117 Clinical Trials for Various Conditions
The purpose of this research study to understand how prior respiratory infections affect the susceptibility to lung inflammation following environmental exposures.
This study will evaluate the effect of CPAP therapy on esophageal pH and lung inflammation in patients with idiopathic pulmonary fibrosis (IPF) and sleep apnea.
An informational evaluation of COVID-19 patients who receive low-level laser therapy in addition to a normal regimen of treatment for symptoms associate with COVID-19. Results are compared to statistical observations published in literature from patients receiving standard care for COVID-19 symptoms without low-level laser therapy.
To determine if a reduction of pneumonic inflammation occurs after treatment with Low-Level Laser Therapy (LLLT) applying red-light technology in the respiratory system of COVID-19 patients suffering from acute viral pneumonia.
Primary Objective: • To assess the effect of dupilumab on lung inflammation and related changes in airway volumes detectable by functional respiratory imaging Secondary Objective: * To evaluate the effect of dupilumab at Week 24 on bronchodynamics, hyperinflation, airway resistance, airway wall thickness, ventilation defects and mucus plugging derived from high-resolution computed tomography (HRCT) scans, patient-reported outcomes, FeNO and spirometry. * To evaluate safety of dupilumab
The purpose of this study is to gain understanding of mechanisms whereby bariatric surgery modulates pulmonary inflammation and pulmonary microbiome composition and how these changes direct the pathobiology of human obese asthma.
The purpose of this research is to measure the extent of lung inflammation between different groups of participants using a radioactive tracer called \[18F\]NOS. A radioactive tracer is a type of imaging drug that is labeled with a radioactive tag and injected into the body.
The primary objective of this study is to assess the lung distribution of the Positron Emission Tomography (PET) imaging radiotracer Cu-DOTA-ECL1i, which binds to the specific population inflammatory cells, in patients with fibrotic lung diseases. This objective includes sub-studies to assess radiotracer distribution in the lung, the reproducibility of PET scans and the relationship of the scan to distribution of inflammatory cells in human lung tissue. The overall goal is to assess the potential of the radiotracer to track inflammatory cells in lung diseases.
The purpose of this study is to determine if using e-cigarettes (ECIG) rather than regular tobacco cigarettes alters lung inflammation in people with and without HIV. The study is also interested in asking subjects their opinion on the use of ECIG and how they make them feel. This study is for research purposes only and is not intended to treat asthma or HIV or to modify tobacco use.
Pulmonary contusion (PC) is a significant problem after blunt trauma that may often lead to acute respiratory distress syndrome (ARDS) and in some patients, death. Although the pathophysiology is incompletely understood, it is clear that there is a biochemical process involving changes in the inflammatory milieu after contusion which occurs in addition to simple direct mechanical injury to the lung. The relationship of severity of contusion on imaging, disturbances in the inflammatory phenotype, and outcome is unknown. This is a prospective, observational study which will evaluate the size and severity of contusion as measured on chest computed tomography (CT). Inflammatory mediators will be measured in the bronchoalveolar lavage (BAL) and in the serum of patients with pulmonary contusion to define the inflammatory nature of the post-contusion lung. The degree of abnormality within the inflammatory parameters will be correlated with lung contusion size and subsequent patient outcomes. These data will be compared to other patient groups: 1) Trauma patients without chest injury who are mechanically ventilated; 2) Uninjured patients undergoing elective surgical procedures that will require intubation and mechanical ventilation; 3) Patients in the Medical ICU who are mechanically ventilated with acute respiratory failure. The hypothesis tested within this study is resolution of lung injury is dependent upon the presence of Tregs in the alveolar space.
The purpose of this study is to learn more about the basic responses of the lungs to inflammation using positron emission tomography, or PET, imaging scans of the lungs. PET is a machine that detects radiation and generates pictures using a donut-shaped scanner similar in appearance to an x-ray "CAT" or computed tomography (CT) scan or an MRI. Inflammation is the way our bodies react to irritation or injury, and involves red, warm, and often painful swelling of the affected tissue. An enzyme called inducible nitric oxide synthase (iNOS) contributes to the development of lung inflammation.
The purpose of this study is to determine whether IL-17 polymorphonuclear leukocytes (PMNs) are central to the disease pathology in CF. This will be determined by demonstrating that IL-17 PMNs are present in the CF airway, correlate with lung function measures, and decrease in patients being treated with IV antibiotics for a pulmonary exacerbation.
The goal of this study is to investigate acute respiratory distress syndrome (ARDS) and septic lung with positron emission tomography (PET) imaging and to examine the distribution of inflammation, as measured by neutrophil metabolic activity.
