Acute respiratory distress syndrome (ARDS) is a lesional pulmonary edema that occurs as a result of direct or indirect lung injury. This condition accounts for 10-15% of ICU admissions and 20-25% of patients admitted require invasive ventilation. Its incidence has increased markedly with the Covid-19 epidemic. ARDS is defined as hypoxemia (Pa02/Fi02 \< 300 mmHg) in ventilated patients without heart failure. Currently, the recommendations of the resuscitation societies advocate a management combining invasive ventilation, short duration curarization and prone sessions. In case of failure of these therapies, venovenous ExtraCorporeal Membrane Oxygenation (VV ECMO) is recommended in case of Pa02/Fi02 \< 80 mmHg. Nevertheless, approximately 40% of patients have refractory and persistent hypoxemia despite optimization of ECMO parameters and invasive ventilation. The refractory hypoxemia is defined as Pa02 \< 55 mmHg and/or Sa02 \< 90% and may be due to a recirculation phenomenon or a significant intra-pulmonary shunt. Currently, there is no official recommendation for the management of these patients, leading to the use of various unvalidated field practices. In addition, hospital mortality of the order of 60% is observed in these patients with high management costs. Some data in the literature suggest that induced therapeutic hypothermia (HT) at 34°C for 48 hours could improve the prognosis of these patients by improving oxygenation. Nevertheless, the level of evidence of published studies remains low because they are either case reviews or studies whose methodology does not guarantee the absence of potential bias. The research hypothesis is that HT at 34°C or 33°C for 48 hours is effective on refractory hypoxemia.
The investigators propose a pilot study, monocentric, prospective, controlled, randomized, to apprehend in an objective and reliable way the effects of induced moderate hypothermia at 34°C, or at 33°C in case of persistence of a Sa02 lower than 90%, during 48 hours in patients under ECMO VV for ARDS. The objective of this study is to show the beneficial effect of the treatment on the patient's oxygenation and to understand the physiopathological mechanism of action at work through different parameters at different times. In parallel, the undesirable effects will be recorded and weighed against the positive effects of the treatment in order to understand the benefit/risk ratio of light HT. The effect on survival will also be evaluated as a secondary objective, not to demonstrate efficacy in this small pilot trial, but to determine the size of the effect that can be expected.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
NONE
Enrollment
30
moderate hypothermia will be induced using the heat controller of the VV-ECMO circuit. Temperature will be maintained between 33°C≤ T°C ≤34°C during 48 hours followed by a progressive reheating (0.2±0.1°C/h) to reach 36 °C. Temperature at 36°C will be maintained during 48 hours after having reached 36 °C.
Temperature at 36°C will be maintained during 48 hours after having reached 36 °C
Effectiveness of 48 hours therapeutic hypothermia on the evolution of hypoxemia in patients on VV ECMO
Hypoxemia is measured by arterial saturation of oxygen (expressed in %)
Time frame: between initiation of hypothermia and 48 hours of induced hypothermia
Effectiveness of 1 hours, 6 hours, 24 hours therapeutic hypothermia on the evolution of hypoxemia in patients on VV ECMO
Hypoxemia is measured by arterial saturation of oxygen (expressed in %)
Time frame: at 1 hour, 6 hours, 24 hours of the randomization
Evolution of arterial transport of oxygen during therapeutic hypothermia
Arterial transport of oxygen is measured by blood gas at different hours (expressed in mL · min-1 · m-2)
Time frame: Evaluation of arterial transport of oxygen by peripheral gas measurement at 1 hour, 6 hours, 24 hours and 48 hours of hypothermia
Evolution of ECMO flow / cardiac output ratio (expressed in %)
Evaluation of the impact of induced hypothermia on the evolution of the ratio of ECMO flow (expressed in L/min) to the patient's cardiac output (assessed by cardiac ultrasound and expressed in L/min). The ratio of ECMO output to patient's cardiac output (expressed in percentage) is calculated as the ratio of ECMO output (expressed in L/min) to cardiac output (expressed in L/min)
Time frame: Measurement at 1 hour, 6 hours, 24 hours and 48 hours
Survival of patients hospitalized in intensive care
The percentage of patients who died during resuscitation hospitalization
Time frame: Measurement following inclusion with a time maximal of 28 days
The duration of VV ECMO during hospitalization in the intensive care unit
The duration of VV ECMO (in days) during resuscitation hospitalization,
Time frame: Measurement following inclusion with a time maximal of 28 days
The number of days without mechanical ventilation during resuscitation hospitalization
The number of days without invasive mechanical ventilation during resuscitation hospitalization
Time frame: Measurement following inclusion with a time maximal of 28 days
Microcirculatory perfusion and flow variables
measurement of sublingual microcirculation by using Sidestream Dark Field (SDF) microscopy SDF will be applied to the sublingual microvascular network with a 5X objective providing a 167X magnification. After the removal of saliva and other secretions using gauze, the device will be gently applied (without any pressure) on the lateral side of the tongue, in an area approximately 1.5-4 cm from the tip of the tongue. Five sequences of 20 secs each from different adjacent areas will be recorded using a computer and a video card and stored under a random number for later analysis. Other Name: SDF ((Microscan; Microvision Medical, Amsterdam, the Netherlands)
Time frame: at 24 and 48 hours
The safety of induced hypothermia treatment during hospitalization in the intensive care unit (infections, coagulation disorders, cardiac risk).
For infectious risk: % of infections during hospitalization in the intensive care unit (maximum follow-up time of 28 days); For risk on coagulation: (i) plasma free hemoglobinemia (expressed in g per 100 mL), and on (ii) prothrombin level (expressed in %), at 48 hours; (iii) Need for blood transfusion with hemoglobin loss of more than 2 points within 48 hours of hypothermia (expressed in number of blood transfusion) (iv) Bleeding manifestations within 48 hours with or without need for surgical treatment; For cardiac risk: (i) percentage of patients with symptomatic cardiac rhythm disturbance requiring specific treatment between H0 and H24 and between H0 and H48 (expressed in percentage), (ii) total duration of vasopressors administered at H24 and at H48 (expressed in days)
Time frame: Measurement following inclusion with a time maximal of 28 days
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