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Query: UMLS:C0020440 (hypercapnia)
 7,939 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Thirteen adult rabbits were exposed to a breathing air mixture containing an increasing amount of CO2 for eight weeks. When the CO2 content reached 9 Vol% the animals became apathic and lost body weight. The EEG showed a reduction of the amplitudes of 1o Hz frequences. Blood gases revealed an increase of bicarbonate but no change of pH. The blood brain barrier which was tested when the animals were killed was not disturbed. Enzyme histochemistry, light and electron microscopy revealed that moderate brain edema had occurred. From these results it is concluded that chronic hypercapnia has a hypnotic effect which in combination with chronic edema may depress vital activities considerably. However, there seem to be no irreversible morphological alterations of the brain.
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PMID:The effect of prolonged experimental hypercapnia on the brain. 2 57

The present studies were performed in order to determine whether "filtration edema" will develop as a consequence of cerebral vasoparalysis, vasoparalysis in combination with arterial hypertension or arterial hypertension alone. A series of dogs, anaesthetised with i.v. Chloralose-Urethane were exposed 1) to cerebral vasoparalysis, produced by hypercapnia (PaCO2 about 150 mm Hg) and hypoxaemia (PaO2 40-60 mm Hg); 2) to arterial hypertension and 3) to a combination of cerebral vasoparalysis and arterial hypertension. Following cerebral vasoparalysis and arterial hypertension, a significant decrease of total cerebrovascular resistance and moderate increase of venous resistance was observed. Regional cerebral blood flow (133Xe), intracranial pressure, as well as the pressure in postcapillary venous outflow (sinus sagittalis wedge pressure and confluence sinuum pressure) were increased. Neither normotonic vasoparalysis nor vasoparalysis in combination with slight arterial hypertension (MABP more than 90 min above 180 mm Hg) resulted in cerebral edema. In contrast, cerebral vasoparalysis in combination with severe arterial hypertension (MABP more than 90 min above 220 mm Hg) resulted in a statistically significant increase in the water content in the white matter without evidence of protein extravasation. Multiple small foci of Evans blue extravasates, however, were found in the cortex following arterial hypertension in combination with vasodilation, indicating a damage of the blood brain barrier. In these blue stained cortical areas the water content was significantly in creased. The following conclusions were drawn from the results. Vasoparalysis during normotension does not produce brain edema despite the slightly elevated hydrostatic pressure gradient between intravasal and extracellular space. Only considerable increase of this hydrostatic pressure gradient caused by a combination of vasoparalysis with severe arterial hypertension is able to produce brain edema in the white matter. In addition, acute hypertension may cause minor multifocal damage of the blood brain barrier in the cerebral cortex. It is concluded that so-called brain swelling, which has been described by several authors in states of cerebral vasoparalysis, is not predominantly caused by brain edema but by vascular congestion. The clinical aspects of the result are discussed.
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PMID:[Cerebral vasoparalysis, arterial hypertension and brain edema (author's transl)]. 5 29

The effects of hypoxia and superimposed hypercapnia or hypertension during hypoxia on brain tissue water content, pH, and electric activity were studied in Sprague-Dawley and stroke-prone spontaneously hypertensive rats. Auditory brainstem responses and sensory evoked potentials were recorded during the experiment as the indices for cerebral oxygen metabolism. The brains were removed immediately, 1 day, and 2 days after hypoxic insult for gravimetric study. The brain water content increased in all groups on the 1st and 2nd days after hypoxia. The percentage change from the control water content increased only on the 1st day in hypoxic rats. In contrast, it increased on both the 1st and 2nd days after hypoxia in hypercapnic or hypertensive rats. The evoked potentials of hypoxic and hypercapnic-hypoxic rats showed that peak latencies were prolonged significantly during hypoxia and recovered 1 and 2 days after hypoxia. The brain tissue pH decreased during hypoxia and recovered after hypoxia. This study suggests that brain edema develops within 2 days of hypoxic insult and that superimposed hypercapnia or hypertension promotes the brain edema.
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PMID:The effect of hypoxia on brain edema--the promoting effect of superimposed hypercapnia or hypertension. 128 17

