Restricted accessResearch articleFirst published online 2020-07
Diffuse Intracranial Injury Patterns Are Associated with Impaired Cerebrovascular Reactivity in Adult Traumatic Brain Injury: A CENTER-TBI Validation Study
Recent single-center retrospective analysis displayed the association between admission computed tomography (CT) markers of diffuse intracranial injury and worse cerebrovascular reactivity. The goal of this study was to further explore these associations using the prospective multi-center Collaborative European Neurotrauma Effectiveness Research in Traumatic Brain Injury (CENTER-TBI) high-resolution intensive care unit (HR ICU) data set. Using the CENTER-TBI HR ICU sub-study cohort, we evaluated those patients with both archived high-frequency digital physiology (100 Hz or higher) and the presence of a digital admission CT scan. Physiological signals were processed for pressure reactivity index (PRx) and both the percent (%) time above defined PRx thresholds and mean hourly dose above threshold. Admission CT injury scores were obtained from the database. Quantitative contusion, edema, intraventricular hemorrhage (IVH), and extra-axial lesion volumes were obtained via semi-automated segmentation. Comparison between admission CT characteristics and PRx metrics was conducted using Mann-U, Jonckheere-Terpstra testing, with a combination of univariate linear and logistic regression techniques. A total of 165 patients were included. Cisternal compression and high admission Rotterdam and Helsinki CT scores, and Marshall CT diffuse injury sub-scores were associated with increased percent (%) time and hourly dose above PRx threshold of 0, +0.25, and +0.35 (p < 0.02 for all). Logistic regression analysis displayed an association between deep peri-contusional edema and mean PRx above a threshold of +0.25. These results suggest that diffuse injury patterns, consistent with acceleration/deceleration forces, are associated with impaired cerebrovascular reactivity. Diffuse admission intracranial injury patterns appear to be consistently associated with impaired cerebrovascular reactivity, as measured through PRx. This is in keeping with the previous single-center retrospective literature on the topic. This study provides multi-center validation for those results, and provides preliminary data to support potential risk stratification for impaired cerebrovascular reactivity based on injury pattern.
Get full access to this article
View all access options for this article.
References
1.
Le RouxP., MenonD.K., CiterioG., VespaP., BaderM.K., BrophyG.M., DiringerM.N., StocchettiN., VidettaW., ArmondaR., BadjatiaN., BöeselJ., ChesnutR., ChouS., ClaassenJ., CzosnykaM., De GeorgiaM., FigajiA., FugateJ., HelbokR., HorowitzD., HutchinsonP., KumarM., McNettM., MillerC., NaidechA., OddoM., OlsonD., O'PhelanK., ProvencioJ.J., PuppoC., RikerR., RobertsonC., SchmidtM., TacconeF., Neurocritical CareSociety, and European Society of Intensive CareMedicine. (2014). Consensus summary statement of the International Multidisciplinary Consensus Conference on Multimodality Monitoring in Neurocritical Care: a statement for healthcare professionals from the Neurocritical Care Society and the European Society of Intensive Care Medicine. Intensive Care Med. 40, 1189–1209.
2.
CzosnykaM., MillerC., and Participants in the International Multidisciplinary Consensus Conference on MultimodalityMonitoring. (2014). Monitoring of cerebral autoregulation. Neurocrit. Care, 21, Suppl. 2, S95–S102.
3.
CzosnykaM., SmielewskiP., KirkpatrickP., LaingR.J., MenonD., and PickardJ.D. (1997). Continuous assessment of the cerebral vasomotor reactivity in head injury. Neurosurgery, 41, 11–17; discussion 17–19.
4.
SorrentinoE., DiedlerJ., KasprowiczM., BudohoskiK.P., HaubrichC., SmielewskiP., OuttrimJ.G., ManktelowA., HutchinsonP.J., PickardJ.D., MenonD.K., and CzosnykaM. (2012). Critical thresholds for cerebrovascular reactivity after traumatic brain injury. Neurocrit. Care, 16, 258–266.
5.
