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Query: UMLS:C0020672 (hypothermia)
 17,327 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Five methods of therapy for increased ICP were used in the treatment of 32 head-injured patients. The effects of steroids could not be evaluated. Withdrawal of CSF was always effective because intracranial volume was reduced and pressure must follow, but because of brain swelling and collapse of the ventricular system in this group of patients, it was not an effective permanent form of therapy. Hypertonic Mannitol reduced ICP in nearly every case irrespective of the degree of brain damage or the height of ICP. Hyperventilation was least effective in the most severely ill patients, presumably due to the non-responsiveness of the cerebral vessels to changes in PaCO2. The poorest response of ICP seemed to be with hypothermia.
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PMID:Analysis of the response to therapeutic measures to reduce intracranial pressure in head injured patients. 93 13

During the last decade several studies of cerebral blood flow (CBF) and metabolism in the acute phase of head injury have been published. It is the aim of this review to describe the dynamic changes in CBF, cerebral metabolic rate of oxygen (CMRO2), cerebral autoregulation (CA), and reactivity to PaCO2 and barbiturate (metabolic reactivity) in the acute phase after severe head injury and to discuss the therapeutical consequences with reference to prolonged artificial hyperventilation, hypothermia, barbiturate sedation, and mannitol therapy. On the basis of present knowledge concerning cerebral circulation and its regulation, the author reviews the literature concerning methodology for experimental and clinical CBF measurements and regulation of CBF and cerebral oxygen uptake. Emphasis is placed on studies of the effect of body temperature (hypothermia) as a therapeutic tool in the control of cerebral metabolism, blood flow, and intracranial pressure. Although hypothermia significantly reduces cerebral metabolism and blood flow, the effect of hypothermia on cerebral blood flow, metabolism, ICP, and outcome after acute head injury has never been investigated in clinically controlled studies. Experimental and clinical studies concerning sensitivity of CBF for changes in PaCO2 are reviewed. The normal CO2 reactivity defined as absolute (delta CBF/delta PaCO2) and relative (% change CBF/delta PaCO2) or delta in CBF/PaCO2 mm Hg are mentioned. In awake normocapnic man the relative CO2 reactivity averages 4%/mm Hg and the absolute CO2 reactivity 2ml/mm Hg. Uncontrolled prospective studies show a therapeutic effect of artificially prolonged hyperventilation on outcome. Only one preliminary controlled study indicates that the outcome is poorer and recovery prolonged. Nevertheless, in the acute phase of HI, artificial hyperventilation is used routinely for control of intracranial hypertension and during the intensive care management of the patients. The steal and inverse steal phenomena are reviewed. Although of considerable theoretical interest these phenomena are without clinical significance in patients with head injury, unless clinical CBF measurements are performed. The frequency of the inverse steal phenomenon in studies of rCBF with a 16-channel Cerebrograph (intraarterial approach) is found to be about 10%. During prolonged hyperventilation experimental studies and clinical studies of apoplexy show an adaptation of CBF and CSF-pH and bicarbonate.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Cerebral blood flow in acute head injury. The regulation of cerebral blood flow and metabolism during the acute phase of head injury, and its significance for therapy. 227 29

Cross-brain oxygen extraction may be altered by coma, hyperventilation, hypothermia, or barbiturates, and has been demonstrated in adults and more recently in children to be related to functional neurologic recovery after a variety of brain injuries. However, measurement of cross-brain oxygen extraction in children is currently not a part of routine clinical care, partly because there have been no published attempts relating the technique of jugular venous bulb (JVB) catheterization and its complication in children. We catheterized the JVB to measure cerebral venous oxygen content and calculate cross-brain oxygen extraction in 26 deeply comatose neonates and children ranging in age from a few hours to 14 yr. Bedside catheterization using the Seldinger technique was successful in 25 children, with standard venous cutdown necessary in the remaining child. All JVB catheterizations were performed with parental consent and during continuous monitoring of the intracranial (ICP) or fontanelle, as well as arterial, pressure. ICP was not significantly altered by the cannulation procedure in any of the children studied, although the cannulation occurred early in the child's course when ICP was well controlled. Inadvertent carotid artery puncture with bleeding controlled by local pressure occurred in four children, and catheter malposition was confirmed on lateral skull xray in two others. Jugular venous bulb catheters remained in place for 2 to 7 days (average 3) and malfunction or obstruction of the catheter did not occur. Organisms were grown from three of 26 catheter tips submitted for culture, with peripheral blood cultures also positive for the same organisms in two of these.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Jugular venous bulb catheterization in infants and children. 231 61

