Work of Breathing Clinical Trial
Official title:
The Impact of the Work of Breathing and Gas Exchange for COPD Patient Using a Gas Mask.
Background: The gas mask is used to protect the aiways against respiratory hazards (CBRN agents). Within the CBRNE committee, speculations are that unprotected lungs would look like to those of COPD patients in post-exposure of some CBRNE agents. The aim of the study was to evaluate the impact of the gas mask on respiratory patterns and indexes of the respiratory effort. Methods: We are completing our study with 9 COPD patients to evaluate breathing patterns, index of respiratory efforts and blood gases. Three conditions have been tested in a randomized order: 1x baseline and 2x different canisters, with and without a mask (C4, Airboss Defence, Bromont, Canada). Airway pressure, inspiratory and expiratory flows have been measured. An esophageal catheter is introduced at the beginning of the study to measure esophageal pressure (Peso) and calculate indexes of respiratory effort (PTPeso, WOB). SpO2 is continuously measured and capillary blood bases are drawn at the end of each condition. Each condition lasts 10 minutes, data of the last 2 minutes at a steady state are considered for analyses. Results. We are compiling data and processing them for analysis.
The principal way of penetration of CBRNE agents is the respiratory system. The current
technology of a gas mask has been used to protect the respiratory system as far back as the
First World War. That originated from Dr Cluny Macpherson's initiatives whom was a Canadian
military physician.
The military gas mask is part of the respirator classification but owes its specific
features. Conventionally, the military gas mask covers a large spectrum of protection
aspects and matched with their specific canisters. Consequently, gas masks are usually
studied separately from other respirators and Self-Contained Breathing Apparatus (SBCA).
While few studies have been about the gas mask technology, no-study addresses it in regards
of the impact from a bad airway protection and consequences on the respiratory system.
The gas mask design and its components may lead to these respiratory load issues. At rest
and from different resistances, what would be the impacts for the work of breathing and gas
exchange? In order to avoid hypoxemia and hyperoxia, what would be the optimal means to
restore proper oxygenation? We hypothesised on a: i. Heightened WOB and the respiratory
demands related to wear of the gas mask; ii. An occurrence of hypoxemia will be manifesting
during a continuous period. Our goal is to measure the impact of the work of breathing and
the gas exchange for a gas mask user and also a COPD patient. We also measure what was the
optimal means for correcting the hypoxemia with a subject.
9 COPD patients have been participating in a comparison and single-blind randomized
experimental study. That was approved by the Ethical Review Committee. A written consent is
obtained for all the subjects prior their acceptance. No rejection has happened during the
recruiting so far. The eligibility criteria are: i. COPD diagnosis from mild-to-severe FEV
30-80%). The exclusion criteria are: i. Refusals relate to wear the oesophageal catheter and
for capillary punctures; ii. Claustrophobia; iii. Oesophageal wounds backgrounds; iv. No
coronary background and stroke history; v. No face morphology incompatibility with the mask.
Spirometry and usual health screening is also done before starting the clinical trial.
Design comprises three 10-minute testing conditions split in two parts. All has been at rest
and sitting on a chair: i. Baseline without gas mask; ii. Gas mask and Canister A; iii. Gas
Mask and Canister B. Between the condition a 5-minute wash-out takes place.
Three five-minute periods is followed to record blood pressure and pulse during the
conditions. SpO2 is continuously measured with Free O2. Capillary punctures are done at the
end of each condition. Comfort was also assessed.
Our main measurements are the WOB performed with a continuous recording of Peso pressure and
respiratory volumes. Software Acknowledge, version 3.9 serves as acquisition data system and
analysis are achieved with a 4.2 version and a free-trial WOB calculus system, named
RESPMAT. That is obtained from Maynaud and al.(2014). As power source, we use a BIOPAC
(MP100, Santa Barbara, Californie, USA, 200 Hertz), four differential sensors (Validyne : 1x
MP45±100 cmH2O; 2x MP100±5 cmH2O; 1x MP100±100 cmH2O) and four Carrier D-Modulators
(Validyne, CT-15,120 Volt, 60 Hertz, 5Watts, Model CD15-A-2-A-1).
Single esophageal catheter (Type Cooper, French caliber #5) and disposable pneumotachs are
used. Lidocain spray and K-Y gel are applied during the insertion of the catheter. Its
placement is done at 37.6±5.7 cm across the subject and a Mueller test is performed for each
subject. In regard of spontaneous breathing, an Hudson mask is used while a C-4 Gas Mask
with a canister was employed (Manufacturer: Airboss Defence, Bromont, Canada). Canister A
and B were respectively a C7A1 and ADB81 trademark. Prototyped Free O2 System is employed
for the correction of the hypoxemia.
;
Allocation: Randomized, Endpoint Classification: Safety/Efficacy Study, Intervention Model: Single Group Assignment, Masking: Single Blind (Subject), Primary Purpose: Health Services Research
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