Hostname: page-component-8448b6f56d-qsmjn Total loading time: 0 Render date: 2024-04-23T13:49:53.278Z Has data issue: false hasContentIssue false
  • English
  • Français

Implementation of Neurocritical Care Is Associated With Improved Outcomes in Traumatic Brain Injury

Published online by Cambridge University Press:  27 March 2017

Mypinder S. Sekhon ,
Peter Gooderham ,
Brian Toyota ,
Navid Kherzi ,
Vivien Hu ,
Vinay K. Dhingra ,
Morad S. Hameed ,
Dean R. Chittock  and
Donald E. Griesdale
Mypinder S. Sekhon*
Affiliation:
Department of Medicine, Division of Critical Care Medicine, Vancouver General Hospital, University of British Columbia, Vancouver, BC, Canada Division of Neurosurgery, Department of Surgery, Vancouver General Hospital, University of British Columbia, Vancouver, BC, Canada
Peter Gooderham
Affiliation:
Division of Neurosurgery, Department of Surgery, Vancouver General Hospital, University of British Columbia, Vancouver, BC, Canada
Brian Toyota
Affiliation:
Division of Neurosurgery, Department of Surgery, Vancouver General Hospital, University of British Columbia, Vancouver, BC, Canada
Navid Kherzi
Affiliation:
Division of Neurosurgery, Department of Surgery, Vancouver General Hospital, University of British Columbia, Vancouver, BC, Canada
Vivien Hu
Affiliation:
Faculty of Medicine, Vancouver General Hospital, University of British Columbia, Vancouver, BC, Canada
Vinay K. Dhingra
Affiliation:
Department of Medicine, Division of Critical Care Medicine, Vancouver General Hospital, University of British Columbia, Vancouver, BC, Canada
Morad S. Hameed
Affiliation:
Department of Medicine, Division of Critical Care Medicine, Vancouver General Hospital, University of British Columbia, Vancouver, BC, Canada Division of Trauma Surgery, Department of Surgery, Vancouver General Hospital, University of British Columbia, Vancouver, BC, Canada
Dean R. Chittock
Affiliation:
Department of Medicine, Division of Critical Care Medicine, Vancouver General Hospital, University of British Columbia, Vancouver, BC, Canada
Donald E. Griesdale
Affiliation:
Department of Medicine, Division of Critical Care Medicine, Vancouver General Hospital, University of British Columbia, Vancouver, BC, Canada Department of Anaesthesiology, Pharmacology and Therapeutics, Vancouver General Hospital, University of British Columbia, Vancouver, BC, Canada Centre for Clinical Epidemiology and Evaluation, Vancouver Coastal Health Research Institute, University of British Columbia, Vancouver, BC, Canada
*
Correspondence to: Mypinder S. Sekhon, Critical Care Medicine, Vancouver General Hospital, Room 2438, Jim Pattison Pavilion, 2nd Floor, 855 West 12th Avenue, Vancouver BC V5Z 1M9 Email: mypindersekhon@gmail.com
Rights & Permissions [Opens in a new window]

Abstract

Background Traditionally, the delivery of dedicated neurocritical care (NCC) occurs in distinct NCC units and is associated with improved outcomes. Institution-specific logistical challenges pose barriers to the development of distinct NCC units; therefore, we developed a consultancy NCC service coupled with the implementation of invasive multimodal neuromonitoring, within a medical-surgical intensive care unit. Our objective was to evaluate the effect of a consultancy NCC program on neurologic outcomes in severe traumatic brain injury patients. Methods: We conducted a single-center quasi-experimental uncontrolled pre- and post-NCC study in severe traumatic brain injury patients (Glasgow Coma Scale ≤8). The NCC program includes consultation with a neurointensivist and neurosurgeon and multimodal neuromonitoring. Demographic, injury severity metrics, neurophysiologic data, and therapeutic interventions were collected. Glasgow Outcome Scale (GOS) at 6 months was the primary outcome. Multivariable ordinal logistic regression was used to model the association between NCC implementation and GOS at 6 months. Results: A total of 113 patients were identified: 76 pre-NCC and 37 post-NCC. Mean age was 39 years (standard deviation [SD], 2) and 87 of 113 (77%) patients were male. Median admission motor score was 3 (interquartile ratio, 1-4). Daily mean arterial pressure was higher (95 mmHg [SD, 10]) versus (88 mmHg [SD, 10], p<0.001) and daily mean core body temperature was lower (36.6°C [SD, 0.90]) versus (37.2°C [SD, 1.0], p=0.001) post-NCC compared with pre-NCC, respectively. Multivariable regression modelling revealed the NCC program was associated with a 2.5 increased odds (odds ratios, 2.5; 95% confidence interval, 1.1-5.3; p=0.022) of improved 6-month GOS. Conclusions: Implementation of a NCC program is associated with improved 6 month GOS in severe TBI patients.

