Back to resultsHydrogen-oxygen Gas Mixture Inhalation in Patients With Convalescent Coronavirus Disease 2019 (COVID-19)
Primary Purpose
Covid19, Hydrogen-oxygen Gas, AMS-H-03
Status
Unknown status
Phase
Not Applicable
Locations
China
Study Type
Interventional
Intervention
Hydrogen-Oxygen Generator with Nebulizer, AMS-H-03
OLO-1 Medical Molecular Sieve Oxygen Generator
Sponsored by
About this trial
This is an interventional treatment trial for Covid19 focused on measuring Covid19, Hydrogen-oxygen Gas, AMS-H-03
Eligibility Criteria
Inclusion Criteria:
1) Male or female, aged between 18 and 75 (including boundary values) at screening.
2) Severe or critically ill patients who have been diagnosed with a novel coronavirus during hospitalization (COVID-19).
3) After treatment, the patients have met the discharge criteria of "COVID-19 Diagnosis and Treatment Guideline", and the time from hospital discharge is at least 1 month at the time of enrollment. The clinical symptoms of the subjects did not worsen significantly as compared with that at the time of discharge, and the COVID-19 nucleic acid test results are negative for at least 2 consecutive times (one of which could be the nucleic acid test before discharge).
4) Forced vital capacity/per predicted (FVC% pred) ≥ 50%. 5) 50% ≤ FEV1 %pred ≤80%。 6) Subject (or legally authorized representative) provides written informed consent prior to initiation of any study procedures. Understands and agrees to comply with planned study procedures.
7) Agrees not to participate in other drug/device studies until the study is completed.
Exclusion Criteria:
1) With one of the following respiratory diseases:
- Subjects with asthma history, or cannot rule out asthma based on the diagnosis of investigator;
- Subjects with chronic obstructive pulmonary disease (COPD);
- Subjects with following respiratory diseases such as active tuberculosis, lung cancer, sarcoidosis, pulmonary hypertension, pneumothorax, uncontrolled pleural effusion through intervention, pulmonary embolism, etc.;
Lung volume reduction: subjects have had lung volume reduction surgery, pulmonary lobectomy, or bronchoscopic lung volume reduction surgery.
2) Subjects with pulmonary heart disease. 3) Patients who are scheduled for elective surgery during the study period, such as thoracic and abdominal major surgery.
4) Subjects, judged by investigators, with previous or current diseases, which may affect the participation in this study or the outcome of this study: such as cancer, diseases of heart, liver, kidney, hematopoietic system and other vital organs or systems, etc.
5) Patients who have undergone surgery within 1 month prior to screening and have not fully recovered.
6) Occurrence of congestive heart failure, uncontrolled or unstable angina or myocardial infarction, cerebrovascular accident, or history of pulmonary embolism within 6 months prior to screening.
7) Patients with active tuberculosis infection within 12 months prior to screening.
8) Pregnancy or lactating women, or women of childbearing potential not agree to either abstinence or use at least one primary form of contraception from the time of screening till the study is completed.
9) Subjects with mental disorders or other conditions that are unable to cooperate effectively with the conduct of the clinical trial.
10) Subjects intolerance to inhalation therapy. 11) Others whom the investigator or sub-investigator judged inappropriate for participation in the study.
Sites / Locations
- Guangzhou Institute of Respiratory Disease
- First Affiliated Hospital of Guangzhou Medical University
Arms of the Study
Arm 1
Arm 2
Arm Type
Experimental
Active Comparator
Arm Label
experimental Group
Control Group
Arm Description
the experimental arm will receive hydrogen-oxygen mixed gas inhalation (Hydrogen-Oxygen Generator with Nebulizer, AMS-H-03, output: 3 L/min (hydrogen concentration: 66.7%, oxygen concentration: 33.3%)) ,the treatment duration will be 8 hours per day, for 12 weeks.
the control arm will receive oxygen inhalation (OLO-1 Medical Molecular Sieve Oxygen Generator, output: 3 L/min (oxygen concentration: 33.3%), Shanghai Ouliang Medical Devices Co., Ltd.)the treatment duration will be 8 hours per day, for 12 weeks.
