Active clinical trials for "Idiopathic Pulmonary Fibrosis"

Detection of Integrin avb6 in Idiopathic Pulmonary Fibrosis, Primary Sclerosing Cholangitis, and Coronavirus Disease 2019 with [18F]FP-R01-MG-F2 with PET/CT

COVID-19 Viral Global Pandemic resulting in post-infection pulmonary damage, including Fibrotic Lung Disease due to inflammatory and reactive protein secretions damaging pulmonary alveolar structure and functionality. A short review includes: Early December, 2019 - A pneumonia of unknown cause was detected in Wuhan, China, and was reported to the World Health Organization (WHO) Country Office. January 30th, 2020 - The outbreak was declared a Public Health Emergency of International Concern. February 7th, 2020 - 34-year-old Ophthalmologist who first identified a SARS-like coronavirus) dies from the same virus. February 11th, 2020 - WHO announces a name for the new coronavirus disease: COVID-19. February 19th, 2020 - The U.S. has its first outbreak in a Seattle nursing home which were complicated with loss of lives.. March 11th, 2020 - WHO declares the virus a pandemic and in less than three months, from the time when this virus was first detected, the virus has spread across the entire planet with cases identified in every country including Greenland. March 21st, 2020 - Emerging Infectious Disease estimates the risk for death in Wuhan reached values as high as 12% in the epicenter of the epidemic and ≈1% in other, more mildly affected areas. The elevated death risk estimates are probably associated with a breakdown of the healthcare system, indicating that enhanced public health interventions, including social distancing and movement restrictions, should be implemented to bring the COVID-19 epidemic under control." March 21st 2020 -Much of the United States is currently under some form of self- or mandatory quarantine as testing abilities ramp up.. March 24th, 2020 - Hot spots are evolving and identified, particularly in the areas of New York-New Jersey, Washington, and California. Immediate attention is turned to testing, diagnosis, epidemiological containment, clinical trials for drug testing started, and work on a long-term vaccine started. The recovering patients are presenting with mild to severe lung impairment as a result of the viral attack on the alveolar and lung tissues. Clinically significant impairment of pulmonary function appears to be a permanent finding as a direct result of the interstitial lung damage and inflammatory changes that accompanied. This Phase 0, first-in-kind for humans, is use of autologous, cellular stromal vascular fraction (cSVF) deployed intravenously to examine the anti-inflammatory and structural potential to improve the residual, permanent damaged alveolar tissues of the lungs.

The purpose of this study is being done to determine whether magnetic resonance imaging (MRI) using inhaled hyper-polarized 129 Xenon gas can help visualize impaired lung function to detect changes over time in Idiopathic Pulmonary Fibrosis (IPF) patients receiving approved IPF treatments. Subjects will undergo an approximately hour long comprehensive MRI protocol, including administration of multiple doses of hyper-polarized 129 Xenon. The subjects will have this initial study prior to initiation of IPF therapies. Then the subjects will have repeat studies at 3, 6 and 12 months following the initiation of therapy. Additional studies including pulmonary function studies, serum for bio markers, 6 minute walk distance and a high-resolution computed tomography (HRCT) scan (only at the 6 month visit) will be performed to determine how 129 Xenon MRI performs relative to standard of care evaluations for IPF. The MRI uses a magnet and radio waves to make diagnostic medical images of the body. There have been no ill effects reported from exposure to the magnetism or radio waves used in this test. Risks of the xenon gas are slight numbness in legs, nausea, a feeling of well-being, and mild tingling in fingertips. You will have pulmonary function testing for the study, you may experience breathlessness or dizziness during or immediately following these tests.

Study RIN-PF-302 is designed to evaluate the long-term safety and tolerability of inhaled treprostinil in subjects with idiopathic pulmonary fibrosis.

The XENON ILD study is a single arm, un-blinded study at Duke University enrolling patients with non-idiopathic pulmonary fibrosis (IPF) progressive fibrosis (PF) interstitial lung disease (ILD). Patients who meet criteria for ILD-progression (defined below in inclusion/exclusion criteria) will be consented prior to the initiation of anti-fibrotic therapy. Subjects will undergo an approximately hour long comprehensive MRI protocol, including administration of multiple doses of hyperpolarized 129Xe. The subjects will have this initial study prior to initiation of anti-fibrotic therapies and repeat MRI studies at 3, 6 and 12 months following the initiation of therapy. If subjects do not decide to initiate anti-fibrotic therapy per discussion with their physician, then the 3, 6 and 12 months repeat studies will initiate based on time after enrollment.