Résumé

Contexte: La prestation de soins intensifs neurologiques (SIN) spécialisés s’effectue habituellement dans diverses unités et est associée à une évolution favorable de l’état des patients. Cela dit, les difficultés logistiques propres à chaque établissement constituent autant d’obstacles à la mise sur pied d’unités de SIN. Nous avons par conséquent créé, au sein d’un service de soins intensifs formé de médecins et de chirurgiens, un service-conseil et mis en œuvre un programme de monitorage multimodal. Notre objectif était d’évaluer l’impact de ce service-conseil quant à l’évolution de patients victimes de sévères traumatismes crâniens. Méthodes: Nous avons mené, dans un seul centre hospitalier, une étude quasi expérimentale non-contrôlée divisant ces patients (score à l’échelle de Glasgow ≤ 8) en deux groupes : les patients n’ayant pas reçu de SIN et ceux en ayant bénéficié. Le programme incluait une série de consultations avec des médecins spécialisés en SIN (neurointensivists) et des neurochirurgiens ainsi qu’un monitorage multimodal. Diverses données (de nature démographique et neurophysiologique mais se rapportant aussi à la gravité des blessures et aux types d’interventions thérapeutiques) ont alors été collectées. Au bout de 6 mois, le score à l’échelle de Glasgow fut le principal indicateur d’évolution. La technique de régression logistique ordinale à variables multiples fut utilisée pour modéliser le lien existant entre la mise en œuvre dudit programme et les scores à l’échelle de Glasgow. Résultats: Un groupe formé de 113 patients a été retenu ; de ce nombre, 76 n’avaient bénéficié d’aucun SIN. L’âge moyen de tous les patients était de 39 ans (écart type [ÉT], 2). Notons que 87 d’entre eux (77%) étaient des hommes. Au moment de leur admission, leur score médian à l’échelle de Glasgow était de 3 (rapport interquartile, 1-4). Si l’on compare les patients ayant bénéficié de SIN à ceux n’en ayant pas reçu, on remarque que la pression artérielle moyenne des premiers était quotidiennement plus élevée (95 mmHg [ÉT, 10]) que celle des derniers (88 mmHg [ÉT, 10], p < 0,001). De plus, la température moyenne centrale des patients ayant bénéficié de SIN s’est avérée plus basse (36,6 °C [ÉT, 0,90]) que celle des autres patients (37,2°C [ÉT, 1,0], p = 0,001). À l’aide d’une régression à variables multiples, il a été démontré que le programme de SIN était associé à une probabilité 2,5 plus élevée (risque relatif approché : 2,5; IC 95%, 1,1-5,3 ; p = 0,022) d’obtenir un meilleur score à l’échelle de Glasgow. Conclusions: Au bout de 6 mois, la mise en œuvre d’un programme de SIN a été associée, chez des patients victimes de sévères traumatismes crâniens, une amélioration de leur score à l’échelle de Glasgow.

Keywords

Traumatic brain injuryNeurocritical careIntracranial pressureCerebral autoregulationBrain tissue oxygen
Type
Original Articles
Information
Canadian Journal of Neurological Sciences , Volume 44 , Issue 4 , July 2017 , pp. 350 - 357
Copyright
Copyright © The Canadian Journal of Neurological Sciences Inc. 2017 

Neurocritical care (NCC) is a rapidly growing subspecialty of critical care medicine that focusses on the evaluation, diagnosis, and management of patients with acute life-threatening central nervous system diseases.Reference Korbakis and Bleck 1 , Reference Kramer and Zygun 2 The growth of this field has led to the development of dedicated NCC units that provide specialized multidisciplinary care for patients. Using this model, patient outcomes have improved in recent years across institutions in both Europe and North America.Reference Kramer and Zygun 3

Traumatic brain injury (TBI) is a devastating disease that falls within the purview of NCC. Following severe TBI, long-term disability is common,Reference Selassie, Zaloshnja, Langlois, Miller, Jones and Steiner 4 , Reference Langlois, Rutland-Brown and Wald 5 with considerable financial societal costs for the long-term care of survivors.Reference Chen, Bushmeneva, Zagorski, Colantonio, Parsons and Wodchis 6 Investigators continue to search for specific interventions to improve neurologic outcomes in severe TBI. Unfortunately, studies have failed to establish firm links between single therapeutic interventions and positive patient outcomes.Reference Cooper, Rosenfeld and Murray 7 - Reference Andrews, Sinclair and Rodriguez 10 Despite these negative studies, TBI outcomes have steadily improved in recent years.Reference Coronado, Xu and Basavaraju 11 The underlying explanation for this paradox is unclear, yet advances in process of care, such as protocolized management schemes aimed at effectively incorporating the additive effects of multiple therapeutic neuroprotective interventions and the development of dedicated specialized NCC units where the delivery of this care occurs, may offer an explanation.Reference Kramer and Zygun 3 , Reference Elf, Nilsson and Enblad 12 - Reference Wärme, Bergström and Persson 14

Unfortunately, the creation of dedicated NCC units poses many institutional challenges, including allocation of space and adequate numbers of available NCC specialists. Furthermore, specialized units have been associated with increased risk-adjusted mortality when admitting patients with an underlying primary diagnosis that is not in keeping with the specific area of dedicated expertise.Reference Lott, Iwashyna, Christie, Asch, Kramer and Kahn 15 Recently, it has been demonstrated that critical care of TBI patients within dedicated NCC units in the United Kingdom is associated with increased health care costs without a significant change in long-term neurological outcome versus combined general neurology intensive care units (ICUs).Reference Grieve, Sadique and Gomes 16

Although it appears that provision of NCC expertise improves long-term neurologic outcomes,Reference Kramer and Zygun 3 the optimal model for providing that care remains unclear. In 2014, we developed a consultancy NCC program within our closed mixed medical-surgical ICU. In addition to providing consultation on patients with TBI, we implemented an invasive multimodal neuromonitoring program consisting of brain tissue oxygen (PbO2) and autoregulation monitoring. The aim of this study was to examine the impact of implementing a dedicated NCC program, consisting of a collaborative model of care amongst the consulting neurosurgeon and neurointensivist with a primary care attending intensivist in a general mixed medical-surgical ICU, on long-term neurologic outcomes on patients admitted with severe TBI. Additionally, we evaluated the effects of the NCC program on the process of care metrics, including hemodynamic, neurophysiologic and temperature management, duration of intravenous sedation, mechanical ventilation, and intensive care admission.

