Alois Zauner

The importance of brain temperature in patients after severe head injury: Relationship to intracranial pressure, cerebral perfusion pressure, cerebral blood flow, and outcome

Brain temperature was continuously measured in 58 patients after severe head injury and compared to rectal temperature, intracranial pressure, cerebral blood flow, and outcome after 3 months. The temperature difference between brain and rectal temperature was also calculated. Mild hypothermia (34-36 degrees C) was also used to treat uncontrollable intracranial pressure (ICP) above 20 mm Hg when other methods failed. Brain and rectal temperature were strongly correlated (r = 0.866; p < 0.001). Four groups were identified. The mean brain temperature ranged from 36.9 +/- 0.4 degrees C in the normothermic group to 38.2 +/- 0.5 degrees C in the hyperthermic group, 35.3 +/- 0.5 degrees C in the mild therapeutic hypothermia group, and 34.3 +/- 1.5 degrees C in the hypothermia group without active cooling. The mean DeltaT(br-rect) was positive for patients with a T(br) above 36.0 degrees C (0.0 +/- 0.5 degrees C) and negative for patients during mild therapeutic hypothermia (-0.2 +/- 0.6 degrees C) and also in those with a brain temperature below 36 degrees C without active cooling (0.8 +/- -1.4 degrees C) - the spontaneous hypothermic group. The cerebral perfusion pressure (CPP) was increased significantly by active cooling compared to the normothermic and hyperthermic groups. The mean cerebral blood flow (CBF) in patients with a brain temperature between 36.0 degrees C and 37.5 degrees C was 37.8 +/- 14.0 mL/100 g/min. The lowest CBF was measured in patients with a brain temperature <36.0 degrees C and a negative brain-rectal temperature difference (17.1 +/- 14.0 mL/100 g/min). A positive trend for improved outcome was seen in patients with mild hypothermia. Simultaneous monitoring of brain and rectal temperature provides important diagnostic and prognostic information to guide the treatment of patients after severe head injury (SHI) and the wide differentials that can develop between the brain and core temperature, especially during rapid cooling, strongly supports the use of brain temperature measurement if therapeutic hypothermia is considered for head injury care.

Cerebral oxygenation in patients after severe head injury: monitoring and effects of arterial hyperoxia on cerebral blood flow, metabolism and intracranial pressure.

Early impaired cerebral blood flow (CBF) after severe head injury (SHI) leads to poor brain tissue oxygen delivery and lactate accumulation. The purpose of this investigation was to elucidate the relationship between CBF, local dialysate lactate (lact(md)) and dialysate glucose (gluc(md)), and brain tissue oxygen levels (PtiO2) under arterial normoxia. The effect of increased brain tissue oxygenation due to high fractions of inspired oxygen (FiO2) on lact(md) and CBF was explored. A total of 47 patients with SHI were enrolled in this studies (Glasgow Coma Score [GCS] < 8). CBF was first assessed in 40 patients at one time point in the first 96 hours (27 +/- 28 hours) after SHI using stable xenon computed tomography (Xe-CT) (30% inspired xenon [FiXe] and 35% FiO2). In a second study, sequential double CBF measurements were performed in 7 patients with 35% FiO2 and 60% FiO2, respectively, with an interval of 30 minutes. In a subsequent study, 14 patients underwent normobaric hyperoxia by increasing FiO2 from 35 +/- 5% to 60% and then 100% over a period of 6 hours. This was done to test the effect of normobaric hyperoxia on lact(md) and brain gluc(md), as measured by local microdialysis. Changes in PtiO2 in response to changes in FiO2 were analyzed by calculating the oxygen reactivity. Oxygen reactivity was then related to the 3-month outcome data. The levels of lact(md) and gluc(md) under hyperoxia were compared with the baseline levels, measured at 35% FiO2. Under normoxic conditions, there was a significant correlation between CBF and PtiO2 (R = 0.7; P < .001). In the sequential double CBF study, however, FiO2 was inversely correlated with CBF (P < .05). In the 14 patients undergoing the 6-hour 100% FiO2 challenge, the mean PtiO2 levels increased to 353 (87% compared with baseline), although the mean lact(md) levels decreased by 38 +/- 16% (P < .05). The PtiO2 response to 100% FiO2 (oxygen reactivity) was inversely correlated with outcome (P < .01). Monitoring PtiO2 after SHI provides valuable information about cerebral oxygenation and substrate delivery. Increasing arterial oxygen tension (PaO2) effectively increased PtiO2, and brain lact(md) was reduced by the same maneuver.

