Intracranial Pressure Monitoring: Fundamental Considerations and Rationale for Monitoring

Traumatic brain injury (TBI) is a major cause of death and disability worldwide. In large part critical care for TBI is focused on the identification and management of secondary brain injury. This requires effective neuromonitoring that traditionally has centered on intracranial pressure (ICP). The purpose of this paper is to review the fundamental literature relative to the clinical application of ICP monitoring in TBI critical care and to provide recommendations on how the technique maybe applied to help patient management and enhance outcome. A PubMed search between 1980 and September 2013 identified 2,253 articles; 244 of which were reviewed in detail to prepare this report and the evidentiary tables. Several important concepts emerge from this review. ICP monitoring is safe and is best performed using a parenchymal monitor or ventricular catheter. While the indications for ICP monitoring are well established, there remains great variability in its use. Increased ICP, particularly the pattern of the increase and ICP refractory to treatment is associated with increased mortality. Class I evidence is lacking on how monitoring and management of ICP influences outcome. However, a large body of observational data suggests that ICP management has the potential to influence outcome, particularly when care is targeted and individualized and supplemented with data from other monitors including the clinical examination and imaging.     

2058例重型颅脑创伤颅内压动态监护分析

目的 探讨颅内压(intraeranial pressure,ICP)持续动态监护对重型颅脑创伤(severe traumatic brain injury,sTBI)救治的指导意义.方法 分别采用脑窜内及脑实质内ICP监护法,对2058例sTBI患者进行ICP持续动态监护,观察ICP与患者生命体征、临床表现和预后的关系,分析其对脑室外引流及其他降颅压治疗的指导作用.结果 ICP持续动态监护末并发严重颅内感染及出血,脑室外引流对持续ICP增高者有显著的治疗作用,ICP值与患者预后呈显著负相关.结论 ICP持续动态临护安全、易行,其有助于sTBI患者病情变化的及时、正确判断,能为临床医生制定治疗方案及预后病人评估提供重要的参考依据.     

Goal Directed Brain Tissue Oxygen Monitoring Versus Conventional Management in Traumatic Brain Injury: An Analysis of In Hospital Recovery

Background

Brain tissue oxygen monitoring (pBtO2) has been advocated in the treatment of patients with severe traumatic brain injuries (TBI); however, controversy exists regarding the improvements that pBtO2 monitoring provides. The objective of our study was to evaluate our experience and effect on mortality with goal directed pBtO2 monitoring for severe TBI compared to traditional ICP/CPP monitoring.

Methods

All patients admitted with severe TBI (GCS < 8) to our Level 1 trauma center from June 2007 through June 2009 were retrospectively analyzed. All patients had ICP monitoring and pBtO2 monitors were placed based on the current practices of the attending neurosurgeon producing two temporally matched cohorts of patients with and without pBtO2 monitors. Exclusion criteria were age <18 years and survival <24 h. Goal-directed therapy was utilized in all patients to maintain ICP <20 mmHg and CPP >60 mmHg. Patients with pBtO2 monitors were managed to maintain a level >20 mmHg.

Results

74 patients were treated for severe TBI over the 2-year study period with 37 patients in each group. Both groups were similar in age, sex, and admission Glascow Coma Score(GCS).The pBtO2-monitored group did, however, have significantly lower injury severity score [26 (25–30) vs. 30 (26–36), p = 0.03] and AIS Chest [0 (0–0) vs. 2 (0–3), p = 0.02]. There was no survival difference found (64.9 vs. 54.1 %, p = 0.34). No difference with respect to discharge GCS or discharge Functional Independence Measure score was identified.

Conclusions

Compared with ICP/CPP-directed therapy alone, the addition of pBtO2 monitoring did not provide a survival or functional status improvement at discharge. The true clinical benefit of pBtO2 monitoring will require further study.     