Methods

We performed a single-center quasi-experimental uncontrolled before-and-after study in keeping with the Strengthening the Reporting of Observational Studies in Epidemiology statement.Reference Vandenbroucke, von Elm and Altman 17 This study was approved by both University of British Columbia and hospital clinical research ethics boards who waived the requirement for written informed consent (H16-01100).

Study Population and Hospitals

We defined our cohort as patients admitted to the ICU at Vancouver General Hospital (31 beds) between February 2010 and May 2016 with a diagnosis of severe TBI (postresuscitation Glasgow Coma Score [GCS] of 8 or lower and if an intracranial pressure [ICP] monitor was inserted). We excluded patients with bilaterally fixed and dilated pupils on admission. The ICU at Vancouver General Hospital is a closed, 31-bed mixed medical-surgical unit that operates on an approximate 1:1.2 nurse-to-patient ratio. It is staffed by fellowship-trained subspecialty critical care medicine physicians with consultant neurosurgeons in attendance and is affiliated with the University of British Columbia.

Data Collection

Patients were identified using the ICU administrative database. Data were then abstracted from the medical record into a standardized case report form in Microsoft Excel 2013 (Redmond, WA). Demographic data consisted of age, gender, and injury details (mechanism and date). Baseline data collected included: documented GCS, pupillary abnormalities, prehospital hypoxia (SpO2 <92%) or hypotension (systolic blood pressure <90 mmHg), and Rotterdam computed tomography head score.Reference Maas, Hukkelhoven, Marshall and Steyerberg 18 The following daily ICU management data were collected and averaged for the first 7 days: mean arterial pressure (MAP), daily mean ICP, temperature (°C), and use of medications (propofol, norepinephrine, neuromuscular blockers, barbiturates, hydrocortisone, fludrocortisone, and midazolam). Additional daily averaged data collected were: intravenous fluids per day (crystalloids, colloids, red blood cells, and mannitol), laboratory values (hemoglobin, troponin, and serum sodium), ventilation parameters (peak and plateau pressure, minute ventilation, positive end-expiratory pressure), arterial blood gases (pH, partial pressure of oxygen and carbon dioxide), and chest x-ray radiography documenting the presence of bilateral infiltrates in keeping with acute respiratory distress syndrome. Neurophysiologic data (MAP, ICP, cerebral perfusion pressure, PbO2, and pressure reactivity index, PRx) were recorded in real-time and continuously at 10-second intervals from our bedside monitors directly onto the ICM+ brain monitoring software program (Division of Neurosurgery, Cambridge University) for the duration of invasive monitoring. The values of each parameter were then averaged and recorded on a daily basis. Procedural data pertaining to surgical interventions (decompressive craniectomy, craniotomy, external ventricular drain, tracheostomy), medical interventions (therapeutic hypothermia, barbiturate use, days of intravenous sedation), and invasive neuromonitoring (days of monitoring, jugular venous oximetry, intraparenchymal ICP, PbO2, and PRx) were recorded in all patients. We obtained the following outcome data from the ICU database: intensive care and hospital days, duration (in days) of mechanical ventilation, and both intensive care and hospital mortality. Neurologic outcomes were recorded with the Glasgow Outcome Scale (GOS) and were determined at 6 months by telephone interview. GOS is an ordinal scale between 1 and 5 in which 1=death, 2=permanently vegetative state, 3=severe disability (requires help with activities of daily living), 4=moderate disability, and 5=good recovery.

Implementation of the NCC Program

Before implementing the NCC program, we used external ventricular drains (EVDs) as the sole method of ICP monitoring and patients were managed using TBI management protocols based on the Brain Trauma Foundation Guidelines.Reference Bratton, Chestnut and Ghajar 19 Our TBI management protocol is modeled after other published protocolsReference Patel, Menon, Tebbs, Hawker, Hutchinson and Kirkpatrick 13 and is presented in the supplementary appendix. The NCC program was implemented in November 2014 is based on an consultancy neurointensivist and neurosurgical model, whereas the attending intensivist maintains the primary care role for each TBI patient and within the identical geographic location of our general mixed medical and surgical ICU. At this time, we also introduced multimodal monitoring, which consists of the Camino parenchymal intracranial pressure and Licox PbO2 monitors (Integra Life Sciences, Plainsboro, NJ). EVDs were reserved as a second-tier therapy for CSF diversion with refractory intracranial hypertension. In addition, we implemented PRx monitoring using the brain monitoring software. The program prospectively records physiologic parameters from the bedside monitors (ICP, PbO2, and MAP) in real time at 10-second intervals, thereby providing a greater granularity to our data than a one per hour recording from bedside nursing flow sheets. ICM+ calculates PRx in real-time, which is a moving Pearson correlation coefficient between 30 consecutive, 10-second averaged values of MAP and corresponding ICP signals.Reference Aries, Czosnyka and Budohoski 20 Using PRx allows identification of the optimal cerebral perfusion pressure (CPP) for each patient.Reference Smielewski, Aries and Lavinio 21 Physiologic goals and suggested management strategies for ICP, CPP, and PbO2 are delineated in the TBI management protocol.