Eleven observations of severe multicystic encephalopathy ( MCE ) in young infants and in a two-year-old child provide the basis for a summing-up and discussion of the various aspects of this characteristic polyetiologic phenomenon occurring in early infancy. In all cases the triggering causes or underlying disorders were different, although in five cases the common pathogenetic mechanism was a disturbance of circulation and/or respiration (acute respiratory distress syndrome). In two cases the basic disorders were a suppurative and a granulomatous meningoencephalitis. Carbon monoxide poisoning had occurred in one and diffuse meningocerebral angiomatosis in another two cases. In the eleventh case, one of a complicated twin birth, the exact cause of the MCE remained obscure. These cases together with those recorded in the literature demonstrate that the surprisingly constant pattern of damage in MCE , which results from different etiologic conditions, should be due to a specific mode of reaction of the infantile brain to a common pathogenetic mechanism. Anoxia with hypercapnia and the formation of brain edema are discussed as the basic events in the pathogenesis of MCE .
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PMID:Multicystic encephalopathy--a polyetiologic condition in early infancy: morphologic, pathogenetic and clinical aspects. 632 15

Perioperative ischemic complications not directly related to surgery require special attention in patients with moyamoya disease; positron emission tomography (H(2) 15O-PET) and single-photon emission computed tomography have been considered indispensable for evaluating pre- and postsurgical cerebral hemodynamics. The clinical records of 14 patients with moyamoya disease who underwent 26 extracranial-intracranial bypass operations were reviewed with special reference to perisurgical complications. One patient developed multiple postoperative ischemic infarctions and died of ischemic brain edema. The history of this patient with prolonged acidosis is analyzed, and the role of metabolic changes induced by H(2) 15O-PET with acetazolamide challenge is reviewed. Seven (77.8%) of nine patients operated on within 48 hours after H(2) 15O-PET with acetazolamide (group 1) developed metabolic acidosis, whereas only three (17.6%) of 17 patients operated on >48 hours (group 2) after the examination had intraoperative pH of <7.35. In group 1, the mean intraoperative pH was 7.328, which was significantly lower than the mean pH of 7.393 (P <.0001) in group 2. After H(2) 15O-PET with acetazolamide challenge, patients must be carefully observed concerning acidosis and volume state. We recommend at least 48 hours between examination and surgery for patients with moyamoya disease so that their conditions can stabilize. Furthermore, special care should be taken to avoid additional perioperative risk factors such as hypotension, hypocapnia, hypercapnia, and hypovolemia.
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PMID:Metabolic changes after H(2) 15O-positron emission tomography with acetazolamide in a patient with moyamoya disease: case report and review of previous cases. 1265 99

Cerebellar masses are a heterogenous group of conditions that can cause compression of the aqueduct or fourth ventricle, resulting in obstructive hydrocephalus, brainstem compression, and upward/downward herniation as a direct result of mass effect. Untreated lesions can be fatal in a few hours, but prompt and appropriate treatment of the mass effect can produce very good outcomes. These patients should be closely followed in a critical care setting that has rapid access to neurosurgical expertise. Medical measures to decrease brain edema should be taken, including elevation of the head of the bed and avoidance of hypo-osmolar solutions, hypercarbia, or hyperthermia. Osmotic diuretics should be initiated promptly in patients with clinical worsening and radiographic evidence of edema resulting in mass effect. However, medical measures should not delay surgical intervention, which should proceed as rapidly as possible when indicated. Cerebellar hemorrhages more than 3 cm in diameter and cerebellar hemispheric strokes involving more than one third of the hemisphere should be considered for early suboccipital craniotomy with decompression. Regardless of lesion size, neurologic deterioration and radiologic signs of obstructive hydrocephalus should call for emergency decompressive surgery with resection of hematoma or necrotic brain tissue. Ventriculostomy should be considered as a bridge to surgical decompression, given the theoretical concern of upward herniation mediated by supratentorial drainage in the face of an underlying posterior fossa mass lesion. Steroids are not indicated for cerebrovascular disease but should be used to treat vasogenic edema induced by tumor. Anticoagulation is reserved for cerebellar venous and dural sinus thrombosis. Specific treatments targeting the underlying pathology should be used aggressively: thrombolysis and endovascular interventions for eligible stroke patients, antibiotic therapy for abscesses, and radiotherapy, chemotherapy, or both for tumors.
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PMID:Treatment of cerebellar masses. 1833 36

