ABSTRACT
We report the case of a patient with schizophrenia, who experienced agranulocytosis during clozapine treatment, followed by bronchopulmonal infection and Guillain-Barré syndrome. The case was recorded within the German surveillance project "drug safety in psychiatry" (AMSP).
Subject(s)
Agranulocytosis/chemically induced , Agranulocytosis/complications , Antipsychotic Agents/adverse effects , Clozapine/adverse effects , Guillain-Barre Syndrome/etiology , Sepsis/complications , Sepsis/etiology , Antipsychotic Agents/therapeutic use , Clozapine/therapeutic use , Female , Humans , Middle Aged , Psychomotor Agitation/complications , Respiratory Tract Infections/complications , Respiratory Tract Infections/etiology , Schizophrenia/complications , Schizophrenia/drug therapySubject(s)
Brain/anatomy & histology , Computer-Assisted Instruction , Information Systems , Software , Anatomy, Artistic , Brain/physiology , Brain Diseases/diagnosis , Brain Mapping , Computer Graphics , Diagnosis, Computer-Assisted , Evoked Potentials , Humans , Medical Illustration , Neurology/education , Radiology/education , User-Computer InterfaceABSTRACT
We evaluated the effects of breathing 35% stable xenon in 65% oxygen on regional cerebral blood flow and the electroencephalogram in 20 normal volunteers. We measured blood flow in 32 brain regions over both hemispheres with the xenon-133 intravenous injection technique in two protocols. In the first protocol (n = 10), a baseline study was followed by a second study during 5 minutes of breathing stable xenon; in the other protocol (n = 8), the baseline study was followed by a second study after 5 minutes of breathing stable xenon. Two volunteers were excluded due to excessive movements during the inhalation of stable xenon. Some of the remaining 18 volunteers had varying alterations of consciousness accompanied by electroencephalogram changes. After stable xenon inhalation the electroencephalogram returned to normal within 2-3 minutes. During stable xenon inhalation mean +/- SD PECO2 dropped significantly from 39.4 +/- 4.4 to 33.3 +/- 5.4 mm Hg in the first protocol and from 39.4 +/- 2.6 to 34.8 +/- 4.1 mm Hg in the second protocol due to hyperventilation in 13 volunteers. Mean regional cerebral blood flow increased significantly by 13.5-25.4% without correction for PECO2. In the first protocol regional cerebral blood flow increased by greater than 12% in 11-14 (depending on the flow parameter) of the 20 hemispheres. In the second protocol regional cerebral blood flow increased by greater than 12% in 9-13 of the 16 hemispheres. We conclude that cautious interpretation is necessary in the assessment of regional cerebral blood flow with 35% xenon-enhanced computed tomography.
Subject(s)
Brain/drug effects , Cerebrovascular Circulation/drug effects , Electroencephalography , Xenon/pharmacology , Adult , Analysis of Variance , Brain/physiology , Carbon Dioxide , Female , Humans , Hyperventilation/chemically induced , Hyperventilation/physiopathology , Male , Partial Pressure , Reference Values , Respiration , Xenon/adverse effectsABSTRACT
Cerebral blood flow (CBF) and cerebral plasma volume (CPV) were measured under steady-state hyperglycemic conditions in the hemispheres and brainstem-cerebellum of conscious rats. There groups of hyperglycemic animals each having a different level of plasma glucose concentration, 25, 33.3, 44.4 mmol/l, and a normoglycemic control group were studied. CBF was not affected at the hyperglycemic levels of 25 and 33.3 mmol/l. Mean hemispheric and brainstem-cerebellum CBF values appeared lower than in controls at the highest glycemic level although the differences were not statistically significant. CPV was found to be unchanged at the hyperglycemic level of 25 mmol/l, while it was found to be increased in the hemispheres of the animals whose plasma glucose concentration had been elevated to 33.3 and 44.4 mmol/l. The results of the study do not support the claim that hyperglycemia may enhance ischemic brain injury by reducing CBF.