Statistical Analysis

We used Stata 10.0 (StataCorp, TX) for all analyses. All hypothesis tests were two-sided and a p value of <0.05 was considered statistically significant. Normally distributed data, non-normally distributed data, and categorical data were described with mean (standard deviation [SD]), median (interquartile range [IQR]), and proportion (percent), respectively. Univariable comparisons of continuous variables were done using t tests for normally distributed data and Mann-Whitney U test for non-normally distributed data where appropriate. The sample size was one of convenience and designed to ensure stability around our point estimates of a multivariable model. Assuming a favorable neurologic outcome of 40%, and approximately seven to eight events per covariateReference Vittinghoff and McCulloch 22 with a final model of approximately five to six covariates, a sample size of approximately 110 patients would be required. Because we had approximately 40 patients in the post-NCC group, we selected approximately 70 pre-NCC patients. To account for the competing risk of death, we calculate days free from 28 days for the following outcomes: ICU length of stay, duration of mechanical ventilation, duration of intravenous sedation, and duration of monitoring. We performed a complete-case analysis and presented the degree of missing data being when applicable.

Relationship Between NCC and Continuous Variables

To explore the relationship between NCC and daily continuous variables (MAP, CPP, ICP, temperature, hemoglobin, serum sodium, and norepinephrine dose), a linear mixed model (with patients included as a random effect) was performed. We included NCC as an indicator variable.

Relationship Between NCC and Neurologic Outcomes

We used multivariable ordinal logistic regression to model the association between NCC program implementation (as a dichotomous variable) and GOS as an ordinal variable. We chose the following covariates a priori for their potential to confound the relationship between NCC and GOS: age in years, admission GCS motor score, pupillary abnormalities (present or absent), Rotterdam score per 1-unit increase, and male gender. Fractional polynomial regression was used to determine the best functional form to include continuous covariates in the final multivariable model. All continuous variables were included in linear covariates. The proportionality assumption was tested using a likelihood-ratio test of proportionality of odds across the response categories.

Finally, we sought to determine which downstream variables may be responsible any association between NCC and GOS. As such, we performed a mediation analysis to determine the percentage of the total effect attributable to the chosen mediators.Reference Buis 23 For the purpose of this analysis, we chose readily measurable mediators that were significantly different from one another before and after implementation of NCC: temperature, MAP, and serum sodium concentration. We modeled the direct variable (NCC) and indirect variables (temperature, MAP, and serum sodium) on a dichotomized favorable neurologic outcome (GOS 4 or 5) as described by Buis.Reference Buis 23

Results

Database search revealed 76 patients before implementation of the NCC program (February 2010 to October 2014) and 39 patients following implementation of the NCC program (November 2014 to May 2016). Two patients with fixed and dilated pupils were excluded (both in the post-NCC group), leaving a total of 113 patients included in the final analysis. The overall age of the cohort was 39 years (SD, 17) and 87 of 113 (77%) were male. The median admission GCS motor score was 3 (IQR, 1-4). All injuries were blunt, with falls and motor vehicle accidents being the most frequent mechanism of injury. The baseline characteristics of the cohort are presented in Table 1. Serum ethanol levels were present in 25 of 76 (33%) and 9 of 37 (24%) pre- and post-NCC, respectively. In patients in whom ethanol was detected, the median level was 43 mmol/l (29-64) pre-NCC and 10 mmol/l (IQR, 4-50) post-NCC.

Table 1 Baseline characteristics of cohort

NCC Program and Physiologic Measures

Physiologic measures pre and post-NCC are displayed in Figure 1. Daily MAP was higher post-NCC (95 mmHg [SD, 10]) than pre-NCC (88 mmHg [SD, 10], p<0.001). Post-NCC was also associated with increased norepinephrine dose (p=0.002), but there was no difference in daily troponin levels between the two groups (p=0.54). Post-NCC was associated with lower mean temperature (36.6°C [SD, 0.90]) compared with pre-NCC (37.2°C [SD, 1.0], p=0.001). There was no difference between ICP or hemoglobin concentration comparing Pre-NCC and Post-NCC.

Figure 1 Differences in physiologic parameters pre-NCC versus post-NCC pertaining to daily averaged MAP, core body temperature, norepinephrine doses, ICP, serum sodium concentration, and hemoglobin concentration during the first 7 days of intensive care admission.

Duration of Monitoring, Sedation, ICU, and Mechanical Ventilation

The clinical interventions and outcomes for the study population are presented in Table 2. EVDs were used in all patients pre-NCC and in 14 of 37 (41%) post-NCC (p<0.0001). Patients post-NCC had fewer days of mechanical ventilation (9 [SD, 6-9] vs 12 [SD, 7-17], p=0.029), days of intravenous sedation (5 [SD, 3-6] vs 7 [SD, 4-11], p=0.0008), and days of ICP monitoring (5 [SD, 3-6] vs 7 [SD, 4-7], p=0.0001). There was no difference before and after NCC in the duration of intensive care admission or hospital stay.

Table 2 Clinical interventions and outcomes stratified by HTS

EVD=external ventricular drain; HTS=hypertonic saline.