Moderately elevated intracranial pressure after diffuse traumatic brain injury is associated with exacerbated neuronal pathology and behavioral morbidity in the rat

Traumatic brain injury (TBI)-induced elevated intracranial pressure (ICP) is correlated with ensuing morbidity/mortality in humans. This relationship is assumed to rely mostly on the recognition that extremely elevated ICP either indicates hematoma/contusions capable of precipitating herniation or alters cerebral perfusion pressure (CPP), which precipitates global ischemia. However, whether subischemic levels of elevated ICP without hematoma/contusion contribute to increased morbidity/mortality remains unknown. To address this knowledge gap, we utilized a model of moderate diffuse TBI in rats followed by either intraventricular ICP monitoring or manual ICP elevation to 20 mm Hg, in which CPP was above ischemic levels. The effects of ICP elevation after TBI on acute and chronic histopathology, as well as on behavioral morbidity, were evaluated. ICP elevation after TBI resulted in increased acute neuronal membrane perturbation and was also associated with reduced neuronal density at 4 weeks after injury. Somatosensory hypersensitivity was exacerbated by ICP elevation and was correlated to the observed neuronal loss. In conclusion, this study indicates that morbidity and increased neuronal damage/death associated with elevated ICP can occur without concurrent global ischemia. Therefore, understanding the pathologies associated with subischemic levels of elevated ICP could lead to the development of better therapeutic strategies for the treatment and management of TBI patients.     

Association Between Optic Nerve Sheath Diameter and Mortality in Patients with Severe Traumatic Brain Injury

Purpose

Increased intracranial pressure (ICP) is associated with worse outcomes following traumatic brain injury (TBI). Studies have confirmed that ICP is correlated with optic nerve sheath diameter (ONSD) on ultrasound. The aim of our study was to assess the independent relationship between ONSD measured using CT and mortality in a population of patients admitted with severe TBI.

Methods

We conducted a retrospective cohort study of patients with a TBI requiring ICP monitoring admitted to the ICU between April 2006 and May 2012 to two neurotrauma centers. ONSD was independently measured by two physicians blinded to patient outcomes. Multivariable logistic regression modeling was used to assess an association between ONSD and hospital mortality.

Results

A total of 220 patients were included in the analysis. Overall, the cohort had a mean age of 35 (SD 17) years and 171 of 220 (79 %) were male. The median admission GCS was 6 (IQR 3–8). Intra-class correlation coefficient between raters for ONSD measurements was 0.92 (95 % CI 0.90–0.94, P < 0.0001). On multivariable analysis, each 1 mm increase in ONSD was associated with a twofold increase in hospital mortality (OR 2.0, 95 % CI 1.2–3.2, P = 0.007). Using linear regression, ONSD was independently associated with increased ICP in the first 48 h after admission (β = 4.4, 95 % CI 2.5–6.3, P < 0.0001).

Conclusions

In patients with TBI, ONSD measured on CT scanning was independently associated with ICP and mortality.     

Indomethacin: a review of its cerebral blood flow effects and potential use for controlling intracranial pressure in traumatic brain injury patients.

Traumatic brain injury (TBI) causes about 75,000 deaths and leaves approximately 200,000 people disabled in USA each year. Brain swelling and increased intracranial pressure (ICP) contribute to this morbidity and mortality. Aggressive management protocols, including ICP control, have been shown to reduce the overall mortality from 50% to 36% following severe head injury. Despite these encouraging results, new and improved pharmacologic strategies to control ICP are required. Indomethacin (IND) is a non-steroidal anti-inflammatory agent with unique effects on cerebral blood flow physiology which may be of benefit in reducing elevated ICP in TBI patients. Data from animal models and randomized, controlled studies with pre-term infants have shown that i.v. IND produces rapid, significant reductions in cerebral blood flow (CBF). Controlled studies of i.v. IND in normal volunteers show a reduction in CBF from 26%-40%. Case series involving severe TBI patients suggest that IND i.v. boluses of 30-50 mg reduce ICP by 37%-52%, reduce CBF by 22%-26%, with a modest 14% increase in cerebral perfusion pressure (CPP). Despite these encouraging results, i.v. IND should only be considered an experimental treatment for control of refractory ICP in TBI patients. Larger, well-designed randomized trials in TBI patients will provide more efficacy and safety data and delineate the effects of IND alone or in combination with other proven, effective, or experimental therapies. Once these concerns have been addressed, larger outcome studies will ultimately be needed to determine the role of IND for ICP control in TBI patients.     

