Literature DB >> 35796613

Inducing oscillations in positive end-expiratory pressure improves assessment of cerebrovascular pressure reactivity in patients with traumatic brain injury.

Jeanette Tas1,2, Kirsten D J Bos1,3, Joost Le Feber3, Erta Beqiri4, Marek Czosnyka4, Roel Haeren2,5, Iwan C C van der Horst1,6, Sander M J van Kuijk7, Ulrich Strauch1, Ken M Brady8,9, Peter Smielewski4, Marcel J H Aries1,2.   

Abstract

The cerebral pressure reactivity index (PRx), through intracranial pressure (ICP) measurements, informs clinicians about the cerebral autoregulation (CA) status in adult-sedated patients with traumatic brain injury (TBI). Using PRx in clinical practice is currently limited by variability over shorter monitoring periods. We applied an innovative method to reduce the PRx variability by ventilator-induced slow (1/min) positive end-expiratory pressure (PEEP) oscillations. We hypothesized that, as seen in a previous animal model, the PRx variability would be reduced by inducing slow arterial blood pressure (ABP) and ICP oscillations without other clinically relevant physiological changes. Patients with TBI were ventilated with a static PEEP for 30 min (PRx period) followed by a 30-min period of slow [1/min (0.0167 Hz)] +5 cmH2O PEEP oscillations (induced (iPRx period). Ten patients with TBI were included. No clinical monitoring was discontinued and no additional interventions were required during the iPRx period. The PRx variability [measured as the standard deviation (SD) of PRx] decreased significantly during the iPRx period from 0.25 (0.22-0.30) to 0.14 (0.09-0.17) (P = 0.006). There was a power increase around the induced frequency (1/min) for both ABP and ICP (P = 0.002). In conclusion, 1/min PEEP-induced oscillations reduced the PRx variability in patients with TBI with ICP levels <22 mmHg. No other clinically relevant physiological changes were observed. Reduced PRx variability might improve CA-guided perfusion management by reducing the time to find "optimal" perfusion pressure targets. Larger studies with prolonged periods of PEEP-induced oscillations are required to take it to routine use.NEW & NOTEWORTHY Cerebral autoregulation assessment requires sufficient slow arterial blood pressure (ABP) waves. However, spontaneous ABP waves may be insufficient for reliable cerebral autoregulation estimations. Therefore, we applied a ventilator "sigh-function" to generate positive end-expiratory pressure oscillations that induce slow ABP waves. This method demonstrated a reduced variability of the pressure reactivity index, commonly used as continuous cerebral autoregulation measure in a traumatic brain injury population.

Entities:  

Keywords:  PEEP; PRx; TBI; cerebral autoregulation; monitoring

Mesh:

Year:  2022        PMID: 35796613      PMCID: PMC9448337          DOI: 10.1152/japplphysiol.00199.2022

Source DB:  PubMed          Journal:  J Appl Physiol (1985)        ISSN: 0161-7567


  21 in total

1.  Prognostic value of major extracranial injury in traumatic brain injury: an individual patient data meta-analysis in 39,274 patients.

Authors:  Nikki van Leeuwen; Hester F Lingsma; Pablo Perel; Fiona Lecky; Bob Roozenbeek; Juan Lu; Haleema Shakur; James Weir; Ewout W Steyerberg; Andrew I R Maas
Journal:  Neurosurgery       Date:  2012-04       Impact factor: 4.654

2.  Cerebral autoregulation testing after aneurysmal subarachnoid hemorrhage: the phase relationship between arterial blood pressure and cerebral blood flow velocity.

Authors:  E W Lang; R R Diehl; H M Mehdorn
Journal:  Crit Care Med       Date:  2001-01       Impact factor: 7.598

3.  Targeting Autoregulation-Guided Cerebral Perfusion Pressure after Traumatic Brain Injury (COGiTATE): A Feasibility Randomized Controlled Clinical Trial.