Outcomes
Primary Outcome Measures
(VO2max)
The change from baseline in maximum oxygen consumption (VO2max) at maximum exercise load at Week 12 of treatment.
Secondary Outcome Measures
(VO2max)
The change from baseline in maximum oxygen consumption (VO2max) at maximum exercise load at Week 4 of treatment.
(VO2max)
The change from baseline in maximum oxygen consumption (VO2max) at maximum exercise load at Week 8 of treatment.
(VE /VCO2)
Differences in the change from baseline in ventilatory equivalent for carbon dioxide (VE /VCO2) at maximum exercise load at Week 4 of treatment.
(VE /VCO2)
Differences in the change from baseline in ventilatory equivalent for carbon dioxide (VE /VCO2) at maximum exercise load at Week 8 of treatment.
(VE /VCO2)
Differences in the change from baseline in ventilatory equivalent for carbon dioxide (VE /VCO2) at maximum exercise load at Week 12 of treatment.
(VE /VO2)
Differences in the change from baseline in ventilatory equivalent for oxygen (VE /VO2) at maximum exercise load at Week 4 of treatment.
(VE /VO2)
Differences in the change from baseline in ventilatory equivalent for oxygen (VE /VO2) at maximum exercise load at Week 8 of treatment.
(VE /VO2)
Differences in the change from baseline in ventilatory equivalent for oxygen (VE /VO2) at maximum exercise load at Week 12 of treatment.
(VO2 /HR)
Differences in the change from baseline in oxygen pulse (VO2 /HR) at maximum exercise load at Week 4 treatment.
(VO2 /HR)
Differences in the change from baseline in oxygen pulse (VO2 /HR) at maximum exercise load at Week 8 of treatment.
(VO2 /HR)
Differences in the change from baseline in oxygen pulse (VO2 /HR) at maximum exercise load at Week 12 of treatment.
(P (A-a) O2)
The change from baseline in the alveolar-arterial oxygen tension gradient (P (A-a) O2) at maximum exercise load at Week 4 of treatment.
(P (A-a) O2)
The change from baseline in the alveolar-arterial oxygen tension gradient (P (A-a) O2) at maximum exercise load at Week 8 of treatment.
(P (A-a) O2)
The change from baseline in the alveolar-arterial oxygen tension gradient (P (A-a) O2) at maximum exercise load at Week 12 of treatment.
(P (a-et) CO2)
The change from baseline in the arterial-to-end-tidal CO2 difference (P (a-et) CO2) at maximum exercise load at Week 4 of treatment.
(P (a-et) CO2)
The change from baseline in the arterial-to-end-tidal CO2 difference (P (a-et) CO2) at maximum exercise load at Week 8 of treatment.
(P (a-et) CO2)
The change from baseline in the arterial-to-end-tidal CO2 difference (P (a-et) CO2) at maximum exercise load at Week 12 of treatment.
maximum exercise power
The change from baseline in maximum exercise power at Week 4 of treatment.
maximum exercise power
The change from baseline in maximum exercise power at Week 8 of treatment.
maximum exercise power
The change from baseline in maximum exercise power at Week 12 of treatment.
RER
The change from baseline in respiratory quotient (RER) at maximum exercise load at Week 4 of treatment.
RER
The change from baseline in respiratory quotient (RER) at maximum exercise load at Week 8 of treatment.
RER
The change from baseline in respiratory quotient (RER) at maximum exercise load at Week 12 of treatment.
The change from baseline in total exercise duration at maximum exercise load at Week 4 of treatment.
The change from baseline in total exercise duration at maximum exercise load at Week 4 of treatment.
The change from baseline in total exercise duration at maximum exercise load at Week 8 of treatment.
The change from baseline in total exercise duration at maximum exercise load at Week 8 of treatment.
The change from baseline in total exercise duration at maximum exercise load at Week 12 of treatment.
The change from baseline in total exercise duration at maximum exercise load at Week 12 of treatment.
