BACKGROUND: Adrenaline (epinephrine) is used during cardiopulmonary resuscitation (CPR) based on animal experiments without supportive clinical data. Clinically CPR was reported recently to have much poorer quality than expected from international guidelines and what is generally done in laboratory experiments. We have studied the haemodynamic effects of adrenaline during CPR with good laboratory quality and with quality simulating clinical findings and the feasibility of monitoring these effects through VF waveform analysis. METHODS AND RESULTS: After 4 min of cardiac arrest, followed by 4 min of basic life support, 14 pigs were randomised to ClinicalCPR (intermittent manual chest compressions, compression-to-ventilation ratio 15:2, compression depth 30-38 mm) or LabCPR (continuous mechanical chest compressions, 12 ventilations/min, compression depth 45 mm). Adrenaline 0.02 mg/kg was administered 30 s thereafter. Plasma adrenaline concentration peaked earlier with LabCPR than with ClinicalCPR, median (range), 90 (30, 150) versus 150 (90, 270) s (p = 0.007), respectively. Coronary perfusion pressure (CPP) and cortical cerebral blood flow (CCBF) increased and femoral blood flow (FBF) decreased after adrenaline during LabCPR (mean differences (95% CI) CPP 17 (6, 29) mmHg (p = 0.01), FBF -5.0 (-8.8, -1.2) ml min(-1) (p = 0.02) and median difference CCBF 12% of baseline (p = 0.04)). There were no significant effects during ClinicalCPR (mean differences (95% CI) CPP 4.7 (-3.2, 13) mmHg (p = 0.2), FBF -0.2 (-4.6, 4.2) ml min(-1)(p = 0.9) and CCBF 3.6 (-1.8, 9.0)% of baseline (p = 0.15)). Slope VF waveform analysis reflected changes in CPP. CONCLUSION: Adrenaline improved haemodynamics during laboratory quality CPR in pigs, but not with quality simulating clinically reported CPR performance.
BACKGROUND:Adrenaline (epinephrine) is used during cardiopulmonary resuscitation (CPR) based on animal experiments without supportive clinical data. Clinically CPR was reported recently to have much poorer quality than expected from international guidelines and what is generally done in laboratory experiments. We have studied the haemodynamic effects of adrenaline during CPR with good laboratory quality and with quality simulating clinical findings and the feasibility of monitoring these effects through VF waveform analysis. METHODS AND RESULTS: After 4 min of cardiac arrest, followed by 4 min of basic life support, 14 pigs were randomised to ClinicalCPR (intermittent manual chest compressions, compression-to-ventilation ratio 15:2, compression depth 30-38 mm) or LabCPR (continuous mechanical chest compressions, 12 ventilations/min, compression depth 45 mm). Adrenaline 0.02 mg/kg was administered 30 s thereafter. Plasma adrenaline concentration peaked earlier with LabCPR than with ClinicalCPR, median (range), 90 (30, 150) versus 150 (90, 270) s (p = 0.007), respectively. Coronary perfusion pressure (CPP) and cortical cerebral blood flow (CCBF) increased and femoral blood flow (FBF) decreased after adrenaline during LabCPR (mean differences (95% CI) CPP 17 (6, 29) mmHg (p = 0.01), FBF -5.0 (-8.8, -1.2) ml min(-1) (p = 0.02) and median difference CCBF 12% of baseline (p = 0.04)). There were no significant effects during ClinicalCPR (mean differences (95% CI) CPP 4.7 (-3.2, 13) mmHg (p = 0.2), FBF -0.2 (-4.6, 4.2) ml min(-1)(p = 0.9) and CCBF 3.6 (-1.8, 9.0)% of baseline (p = 0.15)). Slope VF waveform analysis reflected changes in CPP. CONCLUSION:Adrenaline improved haemodynamics during laboratory quality CPR in pigs, but not with quality simulating clinically reported CPR performance.
Authors: Ryan W Morgan; Todd J Kilbaugh; Wesley Shoap; George Bratinov; Yuxi Lin; Ting-Chang Hsieh; Vinay M Nadkarni; Robert A Berg; Robert M Sutton Journal: Resuscitation Date: 2016-12-05 Impact factor: 5.262
Authors: Robert A Berg; Robert M Sutton; Ron W Reeder; John T Berger; Christopher J Newth; Joseph A Carcillo; Patrick S McQuillen; Kathleen L Meert; Andrew R Yates; Rick E Harrison; Frank W Moler; Murray M Pollack; Todd C Carpenter; David L Wessel; Tammara L Jenkins; Daniel A Notterman; Richard Holubkov; Robert F Tamburro; J Michael Dean; Vinay M Nadkarni Journal: Circulation Date: 2017-12-26 Impact factor: 29.690
Authors: Henrik Wagner; Michael Götberg; Bjarne Madsen Hardig; Malin Rundgren; Jonas Carlson; Matthias Götberg; David Zughaft; David Erlinge; Göran K Olivecrona Journal: BMC Cardiovasc Disord Date: 2014-12-20 Impact factor: 2.298
Authors: Peter Paal; Les Gordon; Giacomo Strapazzon; Monika Brodmann Maeder; Gabriel Putzer; Beat Walpoth; Michael Wanscher; Doug Brown; Michael Holzer; Gregor Broessner; Hermann Brugger Journal: Scand J Trauma Resusc Emerg Med Date: 2016-09-15 Impact factor: 2.953