UMLS:C0268318 - FACTA Search

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The effect of decompressive trepanation was compared to that of surgical resection of the traumatized tissue in the course of traumatic brain edema in standardized experimental brain trauma. Following a right parietal cold injury, the following parameters were monitored continuously in 12 cats: ventricular pressure, epidural pressure over both hemispheres, arterial and central venous pressure and heart rate. The EEG was evaluated continuously, using a computer (power spectra). After catheterization of the superior sagittal sinus, cerebral arteriovenous differences of glucose, lactate, O2 and CO2 were calculated. 6 animals were treated surgically when showing elevated intracranial pressure ICP and markedly altered EEG. In 3 animals, the right hemisphere was decompressed by extensive resection of bone and dura. In 3 further animals, the softened brain tissue of the cold lesion was resected and the skull defect closed. 6 untreated animals were used in controls. A decompression by skull hemiresection for ablation of the injured cortex abolished the high intracranial pressure, but only the latter method seemed to prevent further damage. This could be demonstrated by the EEG registration, and by the normalization of arteriovenous metabolite differences. Only animals treated with edema resection had a normal arousal reaction and survived the trauma. The results indicate, that only an ablation of the local injury will prevent further damage to the brain. After decompressive trepanation alone, the progression of tissue edema is not interrupted. As can be seen from the literature, the poor results obtained even from extensive decompressive operations in traumatic brain edema, indicate that the further development of edema is independent of the intracranial pressure, whereas the favorable results of resection of lobar contusions show an interruption of the spread of dysbolism.
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PMID:Comparison of the effects of surgical decompression and resection of local edema in the therapy of experimental brain trauma. Investigation of ICP, EEG and cerebral metabolism in cats. 47 64

In anesthetised cats, breathing pattern, blood gases, and ventilatory response to CO2 were recorded before and during intermittent 10-minute episodes of hydrostatically raised intracranial pressure. The first effect on breathing was a stimulation which was followed at higher pressures by irregularity, depression, and periods of apnea; hyperventilation at high intracranial pressure (ICP was rare. Raised ICP did not consistently depress the ventilatory response to CO2 until ventilation during airbreathing was already depressed; therefore, we cannot experimentally justify applying this test clinically to detect incipient ventilatory depression. When hypoxemia developed during raised ICP, it was compatible with the degree of hypoventilation due to central depression of breathing; thus, there was no evidence of a neurally mediated effect on the lungs, causing defective gas exchange.
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PMID:Effect of intermittently raised intracranial pressure on breathing pattern, ventilatory response to CO2, and blood gases in anesthetized cats. 124 58

The feline infusion model of brain edema was used to evaluate the role of bradykinin in the etiology and pathophysiology of vasogenic brain edema. Bradykinin (3 or 90 ug in 600 microL saline) did not alter normocapnic regional cerebral blood flow (rCBF) nor induce specific changes in either the somatosensory (SEP) or motor (MEP) evoked potentials. The mean increases in ICP (from 4.5 to 16.1 mmHg) and peri-infusion white matter water content (from 69.4 to 79.8 ml/100 g tissue), mean decrease in lumped craniospinal compliance (from 0.040 to 0.014 ml/mmHg) and local histological changes were all similar to those after 600 microL saline infusion. The interstitial bradykinin infusion caused focal blood-brain-barrier (BBB) opening to Evans Blue dye and was chemotaxic for granulocytes. After the infusion there was a global loss of rCBF CO2 reactivity but there was no ischemia at normocapnia. These results show that bradykinin in brain edema fluid, at concentrations greater than those found in neuropathological conditions, can open the BBB of normal cerebral parenchymal capillaries and cause vascular dysregulation. In neuropathological conditions bradykinin may therefore potentiate formation of vasogenic brain edema but does not contribute to perilesional brain dysfunction.
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PMID:The role of bradykinin in the etiology of vasogenic brain edema and perilesional brain dysfunction. 159 96