The current treatment of individuals with alpha-1 antitrypsin deficiency (AATD) who develop lung disease (COPD) is the administration of intravenous purified alpha-1 antitrypsin (augmentation therapy) at a fixed dose of 60 mg/kg per week. This dose aims at increasing the deficient AAT serum levels just above a predetermined "safety threshold" of 11 uM. However, normal levels of AAT are between 25-50 uM. AAT has shown not only to inhibit lung proteases such as neutrophil elastase, but also to modulate inflammation. Given that many subjects with AATD who receive augmentation therapy still have significant lung disease and inflammation, this study will evaluate whether doubling the dose to 120 mg/kg/week has an effect in decreasing lung inflammation. Only the dosing of 60 mg/kg /week has received FDA approval. FDA has granted an IND number to this study to test the higher dose of 120 mg/kg/week. The study will evaluate systemic (serum) and pulmonary (bronchoscopy samples)markers of inflammation in 3 phases: standard dose (4 weeks), double dose (4 weeks) and standard dose (4 weeks).
Chronic obstructive pulmonary disease (COPD) and lung cancer are leading causes of death and health care use. Diffuse airways inflammation is seen in COPD and is thought to be the reason for deterioration of lung function in COPD. Currently there is no medication available that can modify or reduce this inflammation. Furthermore, from literature review it has been shown that chronic inflammation can result in cancerous changes. Curcumin is a food additive used for centuries. Several studies showed that curcumin suppress the different inflammatory pathways. Specially, the TNF-alpha and the NF kappa-b are down regulated by this substance. This study was designed to evaluate effect of combination of curcumin+Bioprine on sputum cytology in patients with COPD. This is double-blind randomized pilot study.
The purpose of this study is to find out if there is a link between cigarette smoking, inflammation and the spread of breast cancer to the lung. We think that women who are current or former smokers may be at increased risk for breast cancer spreading to the lung compared to women who have never smoked. Smoking causes inflammation in the lung in some women. Researchers at Memorial Sloan-Kettering (MSKCC) think that smoking-related lung inflammation may increase the chance of breast cancer spreading to the lung. In order to find out whether inflammation plays a role in breast cancer spreading to the lung, we will measure a urinary marker of lung inflammation. This will allow us to determine if this marker is more commonly elevated in women with breast cancer that has spread to the lung compared to those without breast cancer in the lung. We will also collect DNA from blood to have the opportunity to determine if there are differences in DNA in women with or without breast cancer that has spread to the other sites including the lung. We will also collect blood to determine if we can identify risk factors for the spread of breast cancer to the lungs.
This Phase IIB proof-of-concept study would examine the effects of an investigational product called N-acetylcysteine (NAC) on the basic processes that cause inflammation in CF lung disease. We hope to learn more about the causes of lung disease in cystic fibrosis by studying the characteristics of the inflammation in the lungs of patients who have CF.
This study will evaluate how heartburn may lead to different types of inflammation in one's airways. Additionally, the study will determine whether aggressive treatment of heartburn results in improvement in both symptoms of heartburn and asthma but also in documented improvement in airway inflammation as determined by biopsy. The results of this study will be important in directing future research into the relationship between heartburn and asthma and may provide a clue whether certain subtypes of asthma may be caused primarily by gastroesophageal reflux (GER).
This study will examine in healthy volunteers how breathing carbon monoxide (CO) affects lung inflammation. Severe lung inflammation sometimes develops in patients with pneumonia or patients who develop serious blood stream infections. Studies in the laboratory and in animals show that CO can decrease lung inflammation. Healthy volunteers between 18 and 40 years of age who do not smoke, are not taking any medications, do not have asthma, are not allergic to sulfa- and penicillin-based drugs, and are not pregnant may be eligible for this study. Candidates are screened with a medical history and physical examination, blood and urine tests, electrocardiogram (EKG), and chest x-ray. Subjects are enrolled in either a pilot study or the main study. Participants undergo bronchoscopy and bronchoalveolar lavage to study the effects of endotoxin (a component of bacteria that causes inflammation similar to that in patients with lung infections) on lung function. Before the procedure, a small plastic tube (catheter) is placed in a vein to collect blood samples and another is placed in an artery to check blood pressure. For the bronchoscopy, the mouth and nasal airways are numbed with lidocaine, and a bronchoscope (thin flexible tube) is passed through the nose into the airways of the lung. A small amount of salt water is squirted through the bronchoscope into one lung and then salt water containing endotoxin is squirted into the other lung. Following the bronchoscopy, subjects are treated with either CO or room air (placebo) for 6 hours. (Subjects in the pilot study receive treatment for only 3 hours). The gas is delivered through a cushioned mask placed over the nose and mouth. The amount of exhaled CO is measured before, during, and after inhalation of the gas. For this measurement, subjects take a deep breath to fill up their lungs and slowly exhale into a mouthpiece connected to a measuring device until they feel their lungs are empty. After the CO treatment, a second bronchoscopy is done to examine how the lung responded to the CO or room air. This is studied in two ways. To sample the air, a large needle is used to withdraw air through the bronchoscope over about 3 seconds. Then the areas of the lung that were squirted with salt water alone and with endotoxin and salt water and are rinsed (lavage) and cells and secretions are collected. ...
