Neurological Monitoring During ECMO
P. Zanatta, E. Bosco, A. Forti, E. Polesel, C. Sorbara
Published 2014 · Medicine
Download PDFAnalyze on Scholarcy
Neurological monitoring during ECMO is one of the most challenging tasks in an intensive care unit because of the complexity of the clinical scenario and the instability of the patient, who is most often in a comatose condition just before the onset of extracorporeal circulation. Neuromonitoring is an extension of clinical examination that is often unfeasible because of multi-organ failure, sedation, and hypothermic treatment. A multimodal neurophysiological strategy can overcome this limitation and provide additional information on brain function, blood-flow velocity, and brain oxygenation.
This paper references
Multimodal brain monitoring reduces major neurologic complications in cardiac surgery.
Paolo Zanatta (2011)
Multimodality neuromonitoring for perioperative brain protection
H. Edmonds (2005)
Intraoperative use of electroencephalography as an assessment of cerebral blood flow.
K. M. McGrail (1996)
Electrophysiological Monitoring and Mild Hypothermia
E. Kochs (1995)
EEG monitoring and evoked potentials in brain ischaemia.
P. Prior (1985)
Predicting neurological outcome after cardiac arrest
M. Oddo (2011)
Brain emboli distribution and differentiation during cardiopulmonary bypass.
Paolo Zanatta (2013)
Transcranial Doppler: clinical and experimental uses.
D. Newell (1992)
Intraoperative neurophysiological monitoring of the afferent pain pathway in cardiac surgery patients
Paolo Zanatta (2011)
Microembolic signals and strategy to prevent gas embolism during extracorporeal membrane oxygenation
P. Zanatta (2010)
Cerebral oxygenation measured by near-infrared spectroscopy: comparison with jugular bulb oximetry.
P. Daubeney (1996)
Usefulness of cardiac biomarkers to predict cardiac recovery in patients on extracorporeal membrane oxygenation support for refractory cardiogenic shock.
C. Luyt (2012)
The rationale and utility of neurophysiological investigations in clinical monitoring for brain and spinal cord ischaemia during surgery and intensive care.
P. Prior (1996)
Continuous electroencephalography monitoring for early prediction of neurological outcome in postanoxic patients after cardiac arrest: A prospective cohort study*
M. C. Cloostermans (2012)
Guidelines for intraoperative neuromonitoring using raw (analog or digital waveforms) and quantitative electroencephalography: a position statement by the American Society of Neurophysiological Monitoring
Michael R. Isley (2009)
Dynamic monitors of brain function: a new target in neurointensive care unit
Enrico Bosco (2011)
Transcranial Doppler sonography and somatosensory evoked potential monitoring in carotid surgery.
A. Thiel (1990)
Sensory evoked potentials and the search for the Holy Grail method to predict the outcome after hypoxic-ischemic coma.
Ehab Farag (2012)
Intraoperative assessment of cerebral ischemia during carotid surgery.
S. Horsch (1990)
Experimental study of migration depth for the photons measured at sample surface
Weijia Cui (1991)
Transcranial Doppler monitoring of cerebral perfusion during cardiopulmonary bypass.
F. A. Burrows (1993)
Deep hypothermic circulatory arrest: I. Effects of cooling on electroencephalogram and evoked potentials.
M. Stecker (2001)
Decrease in jugular venous oxygen saturation during normothermic cardiopulmonary bypass predicts short-term postoperative neurologic dysfunction in elderly patients.
Y. Kadoi (2001)
Correlation of cerebral blood flow and electroencephalographic changes during carotid endarterectomy: with results of surgery and hemodynamics of cerebral ischemia.
T. Sundt (1981)
Cerebral oxygen desaturation is associated with early postoperative neuropsychological dysfunction in patients undergoing cardiac surgery.
F. F. Yao (2004)
Changes in Cerebral Oxygen Uptake and Cerebral Electrical Activity During Defibrillation Threshold Testing
J. de Vries (1998)
Predicting coma and other low responsive patients outcome using event-related brain potentials: A meta-analysis
J. Daltrozzo (2007)
Energy-requiring cell functions in the ischemic brain. Their critical supply and possible inhibition in protective therapy.
J. Astrup (1982)
Improved outcome prediction in unconscious cardiac arrest survivors with sensory evoked potentials compared with clinical assessment
C. Madl (2000)
Somatosensory evoked potential monitoring in carotid surgery. I. Relationships between qualitative SEP alterations and intraoperative events.
J. M. Guérit (1997)
Electroencephalography (EEG) and somatosensory evoked potentials (SEP) to prevent cerebral ischaemia in the operating room
G. Florence (2004)
Deep hypothermic circulatory arrest.
B. Ziganshin (2013)
Predictive value of somatosensory evoked potentials for awakening from coma*
L. Robinson (2003)
Predicting comatose patients with acute stroke outcome using middle-latency somatosensory evoked potentials
Y. Zhang (2011)
This paper is referenced by
Neurologic complications in patients receiving extracorporeal membrane oxygenation for influenza H1N1: Morbid but not futile
S. Laurie Hill (2016)