Arachidonic acid solution (2 to 15 mg/ml) was infused into the right forebrain white matter of anaesthetised cats over three hours to evaluate its contribution to the genesis and pathophysiology of vasogenic brain oedema. The 0.6 ml infusion increased local white matter water content by a mean of 11.3 ml/100 g tissue but did not increase cortical water content. Histological studies revealed local expansion and trabeculation of the white matter with aggregations of granulocytic neutrophils in the venules and perivenular brain. The adjacent cortical cytoarchitecture was normal. The white matter around the infusion site was stained lightly and over a variable area (15-20 mm2) by intravenously administered Evans Blue dye 2%. Regional cerebral blood flow (rCBF) adjacent to the frontal infusion did not change significantly during the period of infusion and remained similar to rCBF in the contralateral hemisphere. Following the arachidonic acid infusion regional CBF CO2 reactivity was normal and three was no asymmetry of either cortical somatosensory evoked potential (SEP) or motor evoked potential (MEP) waveforms. The increase in brain water content and changes in the ICP and ICP related biodynamics (pressure-volume index, lumped craniospinal compliance and CSF outflow resistance) were similar to those seen following infusion of 0.6 ml saline. These studies suggest that free intraparenchymal arachidonic acid, at concentrations exceeding those occurring in most neuropathological conditions, can increase the normal brain parenchymal capillary permeability but does not disrupt focal cerebrovascular and electrophysiological function. The clinical implications of these findings are discussed.
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PMID:The contribution of arachidonic acid to the aetiology and pathophysiology of focal brain oedema; studies using an infusion oedema model. 166 51

Secondary mediator compounds are postulated to have a role in vasogenic oedematogenesis. They may also cause focal brain dysfunction due to their neuronal, axonal and glial modulating properties. Using the feline model of infusion brain oedema the effects of right frontal intracerebral infusion (200 microliters/hr for 3 hrs) of saline, bradykinin (10(-4) to 10(-6) M), arachidonic acid (10(-2) to 10(-3) M), 20% protein and four human glioma cyst fluids were evaluated. Somatosensory evoked potentials (SSEP), motor evoked potentials (MEPs), rCBF and rCBF CO2 reactivity (Hydrogen clearance). ICP, craniospinal compliance, local brain tissue water content (microgravimety), brain histology and BBB function (Evans Blue 2%) were measured. Brain water content increased locally from 69% to 79%, ICP increased (by mean 14 mmHg) and compliance decreased (mean 70%) and there were the histological features of brain oedema with all infusates. BBB opening occurred with Bradykinin (+), arachidonic acid (++), 20% protein ( ) and glioma cyst fluid (4+). Polymorphic and macrophage infiltrates were seen with all infusions but rCBF and MEPs remained normal. SSEPs changed with high dose bradykinin and some glioma cyst infusates whilst CBF CO2 reactivity was locally impaired by all infusates except saline and arachidonic acid. This study suggests that certain compounds in brain oedema fluid could mediate local brain dysfunction.
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PMID:The contribution of secondary mediators to the etiology and pathophysiology of brain oedema: studies using a feline infusion oedema model. 212 86

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

In order to investigate the usefulness of atracurium for neurosurgical anesthesia, we studied its impact on intracranial pressure (subarachnoid bolt) mean arterial pressure (radial artery catheter) and cerebral perfusion pressure (mean arterial pressure-intracranial pressure) in 20 patients undergoing elective craniotomy for brain tumor excision. General anesthesia was induced with thiopental, 4 mg/kg intravenously, and maintained with 70 percent nitrous oxide in oxygen. Ventilation was controlled by face mask, with end-tidal CO2 held constant. Once intracranial pressure and mean arterial pressure had stabilized, the response to atracurium, 0.5 mg/kg intravenously, was continuously recorded for 5 min in 10 patients. An additional 10 patients received no atracurium and served as matched controls. Thiopental caused reductions in ICP in both groups of patients. Comparing the responses of the patients who received atracurium with those who did not, we found that atracurium had no significant effect on intracranial pressure, mean arterial pressure or cerebral perfusion pressure. Based on these data we conclude that atracurium appears to be preferable to the other available neuromuscular blocking agents that have been evaluated for neurosurgical anesthesia.
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PMID:Intracranial pressure after atracurium in neurosurgical patients. 293 38

Intracranial pressure was increased in cats by infusing 'mock' CSF intracranially, thus decreasing cerebral perfusion and oxygenation. The cats then randomly received either 50% O2 or 50% O2-5% CO2 by inhalation. As monitored by in vivo near-infrared spectroscopy (NIR), no improvement was noted after 50% O2 whereas 50% O2-5% CO2 resulted in increased perfusion, an oxidation of cytochrome a,a3, an increase in oxyhemoglobin, and reduced quantities of de-oxyhemoglobin (p less than 0.01) despite a further increase in intracranial pressure. The authors conclude that: NIR is a useful means of noninvasively and directly assessing brain metabolism and has advantages over simple ICP monitoring; and continued investigations of CO2 as a possible therapeutic modality after head injury appear warranted.
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PMID:Direct noninvasive assessment of brain metabolism during increased intracranial pressure: potential therapeutic vistas. 302 65