Subject(s)
Cerebrovascular Circulation/physiology , Hyperglycemia/physiopathology , Plasma Volume/physiology , Animals , Blood Glucose/analysis , Rats , Rats, Inbred StrainsABSTRACT
A comparison of local cerebral blood flow estimates with the microsphere and the 4-[N-methyl-14C]iodoantipyrine ([14C]IAP) techniques has been performed in cats. Good correlation of [14C]IAP with microsphere flow estimates in the gray matter was found. In the white matter, however, [14C]IAP flow estimates were consistently lower than microsphere flow estimates. Error analysis of both techniques and comparison with previous studies suggest that peculiarities of white matter arterial vasculature with preferential microsphere accumulation may lead to this discrepancy. Microspheres did not interfere with flow as shown by the normal appearance of subsequent [14C]IAP autoradiograms. The number of microspheres seen on autoradiograms was used for an estimate of microvessels blocked by spheres and found to be negligible. The study also demonstrates that [14C]IAP is not diffusion limited up to the observed flow values of 2 ml.g-1.min-1. Both techniques might be used together for a combination of their respective advantages, which are temporal and spatial resolution for microsphere and [14C]IAP, respectively.
Subject(s)
Antipyrine/analogs & derivatives , Cerebrovascular Circulation/drug effects , Animals , Antipyrine/pharmacology , Autoradiography , Cats , Mathematics , Microcirculation , Microspheres , Quaternary Ammonium Compounds , Regional Blood FlowABSTRACT
A method was developed to measure simultaneously the rate constants for glucose influx and glucose efflux, and the Michaelis-Menten constant (KM) and maximal velocity (Vmax) for glucose transport across the blood-brain barrier (BBB) in any selected brain area. Moreover, on the basis of a mathematical model, the local perfusion rate (LPR) and local unidirectional glucose transport rate (LUGTR) are calculated in terms of parameters of the time-activity curves registered over different brain regions; 11C-methyl-D-glucose (CMG) is used as an indicator. The transaxial distribution of activity in the organism is registered using dynamic positron-emission tomography (dPET). The method was used in 4 normal subjects and 50 patients with ischemic brain disease. In normals, the rate constant for CMG efflux was found to be 0.25 +/- 0.04 min-1 in the cortex and 0.12 +/- 0.02 min-1 in white matter. In the cortex, the KM was found to be 6.42 mumol/g and the Vmax was 2.46 mumol/g per minute. The LUGTR ranged from 0.43 to 0.6 mumol/g per minute in the cortex, and from 0.09 to 0.12 mumol/g per minute in white matter. The LPR was calculated to be 0.80-0.98 ml/g per minute for the cortex and 0.2-0.4 ml/g per minute for white matter. In patients with stroke, the ischemic defects appeared to be larger in CMG scans than in computed x-ray tomography (CT) scans. Prolonged reversible ischemic neurological deficit was associated with a significant fall in the LUGTR but no change in the LPR in the corresponding cerebral cortex. Normal LUGTR and significantly decreased LPR were registered in a patient with progressive occlusion of the middle cerebral artery. In a patient with transient ischemic attacks, a slightly reduced LPR and a disproportionally reduced LUGTR were observed before operation. After extra- and intracranial bypass surgery, the LPR became normal, whereas the LUGTR increased but did not achieve normal values.