In order to optimize therapy for the injured brain it is desirable to continuously monitor substrate delivery in the critically ill patient. Interruption of substrate delivery is a major factor of the great vulnerability to ischemic damage, which affects a majority of patients after severe head injury, stroke or subarachnoid hemorrhage. An approach to protecting the brain during ischemia is to increase the delivery of oxygen via residual blood flow through ischemic tissue. Hypothermia is also an important means of protecting brain cells from the deleterious effects of ischemia, after severe head injury, because it reduces metabolic demands. In this study we continuously measured brain oxygen, brain CO2, brain pH and brain temperature, as well as hourly brain glucose and lactate. A multiparameter sensor was inserted into brain tissue, via a three lumen bolt, along with a ventriculostomy catheter and a microdialysis probe in 60 severely head injured patients. Brain oxygen delivery was increased by stepwise increase of inspired oxygen (FiO2) from 30% to 60% to 100% over a period of 6 h, in order to test the effect of enhanced oxygen tension, on tissue oxygen. In most patients brain oxygen was initially low, and progressively increased, over the monitoring period, to a steady state level, around 30-40 mmHg. In those who died or remained vegetative, brain oxygen fell to anerobic levels. Episodes of increased ICP (n = 25), hypotension (n = 15), and respiratory difficulties (n = 9) caused an immediate increase in brain CO2. Multiple logistic regression analysis showed brain oxygen to be the strongest predictor for outcome in these patients. By increasing FiO2, an increase in oxygen delivery of more than 100%, and a simultaneous decline in lactate production was seen (p < 0.01). Brain temperature was closely related to rectal temperature, brain oxygen, and cerebral blood flow. Patients who were spontaneously hypothermic had a poor outcome (p < 0.01). A fuller understanding of dynamic factors affecting brain metabolism and substrate delivery may be obtained with extended neuromonitoring.
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PMID:Extended neuromonitoring: new therapeutic opportunities? 958 32

The recovery of injured neurons in primely brain damage, neuroprotection to the secondary brain damage (such as brain edema, brain ischemia, free radicals, neuroexcitation and ICP elevation), activation of gene-tropic regeneration, and prevention of apobiosis are major targets on the management of severe brain injury. However, excess release of catecholamines (catecholamine surge) make a very difficult to control of cerebral hypoxia by changes of systemic blood circulations. Mild cerebral hypothermia is only one method to prevent of these catecholamines surge. We developed new technique, cerebral hypothermia that control brain tissue temperature at 32-34 degrees C with more than 800 ml/min. oxygen delivery at acute stage. Combination therapy with these cerebral hypothermia and replacement of cerebral dopamine-pituitary hormone-estrogen was very successful to prevent of vegetation after severe brain injury.
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PMID:[The control of brain tissue temperature and stimulation of dopamine-immune system to the severe brain injury patients]. 964 93

Current treatment of many conditions associated with elevated ICP of the brain involves stabilization and oxygenation with maintenance of adequate perfusion of cerebral tissue, while maintaining an acceptable ICP. As an example of a standard protocol that is in concordance with what is already known about a patient with a severe head injury, the first priority is radiographic screening for a surgical lesion. Further treatment, as shown by the previously outlined studies, includes keeping the patient normothermic, normoglycemic, and normocapnic, and placing an indwelling ICP monitor. Acutely elevated ICP is treated with mannitol, and if this fails, patients are routinely sedated, paralyzed, and mildly hyperventilated, while repeat radiology is obtained to rule out a further surgical lesion. Hypothermia, aggressive hyperventilation, and barbiturate coma continue to be used and are reserved for intractable ICP elevation, or as warranted based on a specific patient (Table 2).
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PMID:An evidence-based approach to management of increased intracranial pressure. 970 Apr 43