Intracranial Pressure Monitoring in Acute Liver Failure: Institutional Case Series

Acute liver failure (ALF) has been associated with cerebral edema and elevated intracranial pressure (ICP), which may be managed utilizing an ICP monitor. The most feared complication of placement is catastrophic intracranial hemorrhage in the setting of severe coagulopathy. Previous studies reported hemorrhage rates between 3.8–22 % among various devices, with epidural catheters having lower hemorrhage rates and precision relative to subdural bolts and intraparenchymal catheters. We sought to identify institutional hemorrhagic rates of ICP monitoring in ALF and its associated factors in a modern series guided by protocol implantation. Patient records treated for ALF with ICP monitoring at Mayo Clinic in Rochester, MN from 1995 to 2014 were reviewed. Protocalized since 1995, epidural (EP) ICP monitors were first used followed by intraparenchymal (IP) for stage III–IV hepatic encephalopathy. The following variables and outcomes were collected: patient demographics, ICPs and treatment methods, laboratory data, imaging studies, number of days for ICP monitoring, radiographic and symptomatic hemorrhage rates, orthotopic liver transplantation rates, and death. A total of 20 ICP monitors were placed for ALF, 7 EP, and 13 IP. International normalized ratio (INR) at placement of an EP monitor was 2.4 (1.7–3.2) with maximum of 2.7 (2.0–3.6) over the following 2.3 (1–3) days. Mean EP ICP at placement was 36.3 (11–55) and maximum of 43.1 (20–70) mm Hg. INR at placement of an IP monitor was 1.3 (<0.8–3.0) with maximum value of 2.9 (1.6–5.4) over the following 4.2 (2–6) days. Mean IP ICP at placement was 9.9 (2–19) and maximum was 39.8 (11–100) mm Hg. There was one asymptomatic hemorrhage in the EP group (14.3 % hemorrhage rate) and two hemorrhages in the IP group (hemorrhage rate was 15.4 %), both of which were fatal. Overall mortality rate in the EP group was 71.4 % (5/7) with two patients receiving transplantation, and one death in the transplant group. Overall mortality in the IP group was 38.5 % (5/13) with nine liver transplantations; three of the transplanted patients died, including one of the fatal hemorrhages due to monitor placement. Intracranial hypertension is common in patients with ALF with severe hepatic encephalopathy. Monitored patients in both groups experienced elevations of ICP in the setting of intermittent coagulopathy. Severity of coagulopathy did not influence hemorrhage rate. Yet, hemorrhages related to IP monitoring can be catastrophic and may add to the overall mortality.     

Indomethacin: A review of its cerebral blood flow effects and potential use for controlling intracranial pressure in traumatic brain injury patients

Abstract

Traumatic brain injury (TBI) causes about 75,000 deaths and leaves approximately 200,000 people disabled in USA each year. Brain swelling and increased intracranial pressure (ICP) contribute to this morbidity and mortality. Aggressive management protocols,including ICP control, have been shown to reduce the overall mortality from 50% to 36% following severe head injury. Despite these encouraging results, new and improved pharmacologic strategies to control ICP are required. Indomethacin (IND) is a non-steroidal anti-inflammatory agent with unique effects on cerebral blood flow physiology which may be of benefit in reducing elevated ICP in TBI patients. Data from animal models and randomized, controlled studies with pre-term infants have shown that i.v. IND produces rapid, significant reductions in cerebral blood flow (CBF). Controlled studies of I.v. IND in normal volunteers show a reduction In CBF from 26%-40%. Case series involving severe TBI patients suggest that IND i.v. boluses of 30-50mg reduce ICP by 37%-52%, reduce CBF by 22%-26%, with a modest 14% increase in cerebral perfusion pressure (CPP). Despite these encouraging results, i.v. IND should only be considered an experimental treatment for control of refractory ICP in TBI patients. Larger, well-designed randomized trials in TBI patients will provide more efficacy and safety data and delineate the effects of IND alone or in combination with other proven, effective, or experimental therapies. Once these concerns have been addressed, larger outcome studies will ultimately be needed to determine the role of IND for ICP control in TBI patients. [Neurol Res 1999; 21: 491-499]     