Subject(s)
Brain/metabolism , Glucose/metabolism , Methylglucosides , Methylglycosides , Tomography, Emission-Computed , 3-O-Methylglucose , Biological Transport , Blood-Brain Barrier , Brain Ischemia/metabolism , Carbon Radioisotopes , Cerebral Cortex/metabolism , Humans , Kinetics , Methylglucosides/metabolismABSTRACT
In cats, the early development of ischemic brain edema was studied 1 to 4 hours after transorbital occlusion of the left middle cerebral artery (MCA). Two groups of animals were compared: those in which blood flow in the territory of the MCA decreased below the threshold of 10--15 ml/100 g/min (critical ischemia) and those in which it remained above this level (non-critical ischemia). In animals with critical ischemia, water content in the cortex of the MCA territory increased from 80.7 +/- 0.4 to 83.0 +/- 0.3 vol. % (means +/- SE) within 4 h. Edema was associated with an increase in tissue osmolality by 16--22 mosm/kg w.w., and a rise of sodium from 262 +/- 9 to 454 +/- 13 meq/kg d.w. and a decrease of potassium from 442 +/- 20 to 305 +/- 32 meq/kg d.w. The sodium/potassium ratio rose from 0.60 +/- 0.03 to 1.55 +/- 0.17. The water and electrolyte disturbances were accompanied by a major shift of extracellular fluid into the intracellular compartment, as evidenced by the increase in cortical impedance from 282 to 660 ohm/cm within 2 h. According to the Maxwell equation, this reflects a narrowing of the extracellular space from 19.8 to 11.4%. Brain volume was continuously monitored using an induction transducer; swelling began within a few minutes of vascular occlusion, and it continued throughout the 4 h observation period. During this time the blood-brain barrier remained intact as evidenced by the absence of Evans blue staining. Edema was associated with disturbances of the energy producing metabolism, but there was no strict correlation with either lactate or the concentration of high energy phosphates. In animals without critical ischemia, i.e. in which blood flow remained above 10--15 ml/100 g/min, edema was absent despite a distinct deterioration of the energy state of the brain. Edema was also absent in the border zone, in the territory of the posterior cerebral artery and in the contralateral hemisphere of animals with both critical and non-critical ischemia. It is concluded that the early ischemic brain edema following middle cerebral artery occlusion is of the cytotoxic type, that it develops at a flow rate below 10--15 ml/100 g/min, and that it is not strictly correlated with the energy state of the brain.
Subject(s)
Brain Edema/etiology , Brain Ischemia/physiopathology , Animals , Blood-Brain Barrier , Body Water/metabolism , Cats , Cerebrovascular Circulation , Extracellular Space/physiology , Hypernatremia/physiopathology , Hypokalemia/physiopathology , Osmolar ConcentrationABSTRACT
In 48 cases the left middle cerebral artery was occluded under light barbiturate anaesthesia using a transorbital approach. The animals were kept alive for 1, 2, and 4 hours after vascular occlusion. Regional cerebral blood flow was measured by the intracardiac microsphere injection technique before ischemia, 15 min after the onset of ischemia, and at the end of experiments. The density of regional ischemia was correlated with EEG changes and with the electrolyte, water and metabolite content of the same tissue samples in which blood flow was assessed. In the territory of the occluded middle cerebral artery, cortical blood flow decreased from 41.4 +/- 3.8 to 21.3 +/- 4.0 ml/100 g/min (means +/- SE), the actual flow rate depending on the individual efficacy of collateral blood supply. At flow rates below 10--15 ml/100 g/min, ischemia involved more than 50% of the middle cerebral artery territory, water and electrolyte homeostasis was severely disturbed and ischemic brain edema developed. Adenosine triphosphate decreased to about 60% of the control value at flow rates below 40 ml/100 g/min, but it remained at this level down to flow rates as low as 5 ml/100 g/min. EEG intensity -- but not EEG frequency -- decreased in parallel with blood flow, indicating that with increasing density of ischemia an increasing portion of the excitable neuropil was inhibited. The development of ischemic brain edema determined the further progression of ischemia. When blood flow decreased below the threshold for water and ion disturbance, ischemia was progressive (critical ischemia), but an amelioration of flow occurred in animals in which flow remained above this level (non-critical ischemia). In the contralateral hemisphere the EEG, blood flow, water and electrolyte content did not change significantly during the initial few hours of ischemia. Diaschisis, in consequence, was not a prominent feature during the early phase of infarct development.