(SpO2)
The change from baseline in fingertip oxygen saturation (SpO2) at rest and without oxygen inhalation at Week 4 of treatment.
(SpO2)
The change from baseline in fingertip oxygen saturation (SpO2) at rest and without oxygen inhalation at Week 8 of treatment.
(SpO2)
The change from baseline in fingertip oxygen saturation (SpO2) at rest and without oxygen inhalation at Week 12 of treatment.
(mMRC)
The change from baseline in the modified Medical Research Council (mMRC) Dyspnea Scale score at week 4 of treatment.
(mMRC)
The change from baseline in the modified Medical Research Council (mMRC) Dyspnea Scale score at week 8 of treatment.
(mMRC)
The change from baseline in the modified Medical Research Council (mMRC) Dyspnea Scale score at week 12 of treatment.
Full Information
NCT ID
NCT04594460
First Posted
October 19, 2020
Last Updated
October 19, 2020
Sponsor
Guangzhou Institute of Respiratory Disease
1. Study Identification
Unique Protocol Identification Number
NCT04594460
Brief Title
Hydrogen-oxygen Gas Mixture Inhalation in Patients With Convalescent Coronavirus Disease 2019 (COVID-19)
Official Title
A Clinical Trial to Evaluate the Efficacy and Safety of Hydrogen-oxygen Mixed Gas Inhalation in Convalescent Severe/Critically Ill Patients With Novel Coronavirus Pneumonia (COVID-19)
Study Type
Interventional
2. Study Status
Record Verification Date
October 2020
Overall Recruitment Status
Unknown status
Study Start Date
October 31, 2020 (Anticipated)
Primary Completion Date
October 31, 2021 (Anticipated)
Study Completion Date
December 31, 2021 (Anticipated)
3. Sponsor/Collaborators
Responsible Party, by Official Title
Principal Investigator
Name of the Sponsor
Guangzhou Institute of Respiratory Disease
4. Oversight
Studies a U.S. FDA-regulated Drug Product
No
Studies a U.S. FDA-regulated Device Product
No
Data Monitoring Committee
Yes
5. Study Description
Brief Summary
This study is a multicenter, randomized, open, parallel-controlled study. Qualified subjects will randomly be assigned to the experimental arm or the control arm according to the ratio of 1:1, with age (> 60 years or ≤ 60 years), smoking status (yes/no) and forced expiratory volume in one second/prediction (FEV1 %pred > 60% or ≤ 60%) as the random stratification factors.
Detailed Description
Subjects in the experimental arm and the control arm will receive hydrogen-oxygen mixed gas inhalation (Hydrogen-Oxygen Generator with Nebulizer, AMS-H-03, output: 3 L/min (hydrogen concentration: 66.7%, oxygen concentration: 33.3%)) and oxygen inhalation (OLO-1 Medical Molecular Sieve Oxygen Generator, output: 3 L/min (oxygen concentration: 33.3%), Shanghai Ouliang Medical Devices Co., Ltd.), respectively; the treatment duration will not be less than 8 hours per day, for 12 weeks.
Subjects in the experimental arm and the control arm will also receive other medications (excluding antiviral drugs) by the investigator as clinically indicated. Six visits are required for each subject in this study, including Visit 1 (D-7~-1), Visit 2 (D1), Visit 3 (D14±3d), Visit 4 (D28±3d), Visit 5 (D56±7d), Visit 6 (D84±7d).
6. Conditions and Keywords
Primary Disease or Condition Being Studied in the Trial, or the Focus of the Study
Covid19, Hydrogen-oxygen Gas, AMS-H-03
Keywords
Covid19, Hydrogen-oxygen Gas, AMS-H-03
7. Study Design
Primary Purpose
Treatment
Study Phase
Not Applicable
Interventional Study Model
Parallel Assignment
Model Description
Subjects in the experimental arm and the control arm will receive hydrogen-oxygen mixed gas inhalation (Hydrogen-Oxygen Generator with Nebulizer, AMS-H-03, output: 3 L/min (hydrogen concentration: 66.7%, oxygen concentration: 33.3%)) and oxygen inhalation (OLO-1 Medical Molecular Sieve Oxygen Generator, output: 3 L/min (oxygen concentration: 33.3%), Shanghai Ouliang Medical Devices Co., Ltd.), respectively; the targeted treatment duration will be 8 hours per day, for 12 weeks.