The injured brain may be damaged by primary impact, secondary injury from secondary damage due to initiation of destructive inflammatory and biochemical cascades by the primary injury or secondary ischemic injury following secondary insults that initiate or augment these immunological and biochemical cascades. Cerebral ischemia will arise whenever delivery of oxygen and substrates to the brain fall below metabolic needs. Many factors lead to the development of secondary insults to the injured brain during initial resuscitation, transport, surgery, and subsequent intensive care. Continuous monitoring of cerebral oxygenation (jugular oximetry, brain tissue PO2) and cerebral blood flow velocity (transcranial Doppler ultrasonography) in patients with brain trauma reveals multiple episodes of transient hypoperfusion with an adverse relationship between incidence and outcome. Secondary brain insults arise through systemic or intracranial mechanisms that reduce cerebral blood flow from compromised CPP, vascular distortion or cerebrovascular narrowing or lower oxygen delivery from hypoxemia associated with airway obstruction, pulmonary pathology, or anemia. Secondary brain ischemia remains a common pathway to secondary brain damage in most critically ill neurosurgical patients. In the future prevention of secondary brain injury may well hinge on giving a cocktail of novel agents that modify destructive biochemical and inflammatory pathways, each having a potential therapeutic window possibly in a subgroup of patients. To date, phase 3 clinical trials of several agents including PEGSOD and tyrilizad mesylate have failed to show relevant efficacy after brain trauma or subarachnoid hemorrhage. The therapeutic role of calcium channel blockers in traumatic subarachnoid hemorrhage is currently under investigation following the results of subgroup metaanalysis. Several phase 3, NMDA receptor antagonist studies are underway in brain trauma with results expected soon. Although we know that secondary insults promote excitotoxic secondary brain damage there is currently no pharmacological intervention with proven efficacy and, therefore, detection and correction of secondary insults appear to offer the best therapeutic strategy. After brain trauma, systemic hypotension, compromised CPP, raised ICP, elevated temperature, hypoxemia, and jugular bulb venous desaturation are associated with poor prognosis. Clinical trials of moderate hypothermia following brain trauma are ongoing. Following adult brain trauma maintenance of CPP above at least 65 mmHg (probably > 40 mmHg in children below 8 years) seems important to improve outcome indicating the need for continuous ICP monitoring during intensive care of brain-injured patients.
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PMID:Mechanisms and prevention of secondary brain damage during intensive care. 970 38

Intracranial hypertension leading to brain stem herniation is a major cause of death in fulminant hepatic failure (FHF). Mannitol, barbiturates, and hyperventilation have been used to treat brain swelling, but most patients are either refractory to medical management or cannot be treated because of concurrent medical problems or side effects. In this study, we examined whether allogeneic hepatocellular transplantation may prevent development of intracranial hypertension in pigs with experimentally induced liver failure. Of the two preparations tested--total hepatectomy (n = 47), and liver devascularization (n = 16)--only pigs with liver ischemia developed brain edema provided, however, that animals were maintained normothermic throughout the postoperative period. This model was then used in transplantation studies, in which six pigs received intrasplenic injection of allogeneic hepatocytes (2.5 x 10(9) cells/pig) and 3 days later acute liver failure was induced. In both models (anhepatic state, liver devascularization), pigs allowed to become hypothermic had significantly longer survival compared to those maintained normothermic. Normothermic pigs with liver ischemia had, at all time points studied, ICP greater than 20 mmHg. Pigs that received hepatocellular transplants had ICP below 15 mmHg until death; at the same time, cerebral perfusion pressure (CPP) in transplanted pigs was consistently higher than in controls (45 +/- 11 mmHg vs. 16 +/- 18 mmHg; p < 0.05). Spleens of transplanted pigs contained clusters of viable hepatocytes (hematoxylin-eosin, CAM 5.2). It was concluded that removal of the liver does not result in intracranial hypertension; hypothermia prolongs survival time in both anhepatic pigs and pigs with liver devascularization, and intrasplenic transplantation of allogeneic hepatocytes prevents development of intracranial hypertension in pigs with acute ischemic liver failure.
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PMID:Transplantation of hepatocytes for prevention of intracranial hypertension in pigs with ischemic liver failure. 971 Mar 4