MULTIPARAMETRIC CONTINUOUS MONITORING OF BRAIN METABOLISM AND SUBSTRATE DELIVERY IN NEUROSURGICAL PATIENTS

Brain function and tissue integrity are highly dependent on continuous oxygen supply and clearance of CO2. Aerobic metabolism is the major energy source to normal brain, however, during hypoxia and ischemia, lactate accumulation may sometimes be seen, indicating anaerobic glycolysis after severe head injury. Current monitoring techniques often fail to detect such events which can affect substrate delivery to the injured brain. We have recently adapted a method for continuous monitoring of brain tissue pO2, pCO2, pH and temperature, using a single sensor. The multiparameter sensor is inserted into brain tissue, via a new three lumen bolt, together with a standard ventriculostomy catheter and a microdialysis probe. The system has been left in place as long as needed, but never more than 7 days. All readings were compared to clinical parameters, and outcome. Stable measurements could be obtained in the first group of 20 patients, after calibration and rigid fixation, using the new bolt. Severely head injured patients had brain oxygen levels of less than 25-30 mmHg for the first hours after injury. Thereafter two patterns could be seen. Patients with favorable outcome had a slow increase in brain oxygen, and brain CO2 decreased to normal values, as long as the cerebral perfusion pressure (CPP) was kept above 70 mmHg. However, in those patients with secondary ischemic events, and bad outcome, a further decline in brain oxygen to anaerobic levels (< 20 mmHg) was seen. For these patients, both decreased and increased brain CO2 levels could be seen. Brain CO2 levels of 90-150 mmHg were consistently seen after brain death. Brain pH was inversely related to brain CO2 for all patients. Brain glucose and lactate in patients with poor outcome were 639 microM l-1 +/- 330, and 1642 microM l-1 +/- 788, whereas patients with good outcome had brain glucose levels of 808 microM l-1 +/- 321 and lactate levels of 1001 microM l-1 +/- 417. Extended neuromonitoring using a combined sensor for brain oxygen, CO2, pH and temperature measurements, as well as a microdialysis probe for glucose and lactate analysis may optimize the management of comatose neurosurgical patients in the future, by allowing a fuller understanding of dynamic factors affecting brain metabolism.

Glutamate Release and Cerebral Blood Flow After Severe Human Head Injury

Elevations of extracellular glutamate have been found in patients with prolonged brain ischemia and focal cerebral contusions, following severe head injury. About 30% of severely head injured patients develop cerebral ischemia, defined as CBF < 18 ml/100g/min. Patients with both global and regional cerebral ischemia have the worst outcome. However, the relationship between CBF and EAA release is not well understood in head injured humans, and may differ from the findings in normal animals. To study the relationship between EAA release and CBF after severe head injury, we performed cerebral blood flow measurements using stable xenon enhanced computed tomography and correlated these with glutamate release in the extracellular fluid, measured by continuous microdialysis, in 25 severely head injured patients. Sustained cerebral blood flow reductions below the threshold for ischemic neuronal damage was closely related to massive excitatory amino acid release, as in previous animal studies. In patients without secondary ischemia, or focal contusions, delayed post-traumatic glutamate release appeared to be only transient or did not occur at all.