Masking
ParticipantCare ProviderInvestigatorOutcomes Assessor
Masking Description
This study is conducted in a double-blind design with a primary unblinding, and a terminal unblinding is performed after data review, database lock, and finalization of the statistical analysis plan.
Both the investigational device (AMS-H-03 Hydrogen-Oxygen Generator with Nebulizer) and the control device (OLO-1 Medical Molecular Sieve Oxygen Generator) were placed in the shell with the same appearance, with the same operating interface and only ventilation function. During the treatment, neither the investigator nor the subject would be aware of the treatment allocation The study devices will be masked by independent non-blinded personnel of the statistical company according to the corresponding operating procedures, and no specific personnel participating in the clinical operation shall be present during the process.
Allocation
Randomized
Enrollment
198 (Anticipated)
8. Arms, Groups, and Interventions
Arm Title
experimental Group
Arm Type
Experimental
Arm Description
the experimental arm will receive hydrogen-oxygen mixed gas inhalation (Hydrogen-Oxygen Generator with Nebulizer, AMS-H-03, output: 3 L/min (hydrogen concentration: 66.7%, oxygen concentration: 33.3%)) ,the treatment duration will be 8 hours per day, for 12 weeks.
Arm Title
Control Group
Arm Type
Active Comparator
Arm Description
the control arm will receive oxygen inhalation (OLO-1 Medical Molecular Sieve Oxygen Generator, output: 3 L/min (oxygen concentration: 33.3%), Shanghai Ouliang Medical Devices Co., Ltd.)the treatment duration will be 8 hours per day, for 12 weeks.
Intervention Type
Device
Intervention Name(s)
Hydrogen-Oxygen Generator with Nebulizer, AMS-H-03
Intervention Description
the experimental arm will receive hydrogen-oxygen mixed gas inhalation (Hydrogen-Oxygen Generator with Nebulizer, AMS-H-03, output: 3 L/min (hydrogen concentration: 66.7%, oxygen concentration: 33.3%)) ,the treatment duration will be 8 hours per day, for 12 weeks.
Intervention Type
Device
Intervention Name(s)
OLO-1 Medical Molecular Sieve Oxygen Generator
Intervention Description
the control arm will receive oxygen inhalation (OLO-1 Medical Molecular Sieve Oxygen Generator, output: 3 L/min (oxygen concentration: 33.3%), Shanghai Ouliang Medical Devices Co., Ltd.)the treatment duration will be 8 hours per day, for 12 weeks.
Primary Outcome Measure Information:
Title
(VO2max)
Description
The change from baseline in maximum oxygen consumption (VO2max) at maximum exercise load at Week 12 of treatment.
Time Frame
The change from baseline in maximum oxygen consumption (VO2max) at maximum exercise load at Week 12 of treatment.
Secondary Outcome Measure Information:
Title
(VO2max)
Description
The change from baseline in maximum oxygen consumption (VO2max) at maximum exercise load at Week 4 of treatment.
Time Frame
The change from baseline in maximum oxygen consumption (VO2max) at maximum exercise load at Week 4 of treatment.
Title
(VO2max)
Description
The change from baseline in maximum oxygen consumption (VO2max) at maximum exercise load at Week 8 of treatment.
Time Frame
The change from baseline in maximum oxygen consumption (VO2max) at maximum exercise load at Week 8 of treatment.
Title
(VE /VCO2)
Description
Differences in the change from baseline in ventilatory equivalent for carbon dioxide (VE /VCO2) at maximum exercise load at Week 4 of treatment.
Time Frame
Differences in the change from baseline in ventilatory equivalent for carbon dioxide (VE /VCO2) at maximum exercise load at Week 4 of treatment.
