The influence of caloric nystagmus on flash evoked transient and steady-state potentials.

OBJECTIVE: Caloric stimulation leads to a reduction of the cerebral blood flow in the visual cortex. This reduction has been attributed to the suppression of visual input caused by nystagmus induced by caloric stimulation. We investigated the influence of caloric stimulation on transient flash and steady-state flash visual evoked potentials. METHODS: Visual evoked potentials to 1 and 10 Hz flash stimulation were recorded in 12 normal subjects at baseline, during nystagmus induced by caloric stimulation with cold water, and after the cessation of nystagmus. RESULTS: Neither the amplitude of the transient flash visual evoked potentials (1 Hz stimulation) nor the amplitude of the steady-state flash visual evoked potentials (10 Hz stimulation) was influenced by caloric stimulation compared to baseline. CONCLUSIONS: The deactivation of the visual cortex by caloric stimulation does not seem to affect transient flash or steady-state flash visual evoked potentials. Reduction of cerebral blood flow in the visual cortex does not affect the processing of visual qualities (e.g., luminance and pattern). SIGNIFICANCE: Caloric stimulation does not reduce the amplitudes of transient flash or steady-state flash visual evoked potentials.     

Acetaminophen toxicity up-regulates MRP2 expression in the liver of cats: an old story with new vision

This study was conducted to clarify the role of efflux transporter MRP₂ in acetaminophen-induced hepatotoxicity in cats. Sixteen mixed bred male cats and four liver samples from mixed breed male dogs were used. The cats were assigned into four groups (n?=?4), received saline and 2, 10 and 50?mg/kg doses of acetaminophen orally for 14 days. Unlike the intact dogs, the MRP₂ was not detectable in control cats. MRP₂ at mRNA level was expressed in the liver of cats, which received the medium and high doses. Data suggest that the MRP₂ expression may involve in the acetaminophen-induced hepatotoxicity in cats.     

Hemorrhagic shock induces an S 100 B increase associated with shock severity

S 100 B is a glial marker of cerebral Injury. In a previous clinical study, we found an S 100 B increase within the first 24 h in patients with multiple trauma and hemorrhagic shock but without cerebral trauma. The aim of our current experimental study was to determine whether this posttraumatic S 100 B increase is caused by extracerebral soft tissue injury or by hemorrhagic shock and whether it is associated with the severity of hemorrhagic shock. Hemorrhagic shock was achieved by bleeding anesthetized rats to a mean arterial pressure (MAP) of 30-35 mmHg through a femoral catheter and maintaining this MAP until incipient decompensation. At incipient decompensation, MAP was either increased immediately to 40-45 mmHg (moderate shock) or was maintained until 40% of shed blood had