Elevation of the head and thorax, also known as Head-up cardiopulmonary resuscitation (HUP CPR), has been studied extensively in pigs in ventricular fibrillation (VF). HUP combined with active compression decompression and impedance threshold device (ACD+ITD) CPR improves vital organ perfusion and results in a doubling of cerebral perfusion when compared with the same method of CPR in the flat or horizontal plane. HUP CPR enhances the drainage of venous blood from the brain, lowers central venous pressures, reduces intracranial pressures during the decompression phase of CPR, redistributes blood flow through the lungs during CPR, and may reduce brain edema. These mechanisms collectively contribute to improved blood flow and less injury to the brain during CPR. These benefits are due in large part to the effects of gravity on the physiology of HUP CPR. Importantly, HUP CPR is dependent upon a means of generating enough forward flow to adequately pump blood "uphill" to the brain. In this proposed pilot study, CPR will be performed manually before the patient is placed on a controlled mechanical elevation device (Elegard, Minnesota Resuscitation Solutions LLC, USA). An ITD-16 (ResQPOD-16, Zoll, USA) will be placed on the patient's airway before the head is elevated. Automated CPR will be initiated as soon as feasible using a new automated CPR mechanical compression device that provides full active compression-decompression CPR (LUCAS-AD, Stryker, USA). The proposed feasibility clinical study will be the first ever to test the fully integrated system of ACD+ITD HUP CPR.
Elevation of the head and thorax, also known as Head-up cardiopulmonary resuscitation (HUP CPR), has been studied extensively in pigs in ventricular fibrillation (VF). HUP combined with active compression decompression and impedance threshold device (ACD+ITD) CPR improves vital organ perfusion and results in a doubling of cerebral perfusion when compared with the same method of CPR in the flat or horizontal plane. HUP CPR enhances the drainage of venous blood from the brain, lowers central venous pressures, reduces intracranial pressures during the decompression phase of CPR, redistributes blood flow through the lungs during CPR, and may reduce brain edema. These mechanisms collectively contribute to improved blood flow and less injury to the brain during CPR. These benefits are due in large part to the effects of gravity on the physiology of HUP CPR. Importantly, HUP CPR is dependent upon a means of generating enough forward flow to adequately pump blood "uphill" to the brain. Animal studies have shown that HUP CPR must be performed in a specific manner to be effective. For example, conventional standard CPR is insufficient, by itself, for effective HUP CPR. Additional means to enhance circulation are needed, such as concurrent use of the ITD and ACD CPR devices. ACD+ITD CPR alone has been shown to improve hemodynamics and survival with favorable neurologic outcome in several human randomized control trials. Animal studies have shown that HUP CPR is best with the combination of ACD+ITD CPR. Studies have shown that CPR must be initiated before elevating the head. Studies have also shown that HUP CPR is dependent upon the time it takes to elevate the head to the HUP. Elevation of the head and thorax should optimally take place over a 2-minute period of time from a flat position to the maximum head up elevation level in order to optimize cerebral perfusion pressures. Too rapid an elevation of the head and thorax can result in a reduction in cerebral arterial pressure when compared with flat CPR. In this proposed pilot study, CPR will be performed manually before the patient is placed on a controlled mechanical elevation device (Elegard, Minnesota Resuscitation Solutions LLC, USA). An ITD-16 (ResQPOD-16, Zoll, USA) will be placed on the patient's airway before the head is elevated. Automated CPR will be initiated as soon as feasible using a new automated CPR mechanical compression device that provides full active compression-decompression CPR (LUCAS-AD, Stryker, USA). The proposed feasibility clinical study will be the first ever to test the fully integrated system of ACD+ITD HUP CPR.
Study Type
INTERVENTIONAL
Allocation
NON_RANDOMIZED
Purpose
OTHER
Masking
NONE
Enrollment
126
CPR will be performed manually before the patient is placed on a controlled mechanical elevation device who raises the head and thorax, also known as the head-up position (HUP-Elegard, Minnesota Resuscitation Solutions LLC, USA). Rescuers will perform CPR as continuously as possible during the placement of the Elegard, with a \<10 second pause in chest compressions during the placement of this device. After performing (LUCAS AD + ITD CPR, see other interventions below) for 2 minutes with the head in the 'flat' position, the Elegard device will be turned on and the head will begin to rise as long as the patient is being treated with the ResQPOD-16 and the LUCAS AD. The head will be elevated to approximately 22 cm from the ground to the back of the occiput.
An an impedance threshold device ITD-16 (ResQPOD-16, Zoll, USA) will be placed on the patient's airway before the head is elevated.
Automated CPR will be initiated as soon as feasible using a new automated CPR mechanical compression device that provides full active compression-decompression CPR (LUCAS-AD, Stryker, USA).
SAMU 38
Grenoble, Isère, France
SAMU 54 - CHU Nancy
Nancy, Meurthe-et-Moselle, France
Maximum End-tidal carbon dioxide (ETCO2)
The maximum value of ETCO2 during CPR before ROSC measured after a washout period of 4 positive pressure ventilations (\~30 seconds with 30:2 compression: ventilation ratio) will be recorded. ETCO2 value reflects both cardiac output (CO) and pulmonary blood flow, and is an indirect indicator of coronary perfusion pressure during CPR. Levels of ETCO2 \> 10-15 mmHg have been correlated with return of spontaneous circulation (ROSC) and survival in both animal and human models of cardiac arrest.