Title
(VE /VCO2)
Description
Differences in the change from baseline in ventilatory equivalent for carbon dioxide (VE /VCO2) at maximum exercise load at Week 8 of treatment.
Time Frame
Differences in the change from baseline in ventilatory equivalent for carbon dioxide (VE /VCO2) at maximum exercise load at Week 8 of treatment.
Title
(VE /VCO2)
Description
Differences in the change from baseline in ventilatory equivalent for carbon dioxide (VE /VCO2) at maximum exercise load at Week 12 of treatment.
Time Frame
Differences in the change from baseline in ventilatory equivalent for carbon dioxide (VE /VCO2) at maximum exercise load at Week 12 of treatment.
Title
(VE /VO2)
Description
Differences in the change from baseline in ventilatory equivalent for oxygen (VE /VO2) at maximum exercise load at Week 4 of treatment.
Time Frame
Differences in the change from baseline in ventilatory equivalent for oxygen (VE /VO2) at maximum exercise load at Week 4 of treatment.
Title
(VE /VO2)
Description
Differences in the change from baseline in ventilatory equivalent for oxygen (VE /VO2) at maximum exercise load at Week 8 of treatment.
Time Frame
Differences in the change from baseline in ventilatory equivalent for oxygen (VE /VO2) at maximum exercise load at Week 8 of treatment.
Title
(VE /VO2)
Description
Differences in the change from baseline in ventilatory equivalent for oxygen (VE /VO2) at maximum exercise load at Week 12 of treatment.
Time Frame
Differences in the change from baseline in ventilatory equivalent for oxygen (VE /VO2) at maximum exercise load at Week 12 of treatment.
Title
(VO2 /HR)
Description
Differences in the change from baseline in oxygen pulse (VO2 /HR) at maximum exercise load at Week 4 treatment.
Time Frame
Differences in the change from baseline in oxygen pulse (VO2 /HR) at maximum exercise load at Week 4 of treatment.
Title
(VO2 /HR)
Description
Differences in the change from baseline in oxygen pulse (VO2 /HR) at maximum exercise load at Week 8 of treatment.
Time Frame
Differences in the change from baseline in oxygen pulse (VO2 /HR) at maximum exercise load at Week 8 of treatment.
Title
(VO2 /HR)
Description
Differences in the change from baseline in oxygen pulse (VO2 /HR) at maximum exercise load at Week 12 of treatment.
Time Frame
Differences in the change from baseline in oxygen pulse (VO2 /HR) at maximum exercise load at Week 12 of treatment.
Title
(P (A-a) O2)
Description
The change from baseline in the alveolar-arterial oxygen tension gradient (P (A-a) O2) at maximum exercise load at Week 4 of treatment.
Time Frame
The change from baseline in the alveolar-arterial oxygen tension gradient (P (A-a) O2) at maximum exercise load at Week 4 of treatment.
Title
(P (A-a) O2)
Description
The change from baseline in the alveolar-arterial oxygen tension gradient (P (A-a) O2) at maximum exercise load at Week 8 of treatment.
Time Frame
The change from baseline in the alveolar-arterial oxygen tension gradient (P (A-a) O2) at maximum exercise load at Week 8 of treatment.
Title
(P (A-a) O2)
Description
The change from baseline in the alveolar-arterial oxygen tension gradient (P (A-a) O2) at maximum exercise load at Week 12 of treatment.
Time Frame
The change from baseline in the alveolar-arterial oxygen tension gradient (P (A-a) O2) at maximum exercise load at Week 12 of treatment.
Title
(P (a-et) CO2)
Description
The change from baseline in the arterial-to-end-tidal CO2 difference (P (a-et) CO2) at maximum exercise load at Week 4 of treatment.
Time Frame
The change from baseline in the arterial-to-end-tidal CO2 difference (P (a-et) CO2) at maximum exercise load at Week 4 of treatment.
Title
(P (a-et) CO2)
Description
The change from baseline in the arterial-to-end-tidal CO2 difference (P (a-et) CO2) at maximum exercise load at Week 8 of treatment.
