Safety and Efficacy Study of the Use of Sodium Pyruvate Bronchodilation in Asthmatics

Study Results

Results pending

The study team has not published outcome measurements, participant flow, or safety data for this trial yet. Check back later for updates.

Basic Information

Get a concise snapshot of the trial, including recruitment status, study phase, enrollment targets, and key timeline milestones.

Recruitment Status

TERMINATED

Clinical Phase

PHASE1/PHASE2

Total Enrollment

20 participants

Study Classification

INTERVENTIONAL

Study Start Date

2006-01-31

Study Completion Date

2006-09-30

Brief Summary

Review the sponsor-provided synopsis that highlights what the study is about and why it is being conducted.

Sodium pyruvate in sodium chloride solution will be delivered by nebulization to the lungs. It is believed that this administration will produce bronchodilation in asthmatics as determined by improvement in FEV1. FEV1 is a measure of lung function, and will be determined after administration of sodium pyruvate. The study is a blinded, so subjects may receive either the sodium pyruvate or a sodium chloride placebo. The primary endpoint will be the improvement of FEV1 after 15 minutes in subjects receiving sodium pyruvate compared to the FEV1 of subjects receiving the sodium chloride placebo.

Related Clinical Trials

Explore similar clinical trials based on study characteristics and research focus.

Phase1, Placebo-Controlled, Randomized, Double-blind, Single-ascending Dose Study in Healthy Subjects.

NCT02616770

Asthma

COMPLETED PHASE1

Dose Response Effects of Inhaled Fluticasone on Airway Effects of Hypertonic-saline in Asthma

NCT00606242

Asthma

COMPLETED PHASE4

Mucociliary Clearance in Healthy Subjects: Comparison of Levalbuterol and Racemic Albuterol

NCT00325767

Mucociliary Clearance

COMPLETED PHASE4

A Study to Test if a Fixed-Dose Combination of Fluticasone Propionate/Albuterol Sulfate is Effective in Preventing Asthma Exacerbations

NCT06052267

Asthma

RECRUITING PHASE3

Pharmacodynamic Bioequivalence Study of Albuterol Sulfate Inhalation Aerosol, 0.09 mg Albuterol Base/ Inhalation

NCT05292976

Bronchial Asthma

WITHDRAWN PHASE3

Detailed Description

Dive into the extended narrative that explains the scientific background, objectives, and procedures in greater depth.

Sodium Pyruvate, an intermediate metabolite, has been investigated as a therapeutic agent to reduce reactive oxygen species in the lung. Evaluation of FEV1 as a safety parameter and sequela of reactive oxygen species reduction identified inhaled Sodium Pyruvate as a potential bronchodilator.

A number of lung diseases are typically characterized by marked inflammation at the site of the lung injury. This inflammatory process leads to further destruction of surrounding healthy lung tissue, and a continuation and expansion of the sites of inflammation. This inflammatory process results in the production of reactive oxygen species, including superoxide anions and hydrogen peroxide, at the site of inflammation.

Nitric oxide is a known bronchodilator, as well as a vasodilator. It has been used successfully used to treat patients with various pulmonary disorders. 1 When endogenous nitric oxide is exposed to oxygen radicals, however, it is converted to the toxic oxidant nitrogen dioxide, and its bronchodilating effect is mitigated. Conversely, nitrogen dioxide is a known deep lung irritant. Its adverse consequences include the following: pulmonary inflammation; reduced levels of lung antioxidants 2; impairment of respiratory defense mechanisms leading to increased susceptibility to respiratory pathogens 3 and increased incidence and severity of respiratory infections; reduced lung function, and increased asthma and COPD symptoms.

Reactive oxygen species, especially superoxide anions, are known to compromise lung function by increasing bronchoconstriction. As a result of the increasing inflammation and the production of reactive oxygen species, and the decrease in nitric oxide that is believed to occur with the interstitial lung diseases, healthy tissue is damaged and lung function is compromised.

Based on our present understanding of the disease process involved with these lung diseases, it appears that an intervention in the inflammatory process that would result in a reduction in reactive oxygen species and a subsequent increase in nitric oxide could be an effective way to intervene in the disease process. This intervention would prevent the further spread of inflammation and lung damage caused by the production of reactive oxygen species, such as superoxide anions and hydrogen peroxide, and increase lung function by increasing bronchodilation.

