Radar des Essais Cliniques

The main reason for this research study is to learn more about some new tests that are being developing for patients with Cystic Fibrosis (CF) to measure changes in the lungs. In this study, the focus will be to learn how stopping Airway Clearance (ACT) and re-starting ACT can affect these tests. These new tests include using a breathable gas called Xenon (Xe) with MRI (magnetic resonance imaging) to improve the pictures of changes in the lungs. The Xenon (Xe) gas that has been treated to have a larger MRI signal (also called hyperpolarized). The other new test is called LCI (Lung Clearance Index) that can measure how well the lungs are working. The MRI machine used in this study has been approved by the U.S. Food and Drug Administration (FDA) and is commercially available for sale in the USA. Hyperpolarized Xe gas is an FDA-approved, inhaled contrast agent for lung ventilation MRI. The new Xe MRI techniques that are being developed and used for this research study are investigational, meaning these new Xe MRI techniques are not FDA approved, but they are similar to FDA-approved techniques that are used clinically at Cincinnati Children's Hospital Medical Center (CCHMC). Xe gas and the new MRI techniques used in this research study have been used for many years in research, including in many research studies conducted at CCHMC like this one.

Cystic fibrosis (CF) is a progressive, systemic disease affecting an estimated 30,000 children and adults in the United States (70,000+ worldwide) and is caused by mutations in the gene that encodes the cystic fibrosis transmembrane conductance regulator (CFTR) protein--a chloride and bicarbonate channel that regulates ion transport and mucus composition in CF-affected tissues, such as the lung. In airways this leads to mucus stasis, infection, inflammation, and remodeling that result in mucus plugs, regional lung obstruction, and progressive airway destruction and bronchiectasis. Highly-effective CFTR modulators, which are recently available to >90% of patients, have revolutionized CF clinical care, with large increases in pulmonary function as a result of more effective mucociliary clearance. As a result, burdensome maintenance therapies like mechanical airway clearance treatment (ACT), requiring nearly 2 dedicated hours per day, have been questioned by patients, families, and medical providers. In a recent survey of CF community members, ACT was ranked as the most burdensome chronic therapy, yet is the least studied. Prospective studies of maintenance-therapy withdrawal pose potential ethical risks, since traditional testing via spirometry and/or multiple-breath washout is relatively insensitive to small or regional changes and long-term lung-function reductions often have permanent consequences. Nevertheless, many patients have withdrawn these maintenance therapies against advice from their providers. A major gap in CF management is our ability to monitor lung function sensitively and rapidly as a result of treatment changes, such as partial withdrawal of ACT.

Breakthroughs in structural and functional magnetic resonance imaging (MRI) have demonstrated exquisite sensitivity to regional CF lung disease and can monitor regional and subtle changes over time, without ionizing radiation, even in patients with normal spirometry. As demonstrated in the previous R01 that ultrashort echo time (UTE) MRI provides structural images that rival computered tomography (CT) imaging, with sensitivity to detect all of the structural hallmarks of treatable (e.g., mucus plugs) and permanent lung disease (e.g., bronchiectasis). It has been demonstrated that hyperpolarized 129Xe MRI is more sensitive than any other technique at detecting changes in regional pulmonary ventilation and gas exchange. For the first time, a single modality (MRI) is available to safely monitor regional lung disease and treatment changes before FEV1 declines become permanent. This is a unique opportunity to safely evaluate ACT in CF populations that remain at risk of long-term lung function decline.