Time Frame
The change from baseline in the arterial-to-end-tidal CO2 difference (P (a-et) CO2) at maximum exercise load at Week 8 of treatment.
Title
(P (a-et) CO2)
Description
The change from baseline in the arterial-to-end-tidal CO2 difference (P (a-et) CO2) at maximum exercise load at Week 12 of treatment.
Time Frame
The change from baseline in the arterial-to-end-tidal CO2 difference (P (a-et) CO2) at maximum exercise load at Week 12 of treatment.
Title
maximum exercise power
Description
The change from baseline in maximum exercise power at Week 4 of treatment.
Time Frame
The change from baseline in maximum exercise power at Week 4 of treatment.
Title
maximum exercise power
Description
The change from baseline in maximum exercise power at Week 8 of treatment.
Time Frame
The change from baseline in maximum exercise power at Week 8 of treatment.
Title
maximum exercise power
Description
The change from baseline in maximum exercise power at Week 12 of treatment.
Time Frame
The change from baseline in maximum exercise power at Week 12 of treatment.
Title
RER
Description
The change from baseline in respiratory quotient (RER) at maximum exercise load at Week 4 of treatment.
Time Frame
The change from baseline in respiratory quotient (RER) at maximum exercise load at Week 4 of treatment.
Title
RER
Description
The change from baseline in respiratory quotient (RER) at maximum exercise load at Week 8 of treatment.
Time Frame
The change from baseline in respiratory quotient (RER) at maximum exercise load at Week 8 of treatment.
Title
RER
Description
The change from baseline in respiratory quotient (RER) at maximum exercise load at Week 12 of treatment.
Time Frame
The change from baseline in respiratory quotient (RER) at maximum exercise load at Week 12 of treatment.
Title
The change from baseline in total exercise duration at maximum exercise load at Week 4 of treatment.
Description
The change from baseline in total exercise duration at maximum exercise load at Week 4 of treatment.
Time Frame
The change from baseline in total exercise duration at maximum exercise load at Week 4 of treatment.
Title
The change from baseline in total exercise duration at maximum exercise load at Week 8 of treatment.
Description
The change from baseline in total exercise duration at maximum exercise load at Week 8 of treatment.
Time Frame
The change from baseline in total exercise duration at maximum exercise load at Week 8 of treatment.
Title
The change from baseline in total exercise duration at maximum exercise load at Week 12 of treatment.
Description
The change from baseline in total exercise duration at maximum exercise load at Week 12 of treatment.
Time Frame
The change from baseline in total exercise duration at maximum exercise load at Week 12 of treatment.
Title
(SpO2)
Description
The change from baseline in fingertip oxygen saturation (SpO2) at rest and without oxygen inhalation at Week 4 of treatment.
Time Frame
The change from baseline in fingertip oxygen saturation (SpO2) at rest and without oxygen inhalation at Week 4 of treatment.
Title
(SpO2)
Description
The change from baseline in fingertip oxygen saturation (SpO2) at rest and without oxygen inhalation at Week 8 of treatment.
Time Frame
The change from baseline in fingertip oxygen saturation (SpO2) at rest and without oxygen inhalation at Week 8 of treatment.
Title
(SpO2)
Description
The change from baseline in fingertip oxygen saturation (SpO2) at rest and without oxygen inhalation at Week 12 of treatment.
Time Frame
The change from baseline in fingertip oxygen saturation (SpO2) at rest and without oxygen inhalation at Week 12 of treatment.
Title
(mMRC)
Description
The change from baseline in the modified Medical Research Council (mMRC) Dyspnea Scale score at week 4 of treatment.
Time Frame
The change from baseline in the modified Medical Research Council (mMRC) Dyspnea Scale score at week 4 of treatment.
Title
(mMRC)
Description
The change from baseline in the modified Medical Research Council (mMRC) Dyspnea Scale score at week 8 of treatment.
Time Frame
The change from baseline in the modified Medical Research Council (mMRC) Dyspnea Scale score at week 8 of treatment.