Neurologic Outcomes

GOS stratified by NCC is presented in Figure 2. The results of the univariable and multivariable ordinal logistic regression model are presented in Table 3. Implementation of the NCC program was associated with a 2.5 increased odds (OR, 2.5; 95% CI, 1.1-5.3; p=0.022) of an improved GOS given that all other variables in the model are held constant.

Figure 2 Differences in GOS distribution in patients with severe TBI pre-NCC versus post-NCC. Percentages for each GOS point are displayed for pre- and post-NCC.

Table 3 Univariable and multivariable ordinal logistic regression for the implementation of an NCC program on 6-month GOS

Mediator Analysis

As a percentage of the total effect of NCC implementation, the attributable indirect effects of the following mediators were: temperature, 5% (95% CI, 3-9); MAP, 24% (95% CI, 16-48); and serum sodium, 15% (95% CI, 11-28). Thus, the sum of the indirect effects of these three mediators was 46%, leaving 54% of the total effect of NCC being from other factors.

Discussion

In our single-center quasi-experimental uncontrolled before-and-after study, we demonstrated improved long-term favorable neurological outcomes in patients with severe TBI following implementation of a NCC program. Furthermore, we found a significant improvement in secondary clinical outcomes following implementation of the NCC program, including decreased duration of ventilation, intravenous sedation, and days of invasive neuromonitoring. The implementation of the NCC program resulted in increased norepinephrine doses, fludrocortisone use, and MAP and decreased temperatures during the first 7 days of admission. On mediation analysis, more than half of the total benefit of NCC on favorable neurological outcomes was driven by factors other than MAP, temperature, and serum sodium.

Several controlled historical cohort studies have demonstrated improved neurologic outcomes with implementation of a dedicated NCC clinical service, albeit with several different care models in varying populations.Reference Kramer and Zygun 3 Specifically, studies have shown improvements in neurologic outcomes with the creation of a distinct NCC unit with TBIReference Patel, Menon, Tebbs, Hawker, Hutchinson and Kirkpatrick 13 , Reference Wärme, Bergström and Persson 14 and intracerebral hemorrhage (ICH).Reference Diringer and Edwards 24 Other studies have implemented standardized management protocols aimed at incorporating multiple therapeutic interventions in a structured format.Reference Lerch, Yonekawa, Muroi, Bjeljac and Keller 25 Yet other models have added a neurointensivists to existing dedicated NCC units in patients with subarachnoid hemorrhage,Reference Josephson, Douglas, Lawton, English, Smith and Ko 26 , Reference Samuels, Webb, Culler, Martin and Barrow 27 TBI,Reference Varelas, Eastwood and Yun 28 and stroke.Reference Varelas, Schultz, Conti, Spanaki, Genarrelli and Hacein-Bey 29 These have also resulted in decreased mortality and improved neurological outcome. More in keeping with our report, Pineda and colleagues examined the addition of a pediatric NCC program of care to an general ICU.Reference Pineda, Leonard and Mazotas 30 This program consisted of a time-sensitive and severity-based protocolized approach to care. They demonstrated increased favorable disposition (discharged home).

In contrast to these studies, which provide care in dedicated NCC units, we developed a consultancy-based NCC program operating within an existing closed medical-surgical academic ICU. Our model for severe TBI maintains that the primary care is delivered by the attending intensivist with both neurointensivist and neurosurgeon consultation. This collaborative model was chosen for several reasons. First, there are several logistical issues with establishing a separate NCC unit, including the availability of physical space and of neurointensivist coverage and nursing and paramedical personnel. Second, the creation of a dedicated NCC unit carries significant institutional logistical challenges of physician staffing, allied health care provider training, and institutional patient bed flow challenges with boarding and out-of-ICU patient overflow. Finally, it must be recognized that caring for patients in a separate subspecialty unit could confer unexpected risk as demonstrated in a large historical cohort study of 84,182 patients in 124 specialty and general ICUs by Lott and colleagues.Reference Lott, Iwashyna, Christie, Asch, Kramer and Kahn 15 They demonstrated that for patients admitted with specific diagnoses (e.g. acute coronary syndrome, ischemic stroke, ICH, pneumonia, abdominal surgery, coronary artery bypass graft surgery), admission to a specialty ICU, compared with a nonspecialty ICU, did not offer a survival benefit. Furthermore, when examining patients with ICH (n=3835) or ischemic stroke (n=2390), the risk-adjusted ORs for specialty ICU compared with a general ICU were 1.00 (95% CI, 0.79-1.28) and 1.35 (95% CI, 0.96-1.89), respectively. Lott and colleagues also demonstrated that when patients were admitted with ICH to a nonideal specialty ICU (e.g. ICH patient admitted to a non-NCC unit), the OR was 1.31 (95% CI, 1.03-1.66), indicating an increased risk of mortality. These data suggest that patients admitted to specialty ICUs may have increased risk of mortality when the admission diagnosis falls outside of the usual spectrum of care for that particular unit, a significant issue that would have been posed in our institution with the creation of a dedicated NCC unit. Therefore, we elected to create a NCC program that brought this crucial coordinated expert care to our patients within an existing geographical ICU structure.