DonnellyJ., CzosnykaM., AdamsH., CardimD., KoliasA.G., ZeilerF.A., LavinioA., AriesM., RobbaC., SmielewskiP., HutchinsonP.J.A., MenonD.K., PickardJ.D., and BudohoskiK.P. (2019). Twenty-five years of intracranial pressure monitoring after severe traumatic brain injury: a retrospective, single-center analysis. Neurosurgery, 85, E75–E82.
6.
ZeilerF.A., DonnellyJ., SmieleweskiP., MenonD., HutchinsonP.J., and CzosnykaM. (2018). Critical thresholds of ICP derived continuous cerebrovascular reactivity indices for outcome prediction in non-craniectomized TBI patients: PRx, PAx and RAC. J. Neurotrauma, 35, 1107–1115.
7.
ZeilerF.A., ErcoleA., CabeleiraM., ZoerleT., StocchettiN., MenonD.K., SmielewskiP., CzosnykaM., and CENTER-TBI High Resolution Sub-Study Participants andInvestigators. (2019). Univariate comparison of performance of different cerebrovascular reactivity indices for outcome association in adult TBI: a CENTER-TBI study. Acta Neurochir. (Wien) 161, 1217–1227.
8.
ZeilerF.A., ErcoleA., CabeleiraM., CarbonaraM., StocchettiN., MenonD.K., SmielewskiP., CzosnykaM., and CENTER-TBI High Resolution (HR ICU) Sub-Study Participants andInvestigators. (2019). Comparison of performance of different optimal cerebral perfusion pressure parameters for outcome prediction in adult traumatic brain injury: a Collaborative European NeuroTrauma Effectiveness Research in Traumatic Brain Injury (CENTER-TBI) study. J. Neurotrauma, 36, 1505–1517.
9.
SteinerL.A., CzosnykaM., PiechnikS.K., SmielewskiP., ChatfieldD., MenonD.K., and PickardJ.D. (2002). Continuous monitoring of cerebrovascular pressure reactivity allows determination of optimal cerebral perfusion pressure in patients with traumatic brain injury. Crit. Care Med. 30, 733–738.
10.
AriesM.J.H., CzosnykaM., BudohoskiK.P., SteinerL.A., LavinioA., KoliasA.G., HutchinsonP.J., BradyK.M., MenonD.K., PickardJ.D., and SmielewskiP. (2012). Continuous determination of optimal cerebral perfusion pressure in traumatic brain injury. Crit. Care Med. 40, 2456–2463.
11.
NeedhamE., McFadyenC., NewcombeV., SynnotA.J., CzosnykaM., and MenonD. (2017). Cerebral perfusion pressure targets individualized to pressure-reactivity index in moderate to severe traumatic brain injury: a systematic review. J. Neurotrauma, 34, 963–970.
12.
ZeilerF.A., ThelinE.P., DonnellyJ., StevensA.R., SmielewskiP., CzosnykaM., HutchinsonP.J., and MenonD.K. (2019). Genetic drivers of cerebral blood flow dysfunction in TBI: a speculative synthesis. Nat. Rev. Neurol. 15, 25–39.
13.
ZeilerF.A., DonnellyJ., NourallahB., ThelinE.P., CalvielloL., SmielewskiP., CzosnykaM., ErcoleA., and MenonD.K. (2018). Intracranial and extracranial injury burden as drivers of impaired cerebrovascular reactivity in traumatic brain injury. J. Neurotrauma, 35, 1569–1577.
14.
HilerM., CzosnykaM., HutchinsonP., BalestreriM., SmielewskiP., MattaB., and PickardJ.D. (2006). Predictive value of initial computerized tomography scan, intracranial pressure, and state of autoregulation in patients with traumatic brain injury. J. Neurosurg. 104, 731–737.
15.
ThelinE.P., TajsicT., ZeilerF.A., MenonD.K., HutchinsonP.J.A., CarpenterK.L.H., Morganti-KossmannM.C., and HelmyA. (2017). Monitoring the neuroinflammatory response following acute brain injury. Front. Neurol. 8, 351.