Intracranial Pressure and Cerebral Perfusion Pressure Monitoring in Non-TBI Patients: Special Considerations

The effect of intracranial pressure (ICP) and the role of ICP monitoring are best studied in traumatic brain injury (TBI). However, a variety of acute neurologic illnesses e.g., subarachnoid hemorrhage, intracerebral hemorrhage, ischemic stroke, meningitis/encephalitis, and select metabolic disorders, e.g., liver failure and malignant, brain tumors can affect ICP. The purpose of this paper is to review the literature about ICP monitoring in conditions other than TBI and to provide recommendations how the technique may be used in patient management. A PubMed search between 1980 and September 2013 identified 989 articles; 225 of which were reviewed in detail. The technique used to monitor ICP in non-TBI conditions is similar to that used in TBI; however, indications for ICP monitoring often are intertwined with the presence of obstructive hydrocephalus and hence the use of ventricular catheters is more frequent. Increased ICP can adversely affect outcome, particularly when it fails to respond to treatment. However, patients with elevated ICP can still have favorable outcomes. Although the influence of ICP-based care on outcome in non-TBI conditions appears less robust than in TBI, monitoring ICP and cerebral perfusion pressure can play a role in guiding therapy in select patients.     

Intracranial pressure monitoring in severe traumatic brain injury--results of a Canadian survey

OBJECTIVE: The purpose of this study was to obtain information from Canadian neurosurgeons regarding their opinions on, and utilization of, intracranial pressure (ICP) monitoring for severe traumatic brain injury (TBI). METHODS: A brief survey was sent to practicing Canadian neurosurgeons questioning them about their utilization of, and confidence in, intracranial pressure monitoring in the management of patients with severe TBI. RESULTS: One hundred and ninety-six surveys were mailed. There were 103 responses for a response rate of 52.6%. The vast majority of responding neurosurgeons (98.1%) utilized ICP monitoring in the management of patients with severe TBI, with most (63.4%) using it in more than 75% of their patients, 14.9% using it in 50-75% of patients, 14.9% in 25-50% of patients, and 6.9% using it in less than 25% of patients. The level of confidence that routine monitoring improves outcome from severe TBI ranged from 23.3% having a low level of confidence, 56.3% having an intermediate level of confidence, to 20.4% having a high level of confidence. Most respondents (78.6%) felt that some form of prospective trial evaluating the role of ICP monitoring in improving outcome from severe TBI was warranted; 17.4% felt such a trial was not warranted and 3.9% were uncertain. CONCLUSIONS: While ICP monitoring has gained almost universal acceptance among responding Canadian neurosurgeons, their level of confidence that routine monitoring improves outcome from severe TBI was quite variable, with only 20.4% of respondents having a high level of confidence. Over 75% of respondents felt that some form of prospective trial evaluating the utility of ICP monitoring is warranted. This information is being used in consideration of a prospective trial addressing this issue.     

Pediatric intracranial pressure monitoring in hypoxic and nonhypoxic brain injury

We reviewed the results of all pediatric patients undergoing intracranial pressure (ICP) monitoring in a 2-year period at our institution. The outcome of patients suffering hypoxia or ischemic injuries (HII) is compared to those suffering non-hypoxic or non-ischemic injuries (NHII). Thirty-four patients had ICP monitors placed during the study period. Inconplete patient information led to the exclusion of 5 patients. An additional 5 patients were excluded because no measures to control ICP were taken after the monitor was placed. Twenty-four patients required treatment for raised ICP (hyperventilation, 24; mannitol, 19; barbiturate coma, 6). Admission Glasgow Coma Score in patients suffering HII (median score 5) and NHII (median score 6) were not significantly different (Mann-Whitney U Test). Only 2 of 8 patients with HII were near-drowning vietims. The remaining 6 had HII from other causes (5 survivors of various forms of asphyxia and 1 of cardiac arrest). All 8 patients had poor outcomes (1 severely disabled; 7 died). The 16 patients with NHII had a variety of diagnoses (6 trauma, 5 encephalitis, 4 bacterial meningitis, 1 diabetic ketoacidosis). Among these, 6 had good outcomes and 10 poor outcomes (2 severely disabled, 2 vegetative, and 6 died). The difference in outcome between patients with NHII and HII is significant at P=0.059 (Fischer Exact test). Patients with NHII may benefit from ICP monitoring. Patients with HII from near-drowning and other causes did not appear to benefit from ICP monitoring and interventions directed at controlling ICP.     