Sodium pyruvate is a reactive oxygen species antagonist that has been shown to neutralize oxygen radicals, specifically lowering the overproduction of superoxide anions, regulate the production and level of other inflammatory mediators, and increase the synthesis of nitric oxide. 4 Sodium pyruvate also increases cellular levels of glutathione, a major cellular antioxidant, which is reduced dramatically in antigen-induced lung disease patients. 5

In pilot studies in mild asthmatic subjects, it was demonstrated that inhalation of low doses (0.5 mM) of nebulized sodium pyruvate decreased expired hydrogen peroxide by 30% at four hours compared to inhalation of a nebulized saline control. These subjects also experienced increased pulmonary function as determined by FEV1 (+12.8%) and PEF (+34.5%) measurements after four hours (referenced in Cellular Sciences IND #50,089). It is theorized that the reactive oxygen species antagonist properties of sodium pyruvate reduced the production of oxygen radicals, including hydrogen peroxide, and increased the levels of nitric oxide. Together, this led to reduced inflammation and lung damage, and increased lung function through improved bronchodilation.

In summary, it is believed that inhalation of sodium pyruvate will reduce the lung damage resulting from the increase in reactive oxygen species associated with the inflammation component of the disease, and will enhances the availability of nitric oxide to produce bronchodilation by enhancing its synthesis and protecting it from destruction by reactive oxygen species.

Experimental Clinical Protocol Hypothesis: Sodium Pyruvate delivered by nebulization to the lungs produces bronchodilation in asthmatics as measured by FEV1

Intent: Provide support for further drug development of nebulized Sodium Pyruvate as a therapeutic agent in asthma

Design Randomized, double-blind, placebo-controlled cross-over study of 52 completed subjects

Treatment 1: 0.5 mM sodium pyruvate in 0.9% saline solution, (5ml) (Cellular Sciences, CA) nebulized via a Pari LC Plus(R) reusable nebulizer powered by a ProNeb(R) compressor (Midlothian, VA) Treatment 2: Saline 0.9%, (5ml) (Baxter) nebulized using the same nebulizer system as above A randomization algorithm using random permuted blocks (4-8 subjects) will be used to generate treatment order assignments. An unblinded statistician will generate this list of treatment order assignments.

Patient Recruitment and Selection The large cohort of potential subjects who have previously participated in asthma studies through our clinical research laboratory will be apprised of the study. Patients attending the UCLA Asthma and Cough Center will also be informed of the study. Advertisements will be sent by regular mail and by e-mail to physicians participating in the UCLA Healthcare System and to local pulmonologists practicing throughout the Los Angeles area. Local Allergists who collaborate with us in common clinical trial protocols will be informed of the study by personalized letter and e-mail. Advertisements will be placed in the classified and/or health sections of local newspapers. A description of the study will be posted on internet sites featuring clinical research trials.

Subjects will be recruited until a total of 52 complete the study. Assuming a 5% drop-out and non-compliance rate, we expect a total of 55 subjects recruited Patient Eligibility Criteria

Conditions

See the medical conditions and disease areas that this research is targeting or investigating.

Moderate Asthma

Study Design

Understand how the trial is structured, including allocation methods, masking strategies, primary purpose, and other design elements.

Allocation Method

RANDOMIZED

Intervention Model

PARALLEL

Primary Study Purpose

TREATMENT

Blinding Strategy

QUADRUPLE

Participants Caregivers Investigators Outcome Assessors

Interventions

Learn about the drugs, procedures, or behavioral strategies being tested and how they are applied within this trial.

sodium pyruvate

Intervention Type DRUG

Eligibility Criteria

Check the participation requirements, including inclusion and exclusion rules, age limits, and whether healthy volunteers are accepted.

Inclusion Criteria

1. A physician diagnosis of asthma
2. Age years old
3. Symptoms consistent with asthma for at least 6 months
4. Current asthma medications: Short-acting inhaled beta agonists as needed for control of asthma symptoms with or without a low to medium dose of an ICS, as defined in the table below and if on a ICS may also be on a long-acting beta agonist provided it is withheld for 24 hours prior to the testing days.

Inhaled Corticosteroid Dose less than or equal to:

Beclomethasone-HFA 480 µg/day Budesonide-DPI 1000 µg/day Flunisolide 2000 µg/day Fluticasone 500 µg/day Triamcinolone 2000 µg/day
5. FEV1 at screening 50-80% predicted (Hankinson6)
6. Reversibility with albuterol of 12% and 200 ml FEV1FEV1 at 30 minutes.