Asthma is a chronic inflammatory disease. We propose to study inflammatory changes in the lungs of subjects with atopic asthma of different severity in vivo using positron emission tomography (PET) with 2-deoxy-2-\[18F\]fluoro-D-glucose (FDG). It has been shown that the uptake of FDG as detected by PET scanning correlates with inflammation in animal models as well as in human disease processes such as sarcoidosis, tuberculosis and abscess formation. In addition, it has been shown that the inflammation associated with allergen challenge in patients with atopic asthma can be visualized using PET scanning with FDG. We hypothesize that the degree of FDG-uptake as a measure of inflammation correlates with the severity of asthma as determined by pulmonary function tests and clinical signs and symptoms. In addition, information about the spatial distribution of the inflammatory changes will be obtained. To compare the characteristics of the inflammation in asthma with non-asthmatic inflammation of the lung, the images obtained in asthmatic subjects will be compared with images from subjects who have inflammatory changes of the lung caused by Wegener's granulomatosis. Subjects with atopic asthma and non-atopic control subjects will be selected from the community and, if eligible for the study, undergo skin testing against common allergens and pulmonary function testing. Subjects with Wegener's granulomatosis will be selected from a large group of subjects followed with this disease at NIAID. PET scanning with FDG will be used to measure inflammation in the PET scanning facility at the Clinical Center of the NIH and the results of the scanning will be correlated with the severity of the disease. We expect that for the first time this methodology will permit an objective measure of the basic pathogenic process, the allergic inflammation, in patients with atopic asthma. Using this methodology it will be possible to study the efficacy of currently available therapies for allergic inflammation. In addition, this methodology will provide an extremely useful tool for the development of new therapeutic approaches to the treatment of asthma.
The primary purpose of this study is to measure pulmonary function, symptoms, and pulmonary inflammatory responses in healthy young adults during and immediately after exposure to a low concentration of ozone (0.070 ppm) or clean air for 6.6 hours while at rest. This concentration is the current EPA NAAQS standard for ozone.
Background: - When bacteria enter the lungs, serious infections can occur. Researchers want to learn more about the process of inflammation in the lungs by studying lung cells and the products that they make. Lung cells are influenced by infections, smoking, and molecules made within the body. Researchers also want to learn more about one of these molecules, called microRNA (or micro ribonucleic acid). Objective: - To better how the body responds to infection. Also, to understand which cells in the lung secrete microRNA and how they may influence other lung cells. Eligibility: - Healthy, non-smoking adults ages 18-45. Design: * Participants will be screened with a medical history and physical exam. They will have blood and urine tests and an electrocardiogram. * Participants will have blood drawn from an arm vein. They will have an intravenous catheter (small plastic tube) placed in a vein. * All participants will have bronchoscopy with bronchoalveolar lavage. They will be numbed with medicine. A thin flexible tube will be placed through the nasal passages or the mouth into the airways of the lung. * Some participants will have bronchoscopy with bronchoalveolar lavage (rinsing the airways with salt water) in order to obtain cells from lung. The water will then be suctioned out. * Some participants will have two bronchoscopies; during the first procedure, endotoxin, a molecule found in bacteria is squirted into a small portion of the lung. Endotoxin is a molecule that acts like an infection but isn t one. After 6 to 48 hours, bronchoscopy with with bronchoalveolar lavage will be done to look at the lung s response to endotoxin. * Participants heart rhythm and rate, temperature and blood oxygen level will be monitored during the procedures. * Participants will be called the next day to see how they are feeling.
The purpose of this research study is to gain understanding of the basic responses of the lung to inflammation and specifically if a certain medication can reduce the inflammation alone or in combination with another. Inflammation is the way our bodies react to irritation or injury, and involves red, warm, and often painful swelling of the affected tissue. "Acute lung injury" involves inflammation that is not specific to one area of the lung and is caused by any one of several conditions: infection, trauma, breathing toxic substances, etc. When lung injury is severe, not enough oxygen can get into the body; this can lead to the need for mechanical support of breathing (mechanical ventilation), problems with brain, heart or other organ function, and in some cases, death.
In this randomized, double-blind, placebo controlled trial we used positron emission tomography to determine if lovastatin or recombinant human activated protein C exhibit anti-inflammatory effects in humans following intrabronchial installation of lipopolysaccharide (LPS or endotoxin).
