assess both structure and function in parallel. The main Investigator and others have recently formed an international consortium (the 129Xe MRI Clinical Trial Consortium), comprised of both imaging experts and pulmonary clinicians to standardize imaging procedures, thus facilitating multi-site implementations. Data from this proposed study (HyPOINT; Hyperpolarized Imaging for New Treatments) will inform the future utility of MRI for both longitudinal studies to track disease progression over time as well as for future interventional trials. Further, the current study could inform the design of future trials of interventions of patients for whom currently no effective CFTR modulator therapy is available and for patients with rare genotypes thus laying the groundwork for a more personalized medicine approach in the near-term future.
Our project is to describe retrospectively and prospectively CF patients treated with biotherapy in French CF centers. Main objective: To describe the clinical and paraclinical course of CF patients before and after treatment with anti-IL5 and other biotherapies since 2019. Secondary objective: To describe adverse events potentially related to the biotherapies.
Study is looking at the effects of cystic fibrosis treatment on bone muscle.
This is a prospective, multi-center observational study. The study is designed to measure the clinical effectiveness of elexacaftor, tezacaftor and ivacaftor (ETI) triple combination therapy in people with one or more copies of the F508del mutation, study the effects of ETI across a number of CF disease manifestations, and collect specimens for future research. Subjects in the study will have one "before TCT" visit within 30 days before initiation of the therapy and five "after TCT" visits over a 30-month follow-up period. Participants who have participated in the original PROMISE cohort have the option of participating in a long-term extension with annual visits performed at the 42- and 54-month timepoints. The durability of the clinical and biological changes in PROMISE can be assessed with extended follow-up, which would enable the sub-studies to consider potential clinical consequences of the biological or physiological effects being studied. This work will help to inform long term prognosis and feasibility of certain clinical trials outcomes for interventional studies and may be useful when considering research priorities in drug development. Most participating sites have been divided into sub-study groups; each sub-study group has specific non-optional procedures conducted in addition to the "Core" procedures. Finally, there is one optional procedure (transient elastography) that will be offered to subjects at certain sites. The duration of participation for each subject is 30 months (with an additional 24 months if participants agree to the optional long-term extension). NOTE: FDA has reviewed the New Drug Application (NDA) for elexacaftor, tezacaftor and ivacaftor and has granted approval.
The objective of this study is to evaluate the predictive nature of the biomarker Porphyromonas catoniae measured at the age of 12 months in the occurrence of colonization with Pseudomonas aeruginosa at 36 months of age in children with cystic fibrosis.