Relationship between brain temperature, brain chemistry and oxygen delivery after severe human head injury: The effect of mild hypothermia

Abstract We studied brain temperature and the effect of mild hypothermia in 58 patients after severe head injury (SHI). Brain tissue oxygen tension (ptiO2), carbon dioxide tension (ptiCO2), tissuie pH (pHti) and temperature (Tbr) were measured using a multiparameter probe. Microdialysis was performed to measure glucose, lactate, glutamate, and aspartate in the extracellular fluid. Mild hypothermia (34° – 36°C) was employed in 33 selected patients who had persistent increased intracranial pressure (ICP > 20 mmHg). Mild induced hypothermia decreased brain oxygen significantly from 33 ± 24 mmHg to 30 ± 22 mmHg (p < 0.05). The ptiCO2 (46 ± 8 mmHg) was also significantly lower during mild hypothermia (40.4 ± 4.0 mmHg), p < 0.0001). The pH i increased from 7.13 ± 0.15 to 7.24 ± 0.10 (p < 0.0001) under hypothermic conditions. Induced hypothermia may protect patients from secondary ischemic events by lowering the critical ptiO2 threshold, reducing anaerobic metabolism, and decreasing the release of excitatory aminoacids. However, patients with spontaneous brain hypothermia on admission (Tbr < 36.0°C) showed significantly higher levels of glutamate as well as lactate, compared to all other patients, and had a worse outcome. Spontaneous brain hypothermia carries a poor prognosis, and was characterized by markedly abnormal brain metabolic indices. [Neurol Res 2002; 24: 161-168]

Substrate Delivery and Ionic Balance Disturbance After Severe Human Head Injury

The most important early pathomechanism in traumatic brain injury (TBI) is alteration of the resting membrane potential. This may be mediated via voltage, or agonist-dependent ion channels (e.g. glutamate-dependent channels). This may result in a consequent increase in metabolism with increased oxygen consumption, in order to try to restore ionic balance via the ATP-dependent pumps. We hypothesize that glutamate is an important agonist in this process and may induce an increase in lactate, potassium and brain tissue CO2, and hence a decrease in brain pH. Further we propose that an increase in lactate is thus not an indicator of anaerobic metabolic conditions as has been thought for many years. We therefore analyzed a total of 85 patients with TBI, Glasgow Coma Scale (GCS) < 8 using microdialysis, brain tissue oxygen, CO2 and pH monitoring. Cerebral blood flow studies (CBF) were performed to test the relationship between regional cerebral blood flow (rCBF) and the metabolic determinants. Glutamate was significantly correlated with lactate (p < 0.0001), potassium (p < 0.0001), brain tissue pH (p = 0.0005), and brain tissue CO2 (p = 0.006). rCBF was inversely correlated with glutamate, lactate and potassium. 44% of high lactate values were observed in brain with tissue oxygen values, above the threshold level for cell damage. These results support the hypothesis of a glutamate driven increase in metabolism, with secondary traumatic depolarization and possibly hyperglycolysis. Further, we demonstrate evidence for lactate production in aerobic conditions in humans after TBI. Finally, when reduced regional cerebral blood flow (rCBF) is observed, high dialysate glutamate, lactate and potassium values are usually seen, suggesting ischemia worsens these TBI-induced changes.

Extracranial carotid artery pseudoaneurysm presenting with embolic stroke in a pediatric patient. Case report.

Extracranial carotid artery (CA) aneurysms are rare in the pediatric population and are usually the result of connective tissue disorders, traumatic dissection, or infection. The authors present the case of a large calcified internal carotid artery pseudoaneurysm of obscure origins presenting with embolic stroke in a child. Aneurysm excision and CA reconstruction would have been extremely difficult due to the distal location of the lesion, and CA ligation was contraindicated due to a failed balloon test occlusion. Therefore, after anticoagulation therapy, the patient was treated endovascularly with a covered stent and complete exclusion of the aneurysm from the circulation. The patient recovered all neurological function and has remained in excellent condition. A follow-up angiogram performed at 6 months showed no recurrence or stenosis.

rCBF in hemorrhagic, non-hemorrhagic and mixed contusions after severe head injury and its effect on perilesional cerebral blood flow