Intracranial pressure depends on cerebral tissue volume, cerebrospinal fluid volume (CSFV) and cerebral blood volume (CBV). Physiologically, their sum is constant (Monro-Kelly equation) and ICP remains stable. When the blood brain barrier (BBB) is intact, the volume of cerebral tissue depends on the osmotic pressure gradient. When it is injured, water movements across the BBB depend on the hydrostatic pressure gradient. CBV depends essentially on cerebral blood flow (CBF), which is strongly regulated by cerebral vascular resistances. In experimental studies, a decrease in oncotic pressure does not increase cerebral oedema and intracranial hypertension (ICHT). On the other hand, plasma hypoosmolarity increases cerebral water content and therefore ICP, if the BBB is intact. If it is injured, neither hypoosmolarity nor hypooncotic pressure modify cerebral oedema. Therefore, all hypotonic solutes may aggravate cerebral oedema and are contra-indicated in case of ICHT. On the other hand, hypooncotic solutes do not modify ICP. The osmotic therapy is one of the most important therapeutic tools for acute ICHT. Mannitol remains the treatment of choice. It acts very quickly. An i.v. perfusion of 0.25 g.kg-1 is administered over 20 minutes when ICP increases. Hypertonic saline solutes act in the same way, however they are not more efficient than mannitol. CO2 is the strongest modulating factor of CBF. Hypocapnia, by inducing cerebral vasoconstriction, decreases CBF and CBV. Hyperventilation is an efficient and rapid means for decreasing ICP. However, it cannot be used systematically without an adapted monitoring, as hypocapnia may aggravate cerebral ischaemia. Hyperthermia is an aggravating factor for ICHT, whereas moderate hypothermia seems to be beneficial both for ICP and cerebral metabolism. Hyperglycaemia has no direct effect on cerebral volume, but it may aggravate ICHT by inducing cerebral lactic acidosis and cytotoxic oedemia. Therefore, infusion of glucose solutes is contra-indicated in the first 24 hours following head trauma and blood glucose concentration must be closely monitored and controlled during ICHT episodes.
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PMID:[The internal environment and intracranial hypertension]. 975 May 95

Elevated temperature is known to facilitate neuronal injury after ischemia. After head injury a gradient between temperature and body temperature of up to 3 degrees C higher in the brain has been reported. Hypothermia may limit some of the deleterious metabolic consequences of such increased temperature. In 20 patients who had suffered severe ischemic stroke in the middle cerebral artery (MCA) territory, intracerebral temperature combined with ICP monitoring was recorded using two different thermocouples, with epidural, and parenchymatous measurements. Mild hypothermia was induced using cooling blankets. Patients were kept at 33 degrees C core temperature for 48 to 72 hours. In all patients brain temperature exceeded body-core temperature by at least up to 1 degree C (range 1.0-2.1 degrees C). Systemic cooling was effective and sustained hypothermic (33-34 degrees C) brain temperatures. With mild hypothermia critically elevated ICP values could be controlled. 12 patients survived the hemispheric stroke with a mean Barthel index of 70. Severe side effects of hypothermia were not detected. After MCA stroke, human intracerebral temperature is higher than central body-core temperature. Mild hypothermia in the treatment of severe cerebral ischemia using cooling blankets is safe and does not lead to severe side effects. Mild hypothermia can help to control critically elevated ICP values in severe space-occupying stroke and may improve clinical outcome in these patients.
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PMID:Moderate hypothermia and brain temperature in patients with severe middle cerebral artery infarction. 977 65


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