16.
HelmyA., AntoniadesC.A., GuilfoyleM.R., CarpenterK.L.H., and HutchinsonP.J. (2012). Principal component analysis of the cytokine and chemokine response to human traumatic brain injury. PLoS ONE, 7, e39677.
17.
HelmyA., CarpenterK.L.H., MenonD.K., PickardJ.D., and HutchinsonP.J.A. (2011). The cytokine response to human traumatic brain injury: temporal profiles and evidence for cerebral parenchymal production. J. Cereb. Blood Flow Metab. 31, 658–670.
18.
ZeilerF.A., ThelinE.P., CzosnykaM., HutchinsonP.J., MenonD.K., and HelmyA. (2017). Cerebrospinal fluid and microdialysis cytokines in severe traumatic brain injury: a scoping systematic review. Front. Neurol. 8, 331.
19.
ZeilerF.A., ThelinE.P., HelmyA., CzosnykaM., HutchinsonP.J.A., and MenonD.K. (2017). A systematic review of cerebral microdialysis and outcomes in TBI: relationships to patient functional outcome, neurophysiologic measures, and tissue outcome. Acta Neurochir. (Wien) 159, 2245–2273.
20.
ZeilerF.A., McFadyenC., NewcombeV., SynnotA., DonoghueE.L., RipattiS., SteyerbergE.W., GruenR.L., McAllisterT., RosandJ., PalotieA., MaasA., and MenonD. (2019). Genetic influences on patient oriented outcomes in TBI: a living systematic review of non-APOE single nucleotide polymorphisms. J. Neurotrauma [Epub ahead of print].
21.
MaasA.I.R., MenonD.K., SteyerbergE.W., CiterioG., LeckyF., ManleyG.T., HillS., LegrandV., SorgnerA., and CENTER-TBI Participants andInvestigators. (2015). Collaborative European NeuroTrauma Effectiveness Research in Traumatic Brain Injury (CENTER-TBI): a prospective longitudinal observational study. Neurosurgery, 76, 67–80.
22.
CarneyN., TottenA.M., O'ReillyC., UllmanJ.S., HawrylukG.W.J., BellM.J., BrattonS.L., ChesnutR., HarrisO.A., KissoonN., RubianoA.M., ShutterL., TaskerR.C., VavilalaM.S., WilbergerJ., WrightD.W., and GhajarJ. (2017). Guidelines for the Management of Severe Traumatic Brain Injury, Fourth Edition. Neurosurgery, 80, 6–15.
23.
VandeVyvereT., WilmsG., ClaesL., Martin LeonF., NieboerD., VerheydenJ., van den HauweL., PullensP., MaasA.I.R., ParizelP.M., and Collaborative European NeuroTrauma Effectiveness Research in Traumatic Brain Injury (CENTER-TBI) Investigators andParticipants. (2019). Central versus local radiological reading of acute computed tomography characteristics in multi-center traumatic brain injury research. J. Neurotrauma, 36, 1080–1092.
24.
MarshallL.F., MarshallS.B., KlauberM.R., Van Berkum ClarkM., EisenbergH., JaneJ.A., LuerssenT.G., MarmarouA., and FoulkesM.A. (1992). The diagnosis of head injury requires a classification based on computed axial tomography. J. Neurotrauma, 9, Suppl. 1, S287–292.
25.
MaasA.I.R., HukkelhovenC.W.P.M., MarshallL.F., and SteyerbergE.W. (2005). Prediction of outcome in traumatic brain injury with computed tomographic characteristics: a comparison between the computed tomographic classification and combinations of computed tomographic predictors. Neurosurgery, 57, 1173–1182; discussion 1173–1182.
26.
RajR., SiironenJ., SkrifvarsM.B., HernesniemiJ., and KivisaariR. (2014). Predicting outcome in traumatic brain injury: development of a novel computerized tomography classification system (Helsinki computerized tomography score). Neurosurgery, 75, 632–646; discussion 646–647.
27.