The goal of this study is to investigate the safety of [68Ga]CBP8 and its efficacy to detect collagen deposition in pulmonary fibrosis.

Fibrosing interstitial lung diseases or pulmonary fibrosis represent a heterogeneous group of progressive pulmonary pathologies, responsible for a significant morbi-mortality. They are defined by an infiltration of the pulmonary interstitium associating in a variable way an inflammatory component (deposit of inflammatory cells) and a fibrosing component (deposit of collagen). Idiopathic pulmonary fibrosis (IPF) is the most common and most severe pulmonary fibrosis. Other pulmonary fibroses are mainly represented by non-specific interstitial lung disease, pulmonary fibroses associated with connectivites, hypersensitivity pneumonitis, certain pneumoconiosis (occupational diseases) and sarcoidosis. The process of fibrosis is responsible for a loss of elasticity of the lung, leading to a decrease in lung volumes associated with an alteration of gas exchange. In these diseases, the clinician must be able to rely on reliable means to assess the severity of the disease based mainly on the measurement of lung volumes and gas exchange, at diagnosis and in the follow-up of the patient, in order to propose the most appropriate management. Lung volumes are assessed by respiratory function tests. Forced vital capacity is the reference volume value used. Impaired gas exchange is assessed at rest by measuring carbon monoxide diffusion capacity, arterial oxygen saturation and arterial blood gases. The functional capacity to exercise is also a very important evaluation criterion in terms of prognosis and in the follow-up of the patient. It is assessed by means of ergocycle tests which mainly determine the maximal oxygen consumption. These are relatively complex tests that require special equipment and are not routinely performed. Simpler field tests have been developed to assess functional capacity during exercise, the most widely used and validated being the 6-minute Walk Test (TM6). Other field tests to assess functional capacity to exercise have been developed, such as the 30-second, 1-minute, and 3-minute chair lift tests, stepper tests, and step and stair tests. Among them, the 1-minute chair lift test (TLC1) is the best evaluated. It consists of sitting down and getting up from a chair as many times as possible in 1 minute. The criteria measured are mainly the number of lifts and desaturation. Thus, the fundamental advantage of the TLC1 over the TM6 is the exemption from temporal and spatial constraints since it takes only a few minutes and can be performed in a medical office. While TLC1 seems to be the most suitable, there are still a few pitfalls in substituting TLC1 for TM6 during diffuse interstitial lung disease. First, there is only one study reporting the results of TLC1 in a healthy population. It provides a chart of results according to age. Unfortunately, only the number of lifts is reported without any data on heart rate, SaO2 or sensation of dyspnea. In respiratory pathologies, TLC1 has been studied mainly in patients with chronic obstructive pulmonary disease (COPD) and little in PID. Unlike TM6, TLC1 is reproducible and has no learning effect in this population. Interestingly, one study found that peak desaturation and peak oxygen consumption occurred during the recovery phase some seconds after the end of the test. Studies on TLC1 during SID do not allow us to conclude that this test can substitute for TM6. However, investigators may note certain limitations, in particular the small number of patients studied and the retrospective nature of the 2 largest of them. Above all, it seems that the use of TLC1 could be optimized by taking into account the recovery phase in the evaluation of desaturation. The hypothesis of our study is that the TLC1 taking into account the recovery phase can replace the TM6 in the management of fibrosing PID for prognostic evaluation, patient follow-up and indication of oxygen therapy. It is more accessible and its use by all practitioners in face-to-face or telemedicine would allow a better management of these patients. Finally, the investigators hypothesize that the TLC1 will result in lower costs in the management of these patients.

