Clinical Trials Logo

Clinical Trial Summary

The purpose of this study is to find out if combining a state-of-the-art form imaging modality with metabolomics in different types of Interstitial Lung Diseases (ILD) patients compared to controls with chronic obstructive pulmonary disorder (COPD)/emphysema and healthy controls will be a better predictor of disease progression. ILD's are a group of chronic, progressive lung diseases. The most common ILD is idiopathic pulmonary fibrosis (IPF). Metabolomics provides a "snapshot" in time of all metabolites present in a biological sample. The imaging procedure should take approximately 20 minutes. All study related collections of samples will be done in a single visit if possible. There are no direct benefits to participants. This is not a treatment study.


Clinical Trial Description

Interstitial lung diseases (ILD) are a group of chronic, progressive lung disorders. The most common ILD is idiopathic pulmonary fibrosis (IPF) with an average survival ranging between 2.5-5 years after diagnosis. The term pulmonary fibrosis means scarring of the lung tissue and is the cause of worsening shortness of breath. IPF can frequently affect the tissue between the air sacs in the lung called the interstitium and many other areas in lung (blood vessels and air passage ways). Earlier diagnosis of ILD is a prerequisite for better long-term outcomes. However, disease detection and assessment of progression are reliant on many varying host and environmental influences. As a result, patients with ILD are often misdiagnosed early in the disease process. Moreover, patients diagnosed with ILD have different disease courses and predicting which patient is at risk of progression is a challenging problem. Many personalized medicine approaches are being developed but there is a lack of available biomarkers in clinical practice. Biomarkers comes from a new experimental technique called metabolomics which is becoming widely used in medicine and biology for studying living organisms. The method measures the levels of large numbers of naturally occurring small molecules (called metabolites) that are present in the blood, saliva, breath and tissues. The pattern, or fingerprint, of metabolites in human samples can be used to learn about the health of an organism and perhaps allow physicians to diagnose, treat, and follow the progress of specific diseases. Clinical and functional models lack predictive ability to detect patients at risk of disease progression. Thus, there is an urgent need to develop accurate prediction models for disease diagnosis and assess treatment effects. CT-derived ventilation (CT-V) imaging includes quantitative lung function imaging and lung compliance imaging. CT-V is a newer image processing based technique that uses mathematical modeling and scientific computing to gather changes in lung tissue volumes during the breathing cycle. Beaumont is currently using CT-V for radiotherapy planning. CT-V produces a full 3D map of ventilation/breathing, has better image resolution, provides pertinent measurable imaging information, and does not require a contrast agent. Thus, high-resolution anatomical and functional information can be derived using CT-V. To better understand the functional and radiographic changes seen in patients with ILD, there is a need to further examine the downstream changes occurring at the level of proteins and metabolites. Metabolomics provides a "snapshot" in time of all metabolites present in a biological sample. Proteins alone or integrated with other systems, is a particularly informative tool for understanding disease biology in ILD patients.Using an untargeted metabolomics platform and profiling serum and breathe from the patients will determine if additional or more robust biomarkers of disease can be identified and, in conjunction with the assessment of regional ventilation differences through CT-V, will provide a better insight into disease process and further help with accurate prognostication. Participants who have consented for the study and have meet all the inclusion criteria and none of the exclusion criteria will have one full inspiration and expiration CT, and two 4D-CT scans under two different pressures (5 and 10 cm water), except for healthy volunteers. They will have their breath profiled using Owlstone platform and serum collected for metabolomics testing within one week period. Participants will be asked to refrain from smoking one day prior to the study date. All study related sampling will be done in a single visit if possible and if not possible all study procedures and samples will be collected within a one week period. Disease progression will be assessed using chart review over the next 24 months to assess standard of care pulmonary function evaluation and corresponding CT features respiratory hospitalizations and mortality. ;


Study Design


Related Conditions & MeSH terms


NCT number NCT04119115
Study type Observational
Source William Beaumont Hospitals
Contact
Status Terminated
Phase
Start date September 30, 2021
Completion date October 20, 2022

See also
  Status Clinical Trial Phase
Recruiting NCT04638517 - The TELO-SCOPE Study: Attenuating Telomere Attrition With Danazol. Is There Scope to Dramatically Improve Health Outcomes for Adults and Children With Pulmonary Fibrosis Phase 2
Recruiting NCT05299333 - Comparison of Pulmonary Telerehabilitation and Physical Activity Recommendations in Patients With Post Covid Fibrosis N/A
Completed NCT01615484 - Ex-vivo Perfusion and Ventilation of Lungs Recovered From Non-Heart-Beating Donors to Assess Transplant Suitability N/A
Completed NCT01417156 - Safety and PK Study of BIBF 1120 in Japanese Patients With IPF: Follow up Study From 1199.31(NCT01136174) Phase 2
Terminated NCT00981747 - Targeting Vascular Reactivity in Idiopathic Pulmonary Fibrosis Phase 2/Phase 3
Completed NCT00001596 - Oral Pirfenidone for the Pulmonary Fibrosis of Hermansky-Pudlak Syndrome Phase 2
Completed NCT00052052 - An Open-Label Study of the Safety and Efficacy of Subcutaneous Recombinant Interferon-Gamma 1b (IFN-Gamma 1b) in Patients With Idiopathic Pulmonary Fibrosis (IPF) Phase 2
Completed NCT01442779 - Clinical Trial of Low Dose Oral Interferon Alpha in Idiopathic Pulmonary Fibrosis Phase 2
Completed NCT00366509 - Role of Helicobacter Pylori and Its Toxins in Lung and Digestive System Diseases
Recruiting NCT00001532 - Role of Genetic Factors in the Development of Lung Disease
Recruiting NCT04767074 - A Non-pharmacological Cough Control Therapy N/A
Recruiting NCT04864990 - Dyspnea and Idiopathic Pulmonary Fibrosis
Completed NCT01961362 - Supplemental Oxygen in Pulmonary Fibrosis
Completed NCT01271842 - Long-term Outcome and Lung Capacity in Survivors of ARDS Due to Influenza A (H1N1) v2009 The RESPIFLU Study N/A
Completed NCT00650091 - Evaluating the Effectiveness of Prednisone, Azathioprine, and N-acetylcysteine in Patients With IPF Phase 3
Active, not recruiting NCT00258544 - Microarray Analysis of Gene Expression in Idiopathic Pulmonary Fibrosis (IPF)
Enrolling by invitation NCT04930289 - Global Utilization And Registry Database for Improved preservAtion of doNor LUNGs
Completed NCT02055222 - Clinical Outcomes and Molecular Phenotypes in Smokers With Parenchymal Lung Disease
Enrolling by invitation NCT06327360 - Illness Expectations in Pulmonary Fibrosis
Completed NCT06457269 - Evaluating the Potential of Large Language Models for Respiratory Disease Consultations N/A