A critical limitation when considering the results of our study is that we implemented an entire program of care, including both NCC consultation and multimodal neuromonitoring. We attempted to examine the attributable indirect effects of some of these factors using mediation analysis. We chose variables that were present both before and after implementation of the NCC program. Overall, changes in temperature, MAP, and serum sodium management accounted for less than 50% of the total beneficial effects of NCC. However, we were unable to quantify the attributable benefit to other factors such as PbO2 monitoring because these were not present before the NCC program was implemented. Furthermore, it may be that a combination of factors may be responsible for the improvements seen, a factor not accounted for in our analysis. Importantly, studies in neurocritical care have consistently failed to demonstrate that any single intervention results in improved outcomes. Examples of interventions rigorously studied with randomized trials in patients with TBI that have not demonstrated benefit include ICP monitoring,Reference Chesnut, Temkin and Carney 8 therapeutic hypothermia,Reference Andrews, Sinclair and Rodriguez 10 decompressive craniectomy,Reference Cooper, Rosenfeld and Murray 7 liberal transfusion threshold,Reference Robertson, Hannay and Yamal 9 and multiple pharmacologic neuroprotective strategies.Reference Temkin, Anderson and Winn 31 , Reference Wright, Yeatts and Silbergleit 32 Thus, it seems unlikely that any single intervention could account for the benefit observed in our study. This belief is supported by the recent consensus summary statement of the International Multidisciplinary Consensus Conference on Multimodal Monitoring in Neurocritical Care.Reference Le Roux, Menon and Citerio 33 It recommends both ICP and PbO2 within the context of a structured protocol, but that patient care must be individualized. The consensus statement further states that “It is difficult to demonstrate that any single monitor or combination of monitors has a positive effect on outcome, since outcome is influenced by the therapeutic plan driven by monitoring, not by monitoring itself.”Reference Le Roux, Menon and Citerio 33

Thus, in keeping with these recommendations, we implemented multimodal monitoring as part of our NCC program. In addition to the ICP/CPP monitoring that was previously used in our ICU, we added both PbO2 and cerebral autoregulation monitoring using PRx. Historical cohort studies have repeatedly established associations between adverse outcome and concurrent brain hypoxia, anemia, and intracranial hypertension after TBI.Reference Sekhon, McLean, Henderson, Chittock and Griesdale 34 - Reference Vik, Nag and Fredriksli 36 Furthermore, a historical cohort study by Spiotta and colleagues studies have also demonstrated improved neurologic outcomes with the addition of PbO2 to an established ICP/CPP protocol.Reference Spiotta, Stiefel and Gracias 37 We are still waiting for the publication of a completed phase 2 randomized trial comparing the addition of PbO2 targeted management strategy to an existing ICP/CPP protocol.Reference Diaz-Arrastia 38 We also added autoregulation monitoring as part of our NCC program. Aries and colleagues established that patients who had a favorable neurologic outcome spent a great proportion of their monitoring time with their CPP maintained within 5 mmHg of their optimal CPP as assessed by PRx.Reference Aries, Czosnyka and Budohoski 39

There are several additional limitations that need to be considered when interpreting our results. As with all quasi-experimental uncontrolled before-and-after studies, there may be a strong observer effect whereby the clinical care may improve simply by being studied.Reference Grimshaw, Campbell, Eccles and Steen 40 This study design is also subject to an overestimation of the effectiveness of the intervention. Despite our multivariable regression model to adjust for known confounders of outcome in patients with TBI, unmeasured or residual confounding may be an alternate explanation for our results. In addition, because the selection of patients for monitoring is at the discretion of the treating physician, the results may be subject to confounding by indication. This occurs when variables that are associated with outcomes in the study base are also associated with exposure variables.Reference Salas, Hofman and Stricker 41 Furthermore, we attempted to contact patients at a consistent time after injury to obtain their true 6-month functional outcome. However, these outcomes were determined short of 6 months in several of the post-NCC cohort because the study was completed before the 6-month outcome. We would expect this to lead to downward bias in the post-NCC group point estimate because neurologic outcomes continue to improve with time. Finally, we did not examine the factors associated with death in the cohort. For example, there is significant variation in mortality between centers that is driven by the decision to withdraw life-sustaining therapy.Reference Turgeon, Lauzier and Simard 42 We did not capture data on this crucial determinant of outcome; thus, the external validity of these results are limited to centers with similar practice patterns as our own.

Conclusion

Implementation of a consultancy NCC program is associated with improved clinical outcomes in patients with severe TBI who underwent invasive neuromonitoring.

Acknowledgements

We would like acknowledge the physicians, nurses, and allied health staff at Vancouver General Hospital for their contributions to the NCC program.

Disclosures

The authors do not have anything to disclose.

Statement of Authorship

DRC contributed to manuscript preparation and data analysis. DEG contributed to manuscript preparation, data collection, and data analysis. MSS undertook study design, data collection, data analysis, and manuscript preparation. PG undertook study design, data analysis, and manuscript preparation. BT undertook data analysis and manuscript preparation. NK undertook data collection and manuscript preparation. VH undertook data collection and data analysis. VKD undertook data analysis and manuscript preparation. MSH undertook data analysis and manuscript preparation.