Time frame: Day 0
Return of spontaneous circulation (ROSC)
Proportion of patients who's recovered a spontaneous circulation after CPR
Time frame: Day 0
Alive at hospital admission
Vital status at hospital admission
Time frame: Day 0
Survival to hospital discharge
Vital status at hospital discharge
Time frame: up to 30 days
Survival at 30 days
Vital status at 30 days
Time frame: 30 days
Neurological functional status
As measured by using the modified Rankin Scale (mRS). A score equal to 0 = no symptoms at all, A score equal to 1 = no significant disability, despite symptoms ; able to carry out all usual duties and activities A score equal to 2 = slight disability ; unable to carry out all previous activities but able to look after own affairs A score equal to 3 = moderate disability ; requiring some help, but able to walk without assistance A score equal to 4 = moderately severe disability ; unable to walk without assistance and unable to attend to own bodily needs without assistance A score equal to 5 = severe disability ; bedridden, incontinent and requiring constant nursing care and attention We considered to a score less or equal to 3 will be considered as favourable neurologic outcome
Time frame: Day 30
First recorded rhythm
First recorded rhythm and rhythm recorded by EMS (asystole, ryhtme without pulse, ventricular fibrillation or ventricular tacycardia and spontaneous circulation)
Time frame: Day 0
Changes in heart rhythm from ventricular fibrillation (VF)
Proportion of patients who's with changes in heart rhythm from VF to non-VF rhythm and vice versa during the EMS intervention
Time frame: Day 0
Signs of life
Presence of agonal respirations and other signs of life (pupillary response, movement during CPR) recorded by ALS
Time frame: Day 0
Re-arrest rates
We calculated the proportion of patients who's recovered another cardiac arrest during CPR (supported by ALS and EMS)
Time frame: Day 0
Non-invasive arterial O2
Non-invasive arterial O2 saturation values during CPR recorded by EMS
Time frame: Day 0
End-tidal carbon dioxide (ETCO2) after CPR initiation
We compared the difference in ETCO2 values between baseline (i.e., within 2 minutes of CPR initiation) and repeated (i.e., within 4 minutes of CPR initiation) measures during the CPR (recorded by ALS and EMS intervention)
Time frame: Day 0
Non-invasive cerebral oximetry (rsO2)
Non-invasive cerebral oximetry (rsO2) values during CPR repeated (i.e., within 4 minutes of CPR initiation) measures recorded by ALS and EMS intervention
Time frame: Day 0
Left Ventricular (LV) function
LV function will be measured by echocardiography within 12 hours of ROSC at hospital
Time frame: Day 0
Non-invasive measurement of blood pressure
Non-invasive measurement of blood (systolic, diastolic and mean blood pressure) pressure during CPR
Time frame: Day 0
Intubation difficulty
Intubation difficulty assessed by the Intubation Difficulty Scale score. Score equal at 0 will be considered to easy intubation, score between 0 and 5 will be considered to slight difficulty, score more than 5 will be considered to moderate to major difficulty and score equal to infinite will be considered to impossible intubation
Time frame: Day 0
Neuron specific enolase
Serum Neuron specific enolase was measured at admission and 24h after hospital admission
Time frame: Day 0 and 24hours
S100 protein
Serum S100 protein was measured- at admission and 24h after hospital admission
Time frame: Day 0 and 24hours
Arterial Blood gases
Arterial blood gases (PaO2 partial pressure of oxygen, PCO2 partial pressure of cardon dioxide, pH, HCO3- bicarbonates and SaO2 oxygen saturation) were measured at hospital admission
Time frame: Day 0
Serum lactate concentration
The serum lactate concentration was measured at hospital admission
Time frame: Day 0
Serum d-dimer concentration
Serum d-dimer concentration was measured at 4hour and 24 hour after admission
Time frame: Day 0 and 24hours
Troponin C serum concentration
Troponin C serum concentration was measured at 4hour and 24 hour after admission
Time frame: Day 0 and 24hours
Creatinine concentration
Serum creatinine concentration was measured at 4hour and 24 hour after admission
Time frame: Day 0 and 24hours
Transaminases concentration
Serum transaminases concentration (ASAT: aspartate aminotransferases and ALAT: alanine aminotransferases) were measured at 4hour and 24 hour after admission
Time frame: Day 0 and 24hours
Imaging
Head CT will be performed within 12 hours of ROSC. Analysis will include the white to gray matter ratio
Time frame: 12 hours
End-tidal carbon dioxide between witnessed and unwitnessed cardiac arrest out-of-hospital cardiac arrest
We compared the difference in maximum ETCO2 during CPR between values recorded for witnessed and unwitnessed cardiac arrest
Time frame: Day 0
ROSC for witnessed and unwitnessed cardiac arrest
Proportion of patients who's recovered a spontaneous circulation after CPR between witnessed and unwitnessed cardiac arrest
Time frame: Day 0
Survival to hospital admission for witnessed and unwitnessed cardiac arrest
Vital status at hospital admission between witnessed and unwitnessed cardiac arrest
Time frame: Day 0
Survival to hospital discharge for witnessed and unwitnessed cardiac arrest
Vital status at hospital discharge between witnessed and unwitnessed cardiac arrest
Time frame: Up to 30 days
Neurological functional status between witnessed and unwitnessed cardiac arrest
As measured by using the modified Rankin Scale (mRS). A score equal to 0 = no symptoms at all, A score equal to 1 = no significant disability, despite symptoms ; able to carry out all usual duties and activities A score equal to 2 = slight disability ; unable to carry out all previous activities but able to look after own affairs A score equal to 3 = moderate disability ; requiring some help, but able to walk without assistance A score equal to 4 = moderately severe disbility ; unable to walk without assistance and unable to attend to own bodily needs without assistance A score equal to 5 = severe disability ; bedridden, incontinent and requiring constant nursing care and attention We consired to a score less or equal to 3 will be considered as favourable neurologic outcome
Time frame: Up to 30 days
This platform is for informational purposes only and does not constitute medical advice. Always consult a qualified healthcare professional.