Background: The lung is a privileged organ; blood does not reflect most lung processes well, if at all. Therefore, for population scale diagnostics, the investigator team is developing non-invasive portals to the lung, for eventual early detection/risk assessment and diagnostic purposes. However, large macromolecules are not likely suspended nor readily detected in the breath. In particular, genomic DNA in the breath condensate (EBC) is very sparse, and where present, generally highly fragmented, not readily amenable to sequencing based assessments of DNA somatic mutation burden or distribution. Because gDNA (and protein) is challenging to obtain non-invasively from EBC, the study team considered alternative surrogate lower airway specimens. Cough capture is rarely done, and the investigator team is in the process of optimizing its collection. Importantly, the team will be evaluating how much of coughed material is from saliva contamination. Additionally, analyzing material that is target captured by capturing deep lung extracellular vesicles (EVs) using immobilized CCSP/SFTPC antibodies targeting EVs from distal bronchiole Club and alveolar type 2 cells could circumvent the mouth contamination problem, leaving a non-invasive portal to the deep lung suitable for large molecules, and in turn suitable for myriad epidemiologic and clinical applications. Proposal: The investigator team proposes (Aim 1) to pursue optimizing cough collection, and testing the efficacy and practicality of partitioning cough specimen for deep-lung specific extra-cellular vesicles (EVs). This cough specimen will be compared to that from invasively collected deep lung samples BAL/bronchial brushings, and to the potential contaminating mouthrinse, all from the same individuals. (Aim 2) The study team initially proposes to examine these cough specimens for somatic mutations by SMM bulk sequencing for single nucleotide variation, developed in the Vijg/Maslov labs. Finally, the investigator team will (Aim 3) test all airway specimens (cough, mouthwash and BAL) for lung surrogacy of cough, using proteins known to be specific for lung, as opposed to oral cavity/saliva, in the Sidoli/proteomics core. Impact: The investigator team envisions that the translational impact of non-invasively obtained DNA or protein markers could allow for more rapid acute clinical diagnoses, and facilitate precision prevention and/or early detection of many acute and chronic respiratory disorders, including lung cancer, asthma and COPD, acute and chronic infectious diseases, and indeed systemic disorders of inflammation and metabolism.
The aim of this study is to determine whether the use of steroids versus watchful waiting improves pulmonary function tests in patients with history of COVID 19 infection who have residual hypoxemia and lung infiltrates. This is a non-inferiority trial which tests whether the outcomes after watchful waiting are not worst than after the use of steroids, with a margin of acceptable inferiority. The study team will limit inclusion to patients who have PCR- confirmed COVID19 at least in 10-weeks prior to enrollment, persistent opacities on chest imaging, and hypoxemia either at rest or during ambulation.
More than 17 million people have been infected and more than 677K lives have been lost since the COVID-19 pandemic. Unfortunately, there is neither an effective treatment nor is there a vaccination for this deadly virus. The moderate to severe COVID-19 patients suffer acute lung injury and need oxygen therapy, and even ventilators, to help them breathe. When a person gets a viral infection, certain body cells (inflammatory/immune cells) get activated and release a wide range of small molecules, also known as cytokines, to help combat the virus. But it is possible for the body to overreact to the virus and release an overabundance of cytokines, forming what is known as a "cytokine storm". When a cytokine storm is formed, these cytokines cause more damage to their own cells than to the invading COVID-19 that they're trying to fight. Recently, doctors and research scientists are becoming increasingly convinced that, in some cases, this is likely what is happening in the moderate to severe COVID-19 patients. The cytokine storm may be contributing to respiratory failure, which is the leading cause of mortality for severe COVID-19 patients. Therefore, being able to control the formation of cytokine storms will also help alleviate the symptoms and aid in the recovery of severe COVID-19 patients.
This is a multicenter, randomized, double-blind, parallel group study to investigate the efficacy of pemziviptadil (PB1046) by improving the clinical outcomes in hospitalized COVID-19 patients at high risk for rapid clinical deterioration, acute respiratory distress syndrome (ARDS) and death. The study will enroll approximately 210 hospitalized COVID-19 patients who require urgent decision-making and treatment at approximately 20 centers in the United States.
This Phase 2 study will evaluate the efficacy, safety, pharmacodynamics and pharmacokinetics of inhaled TD-0903 compared with a matching placebo in combination with standard of care (SOC) in hospitalized patients with confirmed COVID-19 associated acute lung injury and impaired oxygenation.
It is hypothesized that instillation of Liothyronine Sodium (T3) into the airspace will be safe, well tolerated, and will increase alveolar fluid clearance and decrease inflammation in patients with ARDS, reflected in improved oxygenation index (OI) and oxygenation saturation index (OSI).