It is widely accepted that a tremendous increase in cerebral blood volume (CBV) due to progressive cerebral vasoparesis is an essential to the development of acute brain swelling. This study was designed to determine whether neurogenic and/or metabolic factors are predominant and how these interact with each other in producing cerebral vasoparesis. Fifty-one awake cats immobilized with pancuronium bromide were divided into 4 groups: group I, control; group II, normocapnic hypoxia (PaO2 = 50 mmHg); group III, normoxic hypercapnia (Pa-CO2 = 70 mmHg), and group IV, increased intracranial pressure (ICP = 40 mmHg) by brain compression. Systemic arterial pressure (BP), CBV (photoelectric method), and ICP (epidural pressure) were continuously recorded. The dorsomedial hypothalamic nucleus (DM) and the reticular formation of the midbrain (MB-RF) were bilaterally coagulated by a stereotaxic technique (3mA, 1 min). Therefore alterations in cerebrovascular tonus created by destruction of the cerebral vasomotor centers were examined in the animals with metabolically induced cerebral vasodilatation to various degree's. In group I, vasomotor center destruction resulted in an immediate and transient decrease in BP (DM; -14.1 +/- 6.7 mmHg, MB-RF; -10.2 +/- 4.8 mmHg) and simultaneous increase in CBV and ICP (DM; 7.6 +/- 7.0 mmHg, MB-RF; 6.0 +/- 5.6 mmHg) for 3 to 4 minutes. Increase in ICP by destruction of vasomotor centers reduced significantly in group II (DM; 2.3 +/- 2.6 mmHg, MB-RF; 1.6 +/- 1.2 mmHg) and reduced slightly in group IV (DM; 7.5 +/- 4.0 mmHg, MB-RF; 4.8 +/- 3.2 mmHg). In these 3 groups, autoregulation of cerebral blood flow and CO2 vasoreactivity were not changed by destruction of vasomotor centers.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Interaction between neurogenic and metabolic factors upon deterioration in cerebrovascular tonus--experimental study on the etiology of cerebral vasoparesis]. 344 37

Brain edema represents a disturbance of the volume equilibrium which, in the early stages of formation, must be compensated for by a reduction in other fluid and blood compartments. When this compensation is inadequate, tissue pressure and intracranial pressure increase, the magnitude of which depends on the compliance of the tissue. Tissue pressure gradients develop within the same hemisphere and between hemispheres, but these pressure gradients are transient and dissipate within a few hours after injury. The rate of dissipation is proportional to the product of hydraulic tissue resistance and compliance. These tissue pressure gradients are small in magnitude, less than 15 mm Hg; however, studies with an infusion model of edema in animals show that they are more than sufficient to propel fluid through the parenchyma by a process of bulk flow. The distention caused by the fluid increases the conductance and compliance of the tissue. This biomechanical response favors the dissipation of pressure gradients, and as a result hydrostatic gradients can be sustained only with a continued leakage of fluid from the site of injury. Without a continued extravasation of fluid, equilibration of the tissue pressure to the level of the ICP occurs rapidly. For this reason, the role of hydrostatic gradients in the resorption process may be limited. The development of an infusion model allows more rigid control and simulates the edematous process. Ultrastructural studies of the infusion model have shown that the tissue changes are similar to those reported for vasogenic edema, with the exception that in the infusion model the blood-brain barrier remains intact in the vicinity of the lesion and is not compromised by the mechanical distention of the ECS. The response of the cerebrovasculature to the infusion edema is in contrast to the usual reduction of flow seen after cryogenic injury. The CBF remains constant despite increased tissue water, as confirmed by gravimetric technique. The CO2 reactivity of the vessels in the area of edema is reduced, but the autoregulation to changes in perfusion pressure remains intact. When arterial pressure is raised beyond the limit of autoregulation, the pressure increase of CBF in the edematous area is less than the rise of CBF in normal tissue and suggests a "false autoregulation" caused by an increased tissue pressure. The differences in both the intracranial pressure and CBF response between these two models suggests that other factors must be operative. The cryogenic injury is indeed a traumatic injury to the brain and cannot be simply characterized by the increase in brain tissue water. In some animals a vasomotor paralysis disrupting the vascular compartmental volume and leading to a rapid rise in ICP with eventual reduction of CPP and CBF may explain these differences. Release of vasoactive substances into the ECS is an exciting hypothesis and is an area of investigation ideally suited to the infusion edema process where chemical composition of the fluid can be easily controlled.
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PMID:Biomechanics of brain edema and effects on local cerebral blood flow. 745 51

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