Supplementary materials

To view supplementary material for this article, please visit https://doi.org/10.1017/cjn.2017.25

References

1. Korbakis, G, Bleck, T. The evolution of neurocritical care. Crit Care Clin. 2014;30:657-671.CrossRefGoogle ScholarPubMed
2. Kramer, AH, Zygun, DA. Neurocritical care: why does it make a difference? Curr Opin Crit Care. 2014;20:174-181.CrossRefGoogle Scholar
3. Kramer, AH, Zygun, DA. Do neurocritical care units save lives? Measuring the impact of specialized ICUs. Neurocrit Care. 2011;14:329-333.CrossRefGoogle ScholarPubMed
4. Selassie, AW, Zaloshnja, E, Langlois, JA, Miller, T, Jones, P, Steiner, C. Incidence of long-term disability following traumatic brain injury hospitalization, United States, 2003. J Head Trauma Rehabil. 2008;23:123-131.CrossRefGoogle ScholarPubMed
5. Langlois, JA, Rutland-Brown, W, Wald, MM. The epidemiology and impact of traumatic brain injury: a brief overview. J Head Trauma Rehabil. 2006;21:375-378.CrossRefGoogle ScholarPubMed
6. Chen, A, Bushmeneva, K, Zagorski, B, Colantonio, A, Parsons, D, Wodchis, WP. Direct cost associated with acquired brain injury in Ontario. BMC Neurol. 2012;12:76.CrossRefGoogle ScholarPubMed
7. Cooper, DJ, Rosenfeld, JV, Murray, L, et al. Decompressive craniectomy in diffuse traumatic brain injury. N Engl J Med. 2011;364:1493-1502.CrossRefGoogle ScholarPubMed
8. Chesnut, RM, Temkin, N, Carney, N, et al. A trial of intracranial-pressure monitoring in traumatic brain injury. N Engl J Med. 2012:2471-2481.CrossRefGoogle ScholarPubMed
9. Robertson, CS, Hannay, HJ, Yamal, J-M, et al. Effect of erythropoietin and transfusion threshold on neurological recovery after traumatic brain injury. JAMA. 2014;312:36.CrossRefGoogle ScholarPubMed
10. Andrews, PJD, Sinclair, HL, Rodriguez, A, et al. Hypothermia for intracranial hypertension after traumatic brain injury. N Engl J Med. 2015;373:2403-2412.CrossRefGoogle ScholarPubMed
11. Coronado, VG, Xu, L, Basavaraju, SV, et al. Surveillance for traumatic brain injury-related deaths—United States, 1997-2007. MMWR Surveill Summ. 2011;60:1-32.Google ScholarPubMed
12. Elf, K, Nilsson, P, Enblad, P. Outcome after traumatic brain injury improved by an organized secondary insult program and standardized neurointensive care. Crit Care Med. 2002;30:2129-2134.CrossRefGoogle ScholarPubMed
13. Patel, HC, Menon, DK, Tebbs, S, Hawker, R, Hutchinson, PJ, Kirkpatrick, PJ. Specialist neurocritical care and outcome from head injury. Intens Care Med. 2002;28:547-553.CrossRefGoogle ScholarPubMed
14. Wärme, PE, Bergström, R, Persson, L. Neurosurgical intensive care improves outcome after severe head injury. Acta Neurochir (Wien). 1991;110:57-64.CrossRefGoogle ScholarPubMed
15. Lott, JP, Iwashyna, TJ, Christie, JD, Asch, DA, Kramer, AA, Kahn, JM. Critical illness outcomes in specialty versus general intensive care units. Am J Resp Crit Care Med. 2009;179:676-683.CrossRefGoogle ScholarPubMed
16. Grieve, R, Sadique, Z, Gomes, M, et al. An evaluation of the clinical and cost-effectiveness of alternative care locations for critically ill adult patients with acute traumatic brain injury. Br J Neurosurg. 2016:1-9.Google ScholarPubMed
17. Vandenbroucke, JP, von Elm, E, Altman, DG, et al. Strengthening the Reporting of Observational Studies in Epidemiology (STROBE): explanation and elaboration. Epidemiology. 2007;18:805-835.CrossRefGoogle ScholarPubMed
18. Maas, AIR, Hukkelhoven, CWPM, Marshall, LF, Steyerberg, EW. 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. 2005;57:1173-1182.CrossRefGoogle ScholarPubMed
19. Bratton, SL, Chestnut, RM, Ghajar, J, et al. Guidelines for the management of severe traumatic brain injury. J Neurotrauma. 2007;24:s1-s106.Google ScholarPubMed
20. Aries, MJH, Czosnyka, M, Budohoski, KP, et al. Continuous determination of optimal cerebral perfusion pressure in traumatic brain injury. Crit Care Med. 2012;40:2456-2463.CrossRefGoogle ScholarPubMed
21. Smielewski, P, Aries, M, Lavinio, A, et al. Use of ICM+ software for tracking “optimal” CPP values in real time. Eur J Anaesthesiol. 2012;29:A34.CrossRefGoogle Scholar
22. Vittinghoff, E, McCulloch, CE. Relaxing the rule of ten events per variable in logistic and Cox regression. Am J Epidemiol. 2007;165:710-718.CrossRefGoogle ScholarPubMed
23. Buis, ML. Direct and indirect effects in a logit model. Stata J. 2010;10:11-29.CrossRefGoogle Scholar
24. Diringer, MN, Edwards, DF. Admission to a neurologic/neurosurgical intensive care unit is associated with reduced mortality rate after intracerebral hemorrhage. Crit Care Med. 2001;29:635-640.CrossRefGoogle ScholarPubMed