Failure of an effective physiologic threshold compliance tool to demonstrate benefit in a clinical trial of traumatic brain injury patients

BackgroundBetter physiologic threshold compliance holds promise for improving outcomes in neurocritical care patients.MethodsOur group developed a threshold compliance tool. This software computes and displays the proportion of values out of range in real time. We captured intracranial pressure (ICP) measures in our patients before and after implementation of this technology. Ten months after the threshold compliance tool was introduced we initiated a randomized controlled trial involving acute traumatic brain injury (TBI) patients to assess whether the tool was effective at reducing out-of-range ICP values.ResultsA total of 54 patients with ICP monitors were included in our analysis, 42 of whom sustained a TBI. Implementation of the threshold compliance tool was associated with an 85.3% reduction in ICP values exceeding 22 mmHg in neurocritical care patients (p = 0.004) and a 76.8% reduction in patients with TBI (p = 0.043). Out-of-range values in an area-under-the-curve analysis were reduced by 78.8% in all patients (p = 0.009) and in TBI patients by 77.9% (p = 0.051). Out-of-range values were not further reduced during our randomized controlled trial examining the threshold compliance tool, and a difference between treatment groups was not suggested.ConclusionsImplementation of a threshold compliance tool was associated with a marked and significant reduction in out-of-range ICP values. Benefit was, however, not evident in a randomized controlled trial. Our analysis provides a unique perspective on our failure to detect an apparent true difference and may provide insights into other neurotrauma trial failures.     

Continuous Monitoring of Cerebrovascular Reactivity Using Pulse Waveform of Intracranial Pressure

Background

Guidelines for the management of traumatic brain injury (TBI) call for the development of accurate methods for assessment of the relationship between cerebral perfusion pressure (CPP) and cerebral autoregulation and to determine the influence of quantitative indices of pressure autoregulation on outcome. We investigated the relationship between slow fluctuations of arterial blood pressure (ABP) and intracranial pressure (ICP) pulse amplitude (an index called PAx) using a moving correlation technique to reflect the state of cerebral vasoreactivity and compared it to the index of pressure reactivity (PRx) as a moving correlation coefficient between averaged values of ABP and ICP.

Methods

A retrospective analysis of prospective 327 TBI patients (admitted on neurocritical care unit of a university hospital in the period 2003?C2009) with continuous ABP and ICP monitoring.

Results

PAx was worse in patients who died compared to those who survived (?0.04?±?0.15 vs. ?0.16?±?0.15, ??²?=?28, p?2?=?6, p?=?0.01).

Conclusions

PAx is a new modified index of cerebrovascular reactivity which performs equally well as established PRx in long-term monitoring in severe TBI patients, but importantly is potentially more robust at lower values of ICP. In view of establishing an autoregulation-oriented CPP therapy, continuous determination of PAx is feasible but its value has to be evaluated in a prospective controlled trail.     