Subject(s)
Brain Ischemia/physiopathology , Brain , Cerebral Infarction/physiopathology , Adenosine Triphosphate/metabolism , Animals , Brain/blood supply , Brain Edema , Cats , Cerebrovascular Circulation , Collateral Circulation , Hyperkalemia/physiopathology , Hypernatremia/physiopathology , Phosphocreatine/metabolism , Regional Blood FlowABSTRACT
Moderate unilateral cerebral ischemia was produced by microembolism in 24 adult cats. Two million plastic microspheres with a diameter of 15 +/- 5 microns were injected into the left common carotid artery via the lingual artery. The physiological and metabolic responses to embolism were accessed by electrocorticography and by determining the cerebral energy state. Embolism caused an immediate slowing and voltage reduction of the ipsilateral electrocorticogram with a gradual recovery after 30 to 60 min. Some animals also had an immediate and short depression of the contralateral electrocorticogram. In spite of the market functional suppression, metabolites of the cerebral energy-producing metabolism in most of the animals changed only slightly. In the embolized hemisphere pyruvate increased from 0.06 to 0.10 mumol/g and lactate from 1.9 to 4.6 mumol/g within 5 min after embolization and remained at this level during the 4 h observation period. Phosphocreatine, adenosine triphosphate and the energy charge of the adenylate pool remained uncharged during this period. However, there was a slight increase of ATP in the non-embolized hemisphere during the early postembolic period. In two animals, the initial slowing of the electrocorticogram recurred and spread to the contralateral hemisphere, followed by bilateral flattening after a few hours. This delayed functional deterioration was accomplished by complete loss of energy-rich phosphates. These animals also had a progressive increase of cerebrospinal fluid (CSF) pressure and considerable brain swelling with cerebellar herniation after 4 h. It is concluded that unilateral cerebral embolism in the above concentration leads only to a slight increase of anerobic glycolysis without significant perturbation of the cerebral energy state, unless progressive brain swelling with cerebrellat herniation supervenes. This supports previous findings, that brain edema and not initial ischemia is the main pathogenetic factor for tissue damage in cerebral microembolism.
Subject(s)
Brain Ischemia/metabolism , Brain/metabolism , Energy Metabolism , Animals , Brain Ischemia/etiology , Brain Ischemia/physiopathology , Cats , Female , Intracranial Embolism and Thrombosis/complications , Intracranial Embolism and Thrombosis/physiopathology , MaleABSTRACT
Alteration of the metabolism of calcium and phosphate may be associated with symmetric cerebral calcification. Detailed investigations of the function of parathyroid glands including computer tomography of the brain are so far missing. In 6 patients with clinical and biochemical signs of altered function of the parathyroid glands symmetric cerebral calcification could be demonstrated by computer tomography. They are also visible by X-ray examination in one patient. Consequently, functional disturbances of the brain, cerebellum and of the extrapyramidal system may occur. Moreover, the combination of hypoparathyroidism and hypothyroidism also appears to result in the development of symmetric cerebral calcification. The pathogenesis of the calcification as well as therapeutic approaches will be discussed.
Subject(s)
Calcinosis/etiology , Parathyroid Diseases/metabolism , Adult , Calcium/metabolism , Dihydrotachysterol/therapeutic use , Female , Humans , Magnesium/metabolism , Male , Middle Aged , Parathyroid Hormone/metabolism , Phosphorus/metabolism , Thyroid Diseases/drug therapy , Thyroxine/therapeutic use , Tomography, X-Ray Computed , Vitamin D/therapeutic useABSTRACT
Cats underwent massive microembolization via carotid infusion of 10.5 million microspheres (15 +/- 5 mu in diameter), resulting in brain death within four hours; 87.4 +/- 10.2% of emboli reaching the brain were in the ipsilateral hemisphere; 87.9 +/- 4.4% were in the grey matter; and 12.1 +/- 4.4% were in the white matter. Evans blue and sodium fluorescein dyes were given intravascularly before and at different times after embolization. Fluorescence microscopy disclosed that embolization initially provoked a hyperemic engorgement of both the embolized and nonembolized hemispheres. Multifocal, blood-brain barrier extravasations occurred throughout the ipsilateral cortex and oral basal ganglia. Severe vasogenic brain edema ensued, with migration of extravasations from cortex into the white matter, which initially showed only minimal injury. Migration and accumulation of edema in white matter, with subsequent uptake and swelling of neuroglia and axons, may be related to secondary white matter damage following cortical embolic lesions. Degenerative foci developed throughout the embolized cortex over the one- to four-hour period of this study. These sites may correspond to those areas in which hyperemia and damage to the blood-brain barrier was present shortly after embolization.