Title
(mMRC)
Description
The change from baseline in the modified Medical Research Council (mMRC) Dyspnea Scale score at week 12 of treatment.
Time Frame
The change from baseline in the modified Medical Research Council (mMRC) Dyspnea Scale score at week 12 of treatment.
10. Eligibility
Sex
All
Minimum Age & Unit of Time
18 Years
Maximum Age & Unit of Time
75 Years
Accepts Healthy Volunteers
No
Eligibility Criteria
Inclusion Criteria:
1) Male or female, aged between 18 and 75 (including boundary values) at screening.
2) Severe or critically ill patients who have been diagnosed with a novel coronavirus during hospitalization (COVID-19).
3) After treatment, the patients have met the discharge criteria of "COVID-19 Diagnosis and Treatment Guideline", and the time from hospital discharge is at least 1 month at the time of enrollment. The clinical symptoms of the subjects did not worsen significantly as compared with that at the time of discharge, and the COVID-19 nucleic acid test results are negative for at least 2 consecutive times (one of which could be the nucleic acid test before discharge).
4) Forced vital capacity/per predicted (FVC% pred) ≥ 50%. 5) 50% ≤ FEV1 %pred ≤80%。 6) Subject (or legally authorized representative) provides written informed consent prior to initiation of any study procedures. Understands and agrees to comply with planned study procedures.
7) Agrees not to participate in other drug/device studies until the study is completed.
Exclusion Criteria:
1) With one of the following respiratory diseases:
Subjects with asthma history, or cannot rule out asthma based on the diagnosis of investigator;
Subjects with chronic obstructive pulmonary disease (COPD);
Subjects with following respiratory diseases such as active tuberculosis, lung cancer, sarcoidosis, pulmonary hypertension, pneumothorax, uncontrolled pleural effusion through intervention, pulmonary embolism, etc.;
Lung volume reduction: subjects have had lung volume reduction surgery, pulmonary lobectomy, or bronchoscopic lung volume reduction surgery.
2) Subjects with pulmonary heart disease. 3) Patients who are scheduled for elective surgery during the study period, such as thoracic and abdominal major surgery.
4) Subjects, judged by investigators, with previous or current diseases, which may affect the participation in this study or the outcome of this study: such as cancer, diseases of heart, liver, kidney, hematopoietic system and other vital organs or systems, etc.
5) Patients who have undergone surgery within 1 month prior to screening and have not fully recovered.
6) Occurrence of congestive heart failure, uncontrolled or unstable angina or myocardial infarction, cerebrovascular accident, or history of pulmonary embolism within 6 months prior to screening.
7) Patients with active tuberculosis infection within 12 months prior to screening.
8) Pregnancy or lactating women, or women of childbearing potential not agree to either abstinence or use at least one primary form of contraception from the time of screening till the study is completed.
9) Subjects with mental disorders or other conditions that are unable to cooperate effectively with the conduct of the clinical trial.
10) Subjects intolerance to inhalation therapy. 11) Others whom the investigator or sub-investigator judged inappropriate for participation in the study.
Central Contact Person:
First Name & Middle Initial & Last Name or Official Title & Degree
Wei-jie Guan, PhD
Phone
+86-13826042052
Email
battery203@163.com
Overall Study Officials:
First Name & Middle Initial & Last Name & Degree
Wei-jie Guan, PhD
Organizational Affiliation
Guangzhou Institute of Respiratory Disease
Official's Role
Principal Investigator
Facility Information:
Facility Name
Guangzhou Institute of Respiratory Disease
City
Guangzhou
State/Province
Guangdong
ZIP/Postal Code
510120
Country
China
Facility Name
First Affiliated Hospital of Guangzhou Medical University
City
Guangzhou
State/Province
Guangdong
Country
China
12. IPD Sharing Statement
Plan to Share IPD
Undecided
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Hydrogen-oxygen Gas Mixture Inhalation in Patients With Convalescent Coronavirus Disease 2019 (COVID-19)
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