Neuromonitorización en el traumatismo craneoencefálico grave. Datos del Registro español de Trauma en UCI (RETRAUCI)

ObjectivesTo analyze the use of intracranial pressure (ICP) and cerebral oximetry monitoring in patients with severe traumatic brain injury (TBI) according to the Spanish Trauma ICU Registry (RETRAUCI).MethodsWe included TBI patients with Glasgow Coma Scale score ≤ 8. Hypotheses were tested using the Student-T or Wilcoxon tests (quantitative variables) and the Chi-square test (categorical variables). Multivariate analysis using logistic regression was performed to analyze the variables associated with the use of ICP monitoring.ResultsWe analyzed 1463 patients. Age 49.1 years. Males 1130 (77.3%). Mechanism of injury: falls in 350 cases (23.9%). Injury Severity Score 27.9. Uni- or bilateral mydriasis was present in 39.3% of the patients. Neurosurgical intervention within 24 hours was performed in 331 patients (22.7%). ICP was monitored in 635 patients (45.1%), pbtO2 in 122 patients (8.6%), SjVO₂ in 19 patients (1.34%) and NIRS was used in 25 cases (1.77%). In the multivariate analysis, age, bilateral mydriasis at admission and previous use of antiplatelets or anticoagulants was inversely related with ICP monitoring. Severity of injury and the need of neurosurgical intervention increased the probability of ICP monitoring.ConclusionsOur study shows a picture of ICP monitoring in severe TBI patients in our environment. Use of cerebral oximetry techniques is very limited.     

重型颅脑创伤患者死亡率与其血清脂质过氧化物水平相关(英文)

There is a hyperoxidative state in patients with trauma brain injury( TBI). Malondialdehyde( MDA) is an end-product formed during oxidative stress,concretely lipid peroxidation. In small studies( highest sample size 50 patients),higher levels of MDA have been found in non-surviving than surviving TBI patients. However,an association between serum MDA levels and mortality in patients with TBI has not been reported. Thus,the objective of this prospective,observational,multicenter study,carried out in six Spanish Intensive Care Units,was to determine whether MDA serum levels are associated with early mortality in a large series of patients with severe TBI. Serum MDA levels were measured in 100 patients with severe TBI on day 1 and in 75 healthy controls. The end-point of the study was 30-day mortality.We found higher serum MDA levels in patients with severe TBI than in healthy controls( P 0. 001). Non-surviving TBI patients( N =27) showed higher serum MDA levels( P 0. 001) than survivors( N = 73). Logistic regression analysis showed that serum MDA levels were associated with 30-day mortality( OR = 4. 662; 95% CI = 1. 466- 14. 824; P = 0. 01),controlling for Glasgow coma score,age and computed tomography findings. Survival analysis showed that patients with serum MDA levels higher than 1. 96 nmol /mL presented increased 30-day mortality than patients with lower levels( Hazard ratio =3. 5; 95% CI =1. 43-8. 47; P 0. 001). Thus,the most relevant new finding of our study,the largest to date on serum MDA levels in patients with severe TBI,was an association between serum MDA levels and early mortality.     

Double function of noninvasive intracranial pressure monitoring based on flash visual evoked potentials in unconscious patients with traumatic brain injury

Intracranial pressure (ICP) monitoring based on flash visual evoked potentials (F-VEP) is a noninvasive method of monitoring ICP. The early diagnosis of traumatic optic neuropathy (TON) in unconscious patients with traumatic brain injury (TBI) is a challenge. The aim of this study was to evaluate the function of F-VEP ICP monitoring in predicting TON and detecting contusion enlargement (CE) in unconscious TBI patients using a modified approach. A series of F-VEP ICP-monitored unconscious TBI patients were included in the study. The interocular differences in N2 wave latency (DL) and amplitude (DA) were obtained through monocular flash stimulation. The increases in ICP (dxP) and interchannel difference (dxDC) across various time points were obtained through binocular flash stimulation. The predictive power of DL and DA on TON, as well as of dxP and dxDC on CE, was assessed by logistic regression and receiver operating characteristic (ROC) curve analysis. Patients with TON had a longer DL and a higher DA than those without TON. The dxP and dxDC of patients with CE were both higher than those of patients without CE. The differences were statistically significant. The logistic regression showed that both DL and DA were predictors of TON, whereas only dxDC was a predictor of CE. However, the ROC curve analysis showed that DL had greater predictive power for TON, and dxDC had greater predictive power for CE. An F-VEP ICP monitoring system with a modified approach is beneficial for early diagnosis of TON and prediction of CE in unconscious TBI patients.     

