Cornelia W Hoedemaekers1, Philip N Ainslie2, Stijn Hinssen3, Marcel J Aries4, Laurens L Bisschops5, Jeannette Hofmeijer3, Johannes G van der Hoeven5. 1. Department of Intensive Care Medicine, Radboud University Medical Center, Nijmegen, The Netherlands. Electronic address: Astrid.Hoedemaekers@radboudumc.nl. 2. Centre for Heart, Lung and Vascular Health, University of British Columbia, British Columbia, Canada. 3. Department of Neurology, Rijnstate Hospital, Arnhem and department of Clinical Neurophysiology, University of Twente, Enschede, The Netherlands. 4. Department of Intensive Care, University of Maastricht, Maastricht University Medical Center, Maastricht, The Netherlands. 5. Department of Intensive Care Medicine, Radboud University Medical Center, Nijmegen, The Netherlands.
Abstract
AIM OF THE STUDY: Estimation of cerebral anaerobic metabolism in survivors and non-survivors after cardiac arrest. METHODS: We performed an observational study in twenty comatose patients after cardiac arrest and 19 healthy control subjects. We measured mean flow velocity in the middle cerebral artery (MFVMCA) by transcranial Doppler. Arterial and jugular blood samples were used for calculation of the jugular venous-to-arterial CO2/arterial to-jugular venous O2 content difference ratio. RESULTS: After cardiac arrest, MFVMCA increased from 26.0[18.6-40.4]cm/sec on admission to 63.9[48.3-73.1]cm/sec after 72h (p<0.0001), with no significant differences between survivors and non-survivors (p=0.4853). The MFVMCA in controls was 59.1[52.8-69.0]cm/sec. The oxygen extraction fraction (O2EF) was 38.9[24.4-47.7]% on admission and decreased significantly to 17.3[12.1-26.2]% at 72h (p<0.0001). The decrease in O2EF was more pronounced in non-survivors (p=0.0173). O2EF in the control group was 35.4[32.4-38.7]%. The jugular bulb-arterial CO2 to arterial-jugular bulb O2 content difference ratio was >1 at all time points after cardiac arrest and did not change during admission, with no differences between survivors and non-survivors. Values in cardiac arrest patients were similar to those in normal subjects. CONCLUSIONS: In this study, low CBF after cardiac arrest is not associated with anaerobic metabolism. Hypoperfusion appears to be the consequence of a decrease of neuronal functioning and metabolic needs. Alternatively, hypoperfusion may decrease cerebral metabolism. Subsequently, metabolism increases in survivors, consistent with resumption of neuronal activity, whereas in non-survivors lasting low metabolism reflects irreversible neuronal damage.
AIM OF THE STUDY: Estimation of cerebral anaerobic metabolism in survivors and non-survivors after cardiac arrest. METHODS: We performed an observational study in twenty comatosepatients after cardiac arrest and 19 healthy control subjects. We measured mean flow velocity in the middle cerebral artery (MFVMCA) by transcranial Doppler. Arterial and jugular blood samples were used for calculation of the jugular venous-to-arterial CO2/arterial to-jugular venous O2 content difference ratio. RESULTS: After cardiac arrest, MFVMCA increased from 26.0[18.6-40.4]cm/sec on admission to 63.9[48.3-73.1]cm/sec after 72h (p<0.0001), with no significant differences between survivors and non-survivors (p=0.4853). The MFVMCA in controls was 59.1[52.8-69.0]cm/sec. The oxygen extraction fraction (O2EF) was 38.9[24.4-47.7]% on admission and decreased significantly to 17.3[12.1-26.2]% at 72h (p<0.0001). The decrease in O2EF was more pronounced in non-survivors (p=0.0173). O2EF in the control group was 35.4[32.4-38.7]%. The jugular bulb-arterial CO2 to arterial-jugular bulb O2 content difference ratio was >1 at all time points after cardiac arrest and did not change during admission, with no differences between survivors and non-survivors. Values in cardiac arrestpatients were similar to those in normal subjects. CONCLUSIONS: In this study, low CBF after cardiac arrest is not associated with anaerobic metabolism. Hypoperfusion appears to be the consequence of a decrease of neuronal functioning and metabolic needs. Alternatively, hypoperfusion may decrease cerebral metabolism. Subsequently, metabolism increases in survivors, consistent with resumption of neuronal activity, whereas in non-survivors lasting low metabolism reflects irreversible neuronal damage.
Authors: Chiara Robba; Alberto Goffi; Thomas Geeraerts; Danilo Cardim; Gabriele Via; Marek Czosnyka; Soojin Park; Aarti Sarwal; Llewellyn Padayachy; Frank Rasulo; Giuseppe Citerio Journal: Intensive Care Med Date: 2019-04-25 Impact factor: 17.440