Clinical Trial Details
— Status: Terminated
Administrative data
NCT number |
NCT04657393 |
Other study ID # |
VICA |
Secondary ID |
|
Status |
Terminated |
Phase |
N/A
|
First received |
|
Last updated |
|
Start date |
June 1, 2019 |
Est. completion date |
November 30, 2021 |
Study information
Verified date |
November 2022 |
Source |
Medical University of Graz |
Contact |
n/a |
Is FDA regulated |
No |
Health authority |
|
Study type |
Interventional
|
Clinical Trial Summary
Over the last decades, research in cardiopulmonary resuscitation was primarily focused on
uninterrupted chest compressions to restore sufficient circulation. Ventilation during
ongoing chest compressions was regarded as potentially deleterious and thus not given any
major scientific focus. Current guidelines advise that ventilation be monitored by end-tidal
CO2 and emphasize that hyperventilation be avoided. Recent findings from arterial blood gas
analyses showed high levels of arterial pCO2, resulting in a frequent occurrence of
hypercapnic acidosis, which may be caused by iatrogenic hypoventilation. Ventilation during
ongoing chest compressions can be hard to achieve, as nearly every breath may be terminated
by simultaneous chest compressions. In case of bag ventilation the applied tidal volumes have
not yet been measured und mechanical ventilators so far were not able to ventilate during
chest compressions, because pressure limit settings induced termination of inspiration.
The aim of this study is to provide patients with the best possible ventilation, even under
ongoing chest compressions. Patients are ventilated with a new turbine-driven ventilator
(Monnal T60, Air Liquide, France), which can deliver adequate tidal volumes within a very
short inspiratory phase due to the inspiratory flow of > 200l/min. Thus, in deviation from
the current recommendations, the ventilation rate can be doubled to 20/min, so that
inspiration coincides with cardiac massage less often. The study compares effective
ventilation volumes applied by two regimes, 10 breaths/min and 20/min.
Description:
Restoration of circulation is undoubtedly the basis of success in cardiopulmonary
resuscitation (CPR). Current guidelines on CPR require that hyperventilation be avoided
during CPR. Blood gas analysis results from the "BABICA trial" demonstrate that more than 90%
of patients have highly elevated levels of pCO2 and are acidotic, mainly due to hypercapnia.
No hyperventilated or alkalotic patients were found during CPR. Furthermore, higher pO2
values were found to be associated with improved outcomes. Current recommendations to limit
ventilation frequency to 10/min was also critically questioned in a recent study from
Belgium, which did not show any positive effect of low respiration rate compared to higher
ones, cut-off 10/min. There are currently no clinical trials addressing optimal tidal volumes
or minute volumes during CPR.
A major obstacle to continuous measurement of respiratory minute volumes during CPR are
ongoing chest compressions. In a retrospective study in which respiratory volumes were
derived from bioimpedance curves, better outcomes were found in the group of more frequent
ventilations. Common machine ventilators display set values, while expiratory volumes are
averaged and may be overlaid by volume shifts of cardiac massage. In a recent study,
investigators analyzed flow curves, where each breath can be evaluated individually and
volumes can be derived correctly using dedicated software. We were able to test this method
on a comparative study of three ventilators study on anatomical cadavers.
This study aims to detect whether a higher rate of ventilation using a turbine driven
ventilator is able to provide higher breathing volumes during ongoing chest compressions in
individuals suffering from out-of-hospital cardiac arrest (OHCA). Higher ventilation and
oxygenation parameters as well as optimized acid-base-balance and increased rates of ROSC are
expected.
Patient care (chest compressions, venous access, endotracheal intubation, application of
drugs, defibrillation if necessary) is conducted according to current recommendation for
Advanced Life Support (ALS) as issued by the European Resuscitation Council (ERC).
Ventilation is performed at one of two patterns: the control group is ventilated at 10
breaths per minute, the intervention group is ventilated at 20 breaths per minute. Patterns
are alternating according to calendar week. After successful endotracheal intubation
mechanical ventilation is carried out using a turbine-driven ventilator (Monnal T60,
AirLiquide, France). Ventilator settings are pre-set: respiratory frequency is set at 10/min
or 20/min (see above), other ventilator parameters remain identical: Positive End-Expiratory
Pressure (PEEP) 0 mmHg, FiO2 1,0, tidal volume 6ml/kg ideal body weight [men: 50+(0.91x(body
length-152.4)), women: 45+(0.91y(body length-152.4))]. These calculations can be performed on
the ventilator itself by entering patients' age, height and gender. Chest compressions are
carried out without interruptions and without considerations regarding the respiratory cycle.