The relationship between basal cisterns on CT and time-linked intracranial pressure in paediatric head injury

Purpose  

Although intracranial pressure (ICP) monitoring is a cornerstone of care for severe traumatic brain injury (TBI), the indications for ICP monitoring in children are unclear. Often, decisions are based on head computed tomography (CT) scan characteristics. Arguably, the patency of the basal cisterns is the most commonly used of these signs. Although raised ICP is more likely with obliterated basal cisterns, the implications of open cisterns are less clear. We examined the association between the status of perimesencephalic cisterns and time-linked ICP values in paediatric severe TBI.     

Serum ceruloplasmin and copper are early biomarkers for traumatic brain injury‐associated elevated intracranial pressure

High intracranial pressure (ICP) is a prominent secondary pathology after traumatic brain injury (TBI) and is a major contributor to morbidity and mortality. Currently, there are no clinically proven methods for predicting which TBI patients will develop high ICP. In the present study, we examined whether the serum levels of the copper‐binding protein ceruloplasmin are differentially altered in patients with elevated ICP (≥25 mmHg) vs. those whose ICP remained below 20 mmHg throughout the study period. Consistent with its role as an acute‐phase reactant, we found that ceruloplasmin levels were significantly increased by 3 days post‐TBI compared with healthy volunteers. However, prior to this delayed increase, ceruloplasmin levels during the first 24 hr following injury were found to be significantly reduced in patients who subsequently developed high ICP. This decrease was found to have prognostic accuracy in delineating TBI patients based on their ICP status (cutoff of 140 μg/ml; sensitivity: 87%, specificity: 73%), Likewise, low total serum copper (below 1.32 μg/ml) was also found to be predictive of high ICP (sensitivity 86%, specificity 73%). These results suggest that initial serum ceruloplasmin/copper levels may have diagnostic value in predicting patients at risk for developing high intracranial pressure. © 2010 Wiley‐Liss, Inc.     

Physiological Monitoring of the Severe Traumatic Brain Injury Patient in the Intensive Care Unit

Traumatic brain injury (TBI) is a major cause of morbidity and mortality worldwide. Despite encouraging animal research, pharmacological agents and neuroprotectants have disappointed in the clinical environment. Current TBI management therefore is directed towards identification, prevention, and treatment of secondary cerebral insults that are known to exacerbate outcome after injury. This strategy is based on a variety of monitoring techniques that include the neurological examination, imaging, laboratory analysis, and physiological monitoring of the brain and other organ systems used to guide therapeutic interventions. Recent clinical series suggest that TBI management informed by multimodality monitoring is associated with improved patient outcome, in part because care is provided in a patient-specific manner. In this review we discuss physiological monitoring of the brain after TBI and the emerging field of neurocritical care bioinformatics.     

The Epidemiology of Traumatic Brain Injury: A Review

Summary:  Purpose: Traumatic brain injury (TBI) not only has considerable morbidity and mortality, but it is a major cause of epilepsy. We wish to determine the frequency of TBI, special groups at risk for TBI, and mortality from TBI.
Methods: We reviewed studies of TBI that are either population based or derived from definable catchment areas that allow determination of incidence, identification of risk groups, and mortality. We review methodology used in epidemiologic studies of TBI and try to distinguish this data from that of head injury not necessarily affecting the brain. We report epidemiologic characteristics of TBI, including incidence, differences by age, gender, race and ethnic group, and geographic variation, and mortality.
Results: Population-based studies in the United States suggest that the incidence of TBI is between 180 and 250 per 100,000 population per year. Incidence may be higher in Europe and South Africa. There are groups at high risk for TBI. This includes males and individuals living in regions characterized by socioeconomic deprivation. There are selective age groups at risk for TBI. This includes the very young, adolescents and young adults, and the elderly. Mortality varies by severity but is high in those with severe injury and in the elderly.
Conclusions: TBI is a major public health problem as well as a major cause of epilepsy. If primary prevention is to be undertaken, we must understand the epidemiology of the condition. The primary causes of TBI vary by age, socioeconomic factors, and geographic region, so any planned interventions must be tailored accordingly.