Curcumin, extracted from South Asian spice turmeric, has been determined to have the promising ability in antioxidation and anti-inflammation. However, the effect of curcumin on treating brain damage has been not reported. In this article, the aim was to evaluate the effect of curcumin on cell apoptosis in rats exposed to hypoxia-hypercapnia and explore the therapeutic potential of curcumin in hypoxia-hypercapnia brain damage (HHBD). Sprague Dawley rats were randomly assigned into 3 groups: control group, hypoxia-hypercapnia group and curcumin group. The Fas/FasL expressions in HHBD rats treated by curcumin were measured by immunohistochemical staining and western blotting. The pathological changes of brain cells were observed by transmission electron microscope. Rats with HHBD showed significant increase of Fas/FasL expression and ultrastructural changes in brain tissue cells. Curcumin intervention effectively reversed the Fas/FasL-mediated apoptosis and HHBD-induced brain edema. Curcumin may be a potential therapeutic alternative for HHBD.
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PMID:Curcumin inhibits apoptosis and brain edema induced by hypoxia-hypercapnia brain damage in rat models. 2586 53

The present study aimed to investigate the therapeutic effects of curcumin (CU) against brain edema in a rat model of hypoxia-hypercapnia (HH)-induced brain damage (HHBD). Male Sprague-Dawley rats were divided into five groups, including a control group and four treatment groups. The rats in the control group were raised under normal laboratory conditions and were injected with water, whereas the rats in the treatment groups were exposed to a low O2/high CO2 environment simulating HH conditions, and were injected with water, CU, dimethyl sulfoxide (solvent control) or monosialoganglioside GM1. After 2 weeks, the morphological characteristics of the brain tissues were analyzed using optical and electron microscopy. In addition, aquaporin (AQP)-4 protein expression levels in brain tissue samples were analyzed using streptavidin-biotin complex immunohistochemistry and western blotting, and mRNA expression levels were detected using reverse transcription-quantitative polymerase chain reaction. Severe brain edema, tissue structure disruption and increased AQP4 expression levels were detected in the brain tissues of the HH rats. Conversely, the rats treated with CU or GM1 exhibited attenuated HHBD-induced brain edema and tissue structure disruption, and decreased mRNA and protein expression levels of AQP4. The results of the present study suggested that CU treatment was able to attenuate HHBD-induced brain edema by downregulating the expression levels of AQP4 in a rat model. Therefore, CU may be considered a potential therapeutic drug for the treatment of patients with brain edema.
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PMID:Curcumin alleviates brain edema by lowering AQP4 expression levels in a rat model of hypoxia-hypercapnia-induced brain damage. 2699 83

Therapeutic hypercapnia has the potential for neuroprotection after global cerebral ischemia. Here we further investigated the effects of different degrees of acute systemic hypoxia in combination with hypercapnia on brain damage in a rat model of hypoxia and ischemia. Adult wistar rats underwent unilateral common carotid artery (CCA) ligation for 60 min followed by ventilation with normoxic or systemic hypoxic gas containing 11%O2,13%O2,15%O2 and 18%O2 (targeted to PaO2 30-39 mmHg, 40-49 mmHg, 50-59 mmHg, and 60-69 mmHg, respectively) or systemic hypoxic gas containing 8% carbon dioxide (targeted to PaCO2 60-80 mmHg) for 180 min. The mean artery pressure (MAP), blood gas, and cerebral blood flow (CBF) were evaluated. The cortical vascular permeability and brain edema were examined. The ipsilateral cortex damage and the percentage of hippocampal apoptotic neurons were evaluated by Nissl staining and terminal deoxynucleotidyl transferase-mediated 2'-deoxyuridine 5'-triphosphate-biotin nick end labeling (TUNEL) assay as well as flow cytometry, respectively. Immunofluorescence and western blotting were performed to determine aquaporin-4 (AQP4) expression. In rats treated with severe hypoxia (PaO2 < 50 mmHg), hypercapnia augmented the decline of MAP with cortical CBF and damaged blood-brain barrier permeability (p < 0.05). In contrast, in rats treated with mild to moderate hypoxia (PaO2 > 50 mmHg), hypercapnia protected against these pathophysiological changes. Moreover, hypercapnia treatment significantly reduced brain damage in the ischemic ipsilateral cortex and decreased the percentage of apoptotic neurons in the hippocampus after the CCA ligated rats were exposed to mild or moderate hypoxemia (PaO2 > 50 mmHg); especially under mild hypoxemia (PaO2 > 60 mmHg), hypercapnia significantly attenuated the expression of AQP4 protein with brain edema (p < 0.05). Hypercapnia exerts beneficial effects under mild to moderate hypoxemia and augments detrimental effects under severe hypoxemia on brain damage in a rat model of hypoxia-ischemia.
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PMID:Effects of Acute Systemic Hypoxia and Hypercapnia on Brain Damage in a Rat Model of Hypoxia-Ischemia. 2790 83