DoironD., MarconY., FortierI., BurtonP., and FerrettiV. (2017). Software application profile: Opal and Mica: open-source software solutions for epidemiological data management, harmonization and dissemination. Int. J. Epidemiol. 46, 1372–1378.
28.
KamnitsasK., LedigC., NewcombeV.F.J., SimpsonJ.P., KaneA.D., MenonD.K., RueckertD., and GlockerB. (2017). Efficient multi-scale 3D CNN with fully connected CRF for accurate brain lesion segmentation. Med. Image Anal. 36, 61–78.
29.
YushkevichP.A., PivenJ., HazlettH.C., SmithR.G., HoS., GeeJ.C., and GerigG. (2006). User-guided 3D active contour segmentation of anatomical structures: significantly improved efficiency and reliability. Neuroimage, 31, 1116–1128.
30.
BurkhartC.S., RossiA., Dell-KusterS., GamberiniM., MöckliA., SiegemundM., CzosnykaM., StrebelS.P., and SteinerL.A. (2011). Effect of age on intraoperative cerebrovascular autoregulation and near-infrared spectroscopy-derived cerebral oxygenation. Br. J. Anaesth. 107, 742–748.
31.
CzosnykaM., BalestreriM., SteinerL., SmielewskiP., HutchinsonP.J., MattaB., and PickardJ.D. (2005). Age, intracranial pressure, autoregulation, and outcome after brain trauma. J. Neurosurg. 102, 450–454.
32.
ZeilerF.A., ErcoleA., BeqiriE., CabeleiraM., AriesM., ZoerleT., CarbonaraM., StocchettiN., SmieleweskiP., CzosnykaM., and MenonD.K. (2019). Cerebrovascular reactivity is not associated with therapeutic intensity in adult traumatic brain injury: A CENTER-TBI analysis. Acta Neurochirurgica [Epub ahead of print].
33.
ZeilerF.A., ErcoleA., CabeleiraM., BeqiriE., ZoerleT., CarbonaraM., StocchettiN., MenonD.K., LazaridisC., SmielewskiP., CzosnykaM., and CENTER-TBI High Resolution ICU Sub-Study Participants andInvestigators. (2019). Patient-specific ICP epidemiologic thresholds in adult traumatic brain injury: A CENTER-TBI validation study. J Neurosurg. Anesthesiol. [Epub ahead of print].
34.
MathieuF., ZeilerF.A., WhitehouseD.P., DasT., ErcoleA., SmielewskiP., HutchinsonP.J., CzosnykaM., NewcombeV.F.J., and MenonD.K. (2019). Relationship between measures of cerebrovascular reactivity and intracranial lesion progression in acute TBI patients: an exploratory analysis. Neurocrit. Care [Epub ahead of print].
35.
ZeilerF.A., ThelinE.P., DonnellyJ., StevensA.R., SmielewskiP., CzosnykaM., HutchinsonP.J., and MenonD.K. (2019). Genetic drivers of cerebral blood flow dysfunction in TBI: a speculative synthesis. Nat. Rev. Neurol. 15, 25–39.
36.
ZeilerF.A., ErcoleA., CzosnykaM., SmielewskiP., HawrylukG., HutchinsonP.J.A., MenonD.K., and AriesM. (2020). Continuous cerebrovascular reactivity monitoring in moderate/severe traumatic brain injury: a narrative review of advances in neurocritical care. Br. J. Anaesth. [Epub ahead of print].
37.
TimofeevI., CzosnykaM., NortjeJ., SmielewskiP., KirkpatrickP., GuptaA., and HutchinsonP. (2008). Effect of decompressive craniectomy on intracranial pressure and cerebrospinal compensation following traumatic brain injury. J. Neurosurg. 108, 66–73.
38.
ZeilerF.A., AriesM., CabeleiraM., van EssenT., StocchettiN., MenonD., TimofeevI., CzosnykaM., SmieleweskiP., HutchinsonP.J., and ErcoleA. (2020). Statistical cerebrovascular reactivity signal properties after secondary decompressive craniectomy in traumatic brain injury: A CENTER-TBI pilot analysis. J. Neurotrauma [Epub ahead of print].