25. Lerch, C, Yonekawa, Y, Muroi, C, Bjeljac, M, Keller, E. Specialized neurocritical care, severity grade, and outcome of patients with aneurysmal subarachnoid hemorrhage. Neurocrit Care. 2006;5:85-92.CrossRefGoogle ScholarPubMed
26. Josephson, SA, Douglas, VC, Lawton, MT, English, JD, Smith, WS, Ko, NU. Improvement in intensive care unit outcomes in patients with subarachnoid hemorrhage after initiation of neurointensivist co-management. J Neurosurg. 2010;112:626-630.CrossRefGoogle ScholarPubMed
27. Samuels, O, Webb, A, Culler, S, Martin, K, Barrow, D. Impact of a dedicated neurocritical care team in treating patients with aneurysmal subarachnoid hemorrhage. Neurocrit Care. 2011;14:334-340.CrossRefGoogle ScholarPubMed
28. Varelas, PN, Eastwood, D, Yun, HJ, et al. Impact of a neurointensivist on outcomes in patients with head trauma treated in a neurosciences intensive care unit. J Neurosurg. 2006;104:713-719.CrossRefGoogle Scholar
29. Varelas, PN, Schultz, L, Conti, M, Spanaki, M, Genarrelli, T, Hacein-Bey, L. The impact of a neuro-intensivist on patients with stroke admitted to a neurosciences intensive care unit. Neurocrit Care. 2008;9:293-299.CrossRefGoogle ScholarPubMed
30. Pineda, JA, Leonard, JR, Mazotas, IG, et al. Effect of implementation of a paediatric neurocritical care programme on outcomes after severe traumatic brain injury: a retrospective cohort study. Lancet Neurol. 2013;12:45-52.CrossRefGoogle ScholarPubMed
31. Temkin, NR, Anderson, GD, Winn, HR, et al. Magnesium sulfate for neuroprotection after traumatic brain injury: a randomised controlled trial. Lancet Neurol. 2007;6:29-38.CrossRefGoogle ScholarPubMed
32. Wright, DW, Yeatts, SD, Silbergleit, R, et al. Very early administration of progesterone for acute traumatic brain injury. N Engl J Med. 2014;371:2457-2466.CrossRefGoogle ScholarPubMed
33. Le Roux, P, Menon, DK, Citerio, G, et al. 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. Int Care Med. 2014;40:1189-1209.CrossRefGoogle ScholarPubMed
34. Sekhon, MS, McLean, N, Henderson, WR, Chittock, DR, Griesdale, DE. Association of hemoglobin concentration and mortality in critically ill patients with severe traumatic brain injury. Crit Care. 2012;16:R128.CrossRefGoogle ScholarPubMed
35. Dings, J, Jäger, A, Meixensberger, J, Roosen, K. Brain tissue pO2 and outcome after severe head injury. Neurol Res. 1998;20(Suppl 1):S71-5.CrossRefGoogle ScholarPubMed
36. Vik, A, Nag, T, Fredriksli, OA, et al. Relationship of “dose” of intracranial hypertension to outcome in severe traumatic brain injury. J Neurosurg. 2008;109:678-684.CrossRefGoogle ScholarPubMed
37. Spiotta, AM, Stiefel, MF, Gracias, VH, et al. Brain tissue oxygen-directed management and outcome in patients with severe traumatic brain injury. J Neurosurg. 2010;113:571-580.CrossRefGoogle ScholarPubMed
38. Diaz-Arrastia, R. Brain Tissue Oxygen Monitoring in Traumatic Brain Injury (TBI) (BOOST 2) Available at: https://clinicaltrials.gov/ct2/show/NCT00974259.Google Scholar
39. Aries, MJ, Czosnyka, M, Budohoski, KP, et al. Continuous determination of optimal cerebral perfusion pressure in traumatic brain injury. Crit Care Med. 2012;40:2456-2463.CrossRefGoogle ScholarPubMed
40. Grimshaw, J, Campbell, M, Eccles, M, Steen, N. Experimental and quasi-experimental designs for evaluating guideline implementation strategies. Fam Pr. 2000;17(Suppl 1):S11-6.CrossRefGoogle ScholarPubMed
41. Salas, M, Hofman, A, Stricker, BH. Confounding by indication: an example of variation in the use of epidemiologic terminology. Am J Epidemiol. 1999;149:981-983.CrossRefGoogle ScholarPubMed
42. Turgeon, AF, Lauzier, F, Simard, J-F, et al. Mortality associated with withdrawal of life-sustaining therapy for patients with severe traumatic brain injury: a Canadian multicentre cohort study. CMAJ. 2011;183:1581-1588.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Baseline characteristics of cohort

Figure 1

Figure 1 Differences in physiologic parameters pre-NCC versus post-NCC pertaining to daily averaged MAP, core body temperature, norepinephrine doses, ICP, serum sodium concentration, and hemoglobin concentration during the first 7 days of intensive care admission.

Figure 2

Table 2 Clinical interventions and outcomes stratified by HTS

Figure 3

Figure 2 Differences in GOS distribution in patients with severe TBI pre-NCC versus post-NCC. Percentages for each GOS point are displayed for pre- and post-NCC.

Figure 4

Table 3 Univariable and multivariable ordinal logistic regression for the implementation of an NCC program on 6-month GOS

Supplementary material: File

Sekhon supplementary material

Sekhon supplementary material 1

Download Sekhon supplementary material(File)
File 54.3 KB