Authors:  Jeanette Tas; Erta Beqiri; Ruud C van Kaam; Marek Czosnyka; Joseph Donnelly; Roel H Haeren; Iwan C C van der Horst; Peter J Hutchinson; Sander M J van Kuijk; Analisa L Liberti; David K Menon; Cornelia W E Hoedemaekers; Bart Depreitere; Peter Smielewski; Geert Meyfroidt; Ari Ercole; Marcel J H Aries
Journal:  J Neurotrauma       Date:  2021-08-16       Impact factor: 5.269

4.  Phase shift and correlation coefficient measurement of cerebral autoregulation during deep breathing in traumatic brain injury (TBI).

Authors:  P M Lewis; J V Rosenfeld; R R Diehl; H M Mehdorn; E W Lang
Journal:  Acta Neurochir (Wien)       Date:  2008-01-23       Impact factor: 2.216

5.  Effect of decompressive craniectomy on intracranial pressure and cerebrospinal compensation following traumatic brain injury.

Authors:  Ivan Timofeev; Marek Czosnyka; Jurgens Nortje; Peter Smielewski; Peter Kirkpatrick; Arun Gupta; Peter Hutchinson
Journal:  J Neurosurg       Date:  2008-01       Impact factor: 5.115

6.  Continuous assessment of the cerebral vasomotor reactivity in head injury.

Authors:  M Czosnyka; P Smielewski; P Kirkpatrick; R J Laing; D Menon; J D Pickard
Journal:  Neurosurgery       Date:  1997-07       Impact factor: 4.654

7.  Cerebrovascular pressure reactivity monitoring using wavelet analysis in traumatic brain injury patients: A retrospective study.

Authors:  Xiuyun Liu; Joseph Donnelly; Marek Czosnyka; Marcel J H Aries; Ken Brady; Danilo Cardim; Chiara Robba; Manuel Cabeleira; Dong-Joo Kim; Christina Haubrich; Peter J Hutchinson; Peter Smielewski
Journal:  PLoS Med       Date:  2017-07-25       Impact factor: 11.069

8.  A management algorithm for adult patients with both brain oxygen and intracranial pressure monitoring: the Seattle International Severe Traumatic Brain Injury Consensus Conference (SIBICC).

Authors:  Randall Chesnut; Sergio Aguilera; Andras Buki; Eileen Bulger; Giuseppe Citerio; D Jamie Cooper; Ramon Diaz Arrastia; Michael Diringer; Anthony Figaji; Guoyi Gao; Romer Geocadin; Jamshid Ghajar; Odette Harris; Alan Hoffer; Peter Hutchinson; Mathew Joseph; Ryan Kitagawa; Geoffrey Manley; Stephan Mayer; David K Menon; Geert Meyfroidt; Daniel B Michael; Mauro Oddo; David Okonkwo; Mayur Patel; Claudia Robertson; Jeffrey V Rosenfeld; Andres M Rubiano; Juan Sahuquillo; Franco Servadei; Lori Shutter; Deborah Stein; Nino Stocchetti; Fabio Silvio Taccone; Shelly Timmons; Eve Tsai; Jamie S Ullman; Paul Vespa; Walter Videtta; David W Wright; Christopher Zammit; Gregory W J Hawryluk
Journal:  Intensive Care Med       Date:  2020-01-21       Impact factor: 17.440

9.  Feasibility of individualised severe traumatic brain injury management using an automated assessment of optimal cerebral perfusion pressure: the COGiTATE phase II study protocol.

Authors:  Erta Beqiri; Peter Smielewski; Chiara Robba; Marek Czosnyka; Manuel Teixeira Cabeleira; Jeanette Tas; Joseph Donnelly; Joanne G Outtrim; Peter Hutchinson; David Menon; Geert Meyfroidt; Bart Depreitere; Marcel J Aries; Ari Ercole
Journal:  BMJ Open       Date:  2019-09-20       Impact factor: 2.692

10.  Dynamic cerebral autoregulation estimates derived from near infrared spectroscopy and transcranial Doppler are similar after correction for transit time and blood flow and blood volume oscillations.

Authors:  Jan Willem J Elting; Jeanette Tas; Marcel Jh Aries; Marek Czosnyka; Natasha M Maurits
Journal:  J Cereb Blood Flow Metab       Date:  2018-10-24       Impact factor: 6.200
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