View clinical trials related to Pulmonary Alveolar Proteinosis.
Filter by:By updating the chest HRCT scoring criteria of patients with pulmonary alveolar proteinosis, a new and more perfect system for evaluating the severity of alveolar proteinosis will be established.
The purpose of this study is to determine the safety and tolerance of an oral administration of methionine in the treatment of pulmonary alveolar proteinosis due to the double mutation Ala393Thr / Ser567Leu in the MARS gene. This disease is very severe and especially leads to chronic respiratory insufficiency. There is no curative treatment for this disease. The MARS gene encodes the methionine tRNA synthetase (MetRS). Mutations in this gene leads to a defect in MetRS function. In cultured mutated yeast, addition of methionine in culture medium restores MetRS function. Therefore, the investigators hypothesized that treatment of patients with methionine could have beneficial effects on the disease.
The major goal of this study is to conduct a prospective, longitudinal study of autoimmune PAP to examine outcome measures for disease severity of potential use in clinical practice and/or clinical research studies. These results will impact the field by: 1) improving an understanding of the clinical course of autoimmune PAP, 2) providing information on various clinical outcome and quality of life outcome measures to guide patients and physicians in making treatment choices, and 3) facilitate the development of pharmaco-therapeutics for autoimmune PAP and 4) better informing PAP researchers.
Clinical trial for subjects with autoimmune pulmonary alveolar proteinosis (aPAP) who have completed the IMPALA trial (NCT02702180). At the Baseline visit, eligible subjects may continue or re-start treatment with 300 µg inhaled molgramostim (recombinant human Granulocyte-Macrophage Colony Stimulating Factor; GM-CSF) administered intermittently in cycles of seven days molgramostim, administered once daily, and seven days off treatment. Subject will be treated with inhaled molgramostim for up to 36 months. During the trial, whole lung lavage will be applied as rescue therapy.
Pulmonary alveolar proteinosis (PAP) is a syndrome of surfactant accumulation, respiratory failure, and innate immune deficiency for which therapy remains limited to whole lung lavage (WLL), an invasive physical procedure to remove surfactant unavailable at most medical centers. While PAP occurs in multiple diseases affecting men, women, and children of all ages and ethnic origins, in 85% of patients, it occurs as an idiopathic disease associated with neutralizing GM-CSF autoantibodies. Basic science and translational research has shown that idiopathic PAP is an autoimmune disease in which disruption of GM-CSF signaling impairs the ability of alveolar macrophages to clear surfactant and perform host defense functions. Recently, it has been shown that cholesterol toxicity drives pathogenesis in alveolar macrophages from GM-CSF deficient (Csf2-/-) mice and patients with autoimmune PAP. Loss of GM-CSF signaling reduces PU.1/CEBP-mediated expression of PPARĪ³ and its downstream target ABCG1 (a cholesterol exporter important in macrophages). The cell responds by esterifying and storing cholesterol in vesicles to reduce toxicity. Eventually, vesicles fill the cell, impair intracellular transport and reduce uptake and clearance of surfactant from the lung surface resulting in disease manifestations. Recent data indicates that pioglitazone, a PPARĪ³ agonist currently approved by the FDA for human use, increases cholesterol/surfactant clearance by alveolar macrophages from autoimmune PAP patients and Csf2-/- mice. Importantly, pioglitazone significantly reduced the severity of PAP lung disease in Csf2-/- mice after several months of therapy. Together, these observations suggest pioglitazone could be 'repurposed' as pharmacologic therapy for PAP.
The purpose of this study is to (1) compare a technically improved assay with an existing assay used to measure serum anti-GM-CSF antibodies in stored serum samples previously obtained from patients diagnosed with either primary, secondary, congenital or idiopathic pulmonary alveolar proteinosis (PAP), other chronic diseases or disease-free, healthy individuals; (2) determine the prevalence and levels of anti-GM-CSF autoantibodies and (3) define the breadth of the autoimmune antibody responses in primary PAP patients from the United States, Japan, Australia, and Europe using previously collected serum samples; and (4) using a chart review approach, compare the clinical, radiologic and laboratory features of primary PAP patients to determine if differences exist among patients in these globally geographically distributed regions.
Autoimmune PAP is a rare lung disease affecting less than 5,000 individuals in US with no FDA-approved pharmacologic therapy. Results from "off-label" use in case reports and clinical studies completed outside of the US indicate that inhaled rhGM-CSF may be a safe and effective thera-py for autoimmune PAP. Preliminary clinical trials of inhaled rhGM-CSF in autoimmune PAP patients show promising results, 62%-96% therapeutic response rate without any identifiable drug-related adverse effects in at least 73 autoimmune PAP patients. However, the pharmacokinetics (PK), pharmacodynamics (PD), optimal dose, and treatment duration to maximize efficacy are unknown. The goal is to begin to address these knowledge gaps for inhaled sargramostim for autoimmune PAP patients with a pilot safety and PK/PD study (TPSC-110). TPSC-110, PharmPAP, which is a self-controlled open-label, phase I study to evaluate the safety, PK, and PD of inhaled sargra-mostim in autoimmune PAP patients. These results will impact the field by 1) confirming existing published data, 2) monitoring the local effects of inhaled sargramostim in autoimmune PAP patients, 3) potentially demonstrating a safe starting dose for a later trial to evaluate the therapeutic efficacy of inhaled sargramostim for autoimmune PAP.
Objective: Evaluate Pharmacokinetics and determine the safety of GM-CSF single dose inhalation. Study Design: Pharmacokinetic open study
Objective: Determine the safety and efficacy of GM-CSF inhalation in patients with aPAP. Study Design: multi-center, randomized, double-blind, placebo- controlled, safety/efficacy study.
This study evaluates inhaled molgramostim (recombinant human granulocyte macrophage-colony stimulating factor [rhGM-CSF]) in the treatment of autoimmune pulmonary alveolar proteinosis (aPAP) patients. A third of the patients will receive inhaled molgramostim once daily for 24 weeks, a third will receive inhaled molgramostim intermittently (7 days on, 7 days off) for 24 weeks and a third will receive inhaled matching placebo for 24 weeks.