39.
MomjianS., OwlerB.K., CzosnykaZ., CzosnykaM., PenaA., and PickardJ.D. (2004). Pattern of white matter regional cerebral blood flow and autoregulation in normal pressure hydrocephalus. Brain, 127, 965–972.
40.
SchmidtE.A., CzosnykaM., SteinerL.A., BalestreriM., SmielewskiP., PiechnikS.K., MattaB.F., and PickardJ.D. (2003). Asymmetry of pressure autoregulation after traumatic brain injury. J. Neurosurg. 99, 991–998.
41.
SchmidtE.A., CzosnykaM., SmielewskiP., PiechnikS.K., and PickardJ.D. (2002). Asymmetry of cerebral autoregulation following head injury. Acta Neurochir. Suppl. 81, 133–134.
42.
ZweifelC., CzosnykaM., LavinioA., CastellaniG., KimD.-J., CarreraE., PickardJ.D., KirkpatrickP.J., and SmielewskiP. (2010). A comparison study of cerebral autoregulation assessed with transcranial Doppler and cortical laser Doppler flowmetry. Neurol. Res. 32, 425–428.
43.
ZweifelC., CastellaniG., CzosnykaM., HelmyA., ManktelowA., CarreraE., BradyK.M., HutchinsonP.J.A., MenonD.K., PickardJ.D., and SmielewskiP. (2010). Noninvasive monitoring of cerebrovascular reactivity with near infrared spectroscopy in head-injured patients. J. Neurotrauma, 27, 1951–1958.
44.
AriesM.J.H., CzosnykaM., BudohoskiK.P., KoliasA.G., RadolovichD.K., LavinioA., PickardJ.D., and SmielewskiP. (2012). Continuous monitoring of cerebrovascular reactivity using pulse waveform of intracranial pressure. Neurocrit. Care, 17, 67–76.
45.
ZeilerF.A., DonnellyJ., MenonD.K., SmielewskiP., HutchinsonP.J.A., and CzosnykaM. (2018). A description of a new continuous physiological index in traumatic brain injury using the correlation between pulse amplitude of intracranial pressure and cerebral perfusion pressure. J. Neurotrauma [Epub ahead of print].
46.
ZeilerF.A., DonnellyJ., CalvielloL., SmielewskiP., MenonD.K., and CzosnykaM. (2017). Pressure autoregulation measurement techniques in adult traumatic brain injury, Part II: a scoping review of continuous methods. J. Neurotrauma, 34, 3224–3237.
47.
ZeilerF.A., DonnellyJ., CalvielloL., LeeJ.K., SmielewskiP., BradyK., KimD.-J., and CzosnykaM. (2018). Validation of pressure reactivity and pulse amplitude indices against the lower limit of autoregulation, Part I: experimental intracranial hypertension. J. Neurotrauma, 35, 2803–2811.
48.
ZeilerF.A., LeeJ.K., SmielewskiP., CzosnykaM., and BradyK. (2018). Validation of intracranial pressure-derived cerebrovascular reactivity indices against the lower limit of autoregulation, Part II: experimental model of arterial hypotension. J. Neurotrauma, 35, 2812–2819.
49.
BradyK.M., LeeJ.K., KiblerK.K., EasleyR.B., KoehlerR.C., and ShaffnerD.H. (2008). Continuous measurement of autoregulation by spontaneous fluctuations in cerebral perfusion pressure: comparison of 3 methods. Stroke, 39, 2531–2537.
50.
BeqiriE., SmielewskiP., RobbaC., CzosnykaM., CabeleiraM.T., TasJ., DonnellyJ., OuttrimJ.G., HutchinsonP., MenonD., MeyfroidtG., DepreitereB., AriesM.J., and ErcoleA. (2019). Feasibility of individualised severe traumatic brain injury management using an automated assessment of optimal cerebral perfusion pressure: the COGiTATE phase II study protocol. BMJ Open, 9, e030727.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