Intracerebral contusions can lead to regional ischemia caused by extensive release of excitotoxic aminoacids leading to increased cytotoxic brain edema and raised intracranial pressure. rCBF measurements might provide further information about the risk of ischemia within and around contusions. Therefore, the aim of the presented study was to compare the intra- and perilesional rCBF of hemorrhagic, non-hemorrhagic and mixed intracerebral contusions. In 44 patients, 60 stable Xenon-enhanced CT CBF-studies were performed (EtCO2 30 +/- 4 mmHg SD), initially 29 hours (39 studies) and subsequent 95 hours after injury (21 studies). All lesions were classified according to localization and lesion type using CT/MRI scans. The rCBF was calculated within and 1-cm adjacent to each lesion in CT-isodens brain. The rCBF within all contusions (n = 100) of 29 +/- 11 ml/100 g/min was significantly lower (p < 0.0001, Mann-Whitney U) compared to perilesional rCBF of 44 +/- 12 ml/100 g/min and intra/perilesional correlation was 0.4 (p < 0.0005). Hemorrhagic contusions showed an intra/perilesional rCBF of 31 +/- 11/44 +/- 13 ml/100 g/min (p < 0.005), non-hemorrhagic contusions 35 +/- 13/46 +/- 10 ml/100 g/min (p < 0.01). rCBF in mixed contusions (25 +/- 9/44 +/- 12 ml/100 g/min, p < 0.0001) was significantly lower compared to hemorrhagic and non-hemorrhagic contusions (p < 0.02). Intracontusional rCBF is significantly reduced to 29 +/- 11 ml/100 g/min but reduced below ischemic levels of 18 ml/100 g/min in only 16% of all contusions. Perilesional CBF in CT normal appearing brain closed to contusions is not critically reduced. Further differentiation of contusions demonstrates significantly lower rCBF in mixed contusions (defined by both hyper- and hypodense areas in the CT-scan) compared to hemorrhagic and non-hemorrhagic contusions. Mixed contusions may evolve from hemorrhagic contusions with secondary increased perilesional cytotoxic brain edema leading to reduced cerebral blood flow and altered brain metabolism. Therefore, the treatment of ICP might be individually modified by the measurement of intra- and pericontusional cerebral blood.

Microdialysis nitric oxide levels and brain tissue oxygen tension in patients with subarachnoid hemorrhage

Nitric oxide (NO) is a highly reactive molecule that is believed to be involved in many physiological events. In the brain, nitric oxide has been implicated in a number of biological responses such as neurotransmitter modulation, retrograde neurotransmitter and synaptic plasticity. Nitric oxide diffuses across membranes and has guanylate cyclase in the smooth muscle as its primary target, by which nitric oxide leads to vasodilation thus regulating cerebral blood flow [3].

Spontaneous Cerebral Hypothermia After Severe Head Injury: Relation with Brain Chemistry and Cerebrovascular Parameters

Secondary ischemic events are one of the major causes of bad outcome in patients with severe traumatic brain injury (TBI). Multiple clinical trials testing diverse neuroprotective compounds have so far failed to provide new therapies. Nevertheless, multiple studies using hypothermia have shown evidence of benefit, and the latest results of a U.S. multicenter hypothermia trial are awaited. Meanwhile hypothermia is being used in many neurosurgical centers all over the world and especially in Japan. We therefore retrospectively analyzed patients suffering from TBI with a Glascow Coma Scale (GCS) score of 8 or less. We studied brain temperature using a multiparameter sensor, brain chemistry using microdialysis, intracranial pressure (ICP) using a ventriculostomy, and cerebral blood flow (CBF) using stable-xenon CT. Patients were retrospectively separated into four temperature cohorts according to their brain temperature. Patients with spontaneous hypothermia (Tbr < 36°C) significantly differed from the other cohorts. The mean ICP (P < 0.01), cerebral perfusion pressure (CPP) (P < 0.001), and glutamate P < 0.0004) were significantly higher, whereas the CBF (P < 0.05) and brain glucose were lower. A negative brain temperature-rectal temperature (Trect) difference (ΔTbr-Trect) was correlated with a bad outcome as observed in the patients with spontaneous brain hypothermia and those with therapeutic cooling. When monitoring severely brain-injured patients, spontaneous brain hypothermia and a negative brain to rectal temperature difference (ΔTbr-Trect) represents an indicator of bad outcome and brain chemistry derangement (glutamate, lactate, glucose) and CBF.