The increasing incidence of chronic respiratory disease is a public health problem that affects hundreds of thousands of people worldwide at all ages. Directly exposed to atmospheric airborne contaminants (pollution, allergens), the respiratory tract represents a complex ecosystem involving different cells (multiciliated, basal, mucosecretory, neuroendocrine, etc.) that develop complex interactions with the surrounding connective tissue but also with their rich immune environment and the local microbiota. Although a pathophysiological continuum is postulated between the nasal and bronchial airways in certain diseases, such as allergic diseases, investigators have demonstrated large gene expression gradients between samples taken from the nasal and bronchial airways in different studies. Specifying the cellular variability throughout the respiratory tree in a normal physiological situation is one of the major objectives defined in the establishment of an atlas of all airway cells, as defined in the objectives of the international consortium Human Cell Atlas. The sequencing of the RNAs present specifically in each individual cell ("single-cell RNAseq"), and its comparison with neighbouring cells allows to document the precise cellular contributions, as well as the signalling pathways involved. The development of tissue sampling, stabilization, transport and single cell analysis procedures can be performed on primary respiratory epithelium cultures and can also be extended to respiratory samples from healthy volunteers. This project will analyze gene expression profiles at the single cell level (single cell RNAseq) in volunteers with chronic obstructive pulmonary disease, interstitial pulmonary fibrosis and compared to healthy subjects of the same age. The technical modalities of the samples will be brushing and staged airway biopsies for direct analysis of the samples. This approach will be complemented by an air-liquid interface culture to allow secondary analysis in single cell RNAseq and three-dimensional mapping of the distribution of these cells with single cell in situ analysis. Thanks to sampling at several levels of the respiratory tree (nose, bronchioles, bronchioles), cellular and gene expression variations along the tracheobronchial axis will be exhaustively documented in subjects of different ages, healthy or suffering from pathologies such as chronic obstructive pulmonary disease and interstitial pulmonary fibrosis. These data will serve as worldwide references for comparisons in different physiological and pathological contexts.

Idiopathic Pulmonary Fibrosis(IPF) is the most common idiopathic interstitial lung disease whose cause is unknown. With age and gender, socio-economic factors are the most influential indicators of health. At present there is very little data on socio-economic factors in the IPF. The investigators hypothesize that a lower socio-economic level and / or exposure to various air pollutants may influence the IPF's natural history, including the severity of diagnosis and prognosis of the IPF. The investigators also hypothesize that the deleterious effect of air pollutants is modulated by individual susceptibility (shorter telomeres) and that this effect is related to oxidative stress and shortening of telomeres.

Idiopathic Pulmonary Fibrosis (IPF) is a progressive lung disease marked by reduced exercise capacity and activity-related breathlessness (commonly termed dyspnea). Our previous work has shown that dyspnea during exercise is associated with an increased drive to breathe (inspiratory neural drive; IND). However, little work has been done to understand the mechanisms of exertional dyspnea in patients with mild IPF. The objectives of this study are to compare the acute effects of inhaled nitric oxide to placebo on ventilatory efficiency (VE/VCO2), and IND at rest and during a standard cardiopulmonary exercise test (CPET). Twenty patients with diagnosed IPF with mild (or absent) mechanical restriction and 20 healthy age- and sex-matched controls will be recruited from a database of volunteers and from the Interstitial Lung Disease and Respirology clinics at Hotel Dieu Hospital. Participants with cardiovascular, or any other condition that contributes to dyspnea or abnormal cardiopulmonary responses to exercise will be excluded. After giving written informed consent, all participants will complete 7 visits, conducted 2 to 7 days apart. Visit 1 (screening): medical history, pulmonary function testing and a symptom limited incremental CPET. Visit 2: Standard CT examination conducted at KGH Imaging. Visit 3: assessment of resting chemoreceptor sensitivity, followed by a symptom limited incremental CPET to determine peak work rate (Wmax). Visits 4 & 5 (run-in): familiarization to standardized constant work rate (CWR) CPET to symptom limitation at 75% Wmax. Visits 6 & 7 (Randomized & Blinded): CWR CPET to symptom limitation while breathing a gas mixture with either 1) 40 ppm iNO or 2) placebo [medical grade normoxic gas, 21% oxygen]. The proposed work has the potential to provide important physiological insights into the underlying mechanisms of heightened dyspnea, as well as examine therapeutic avenues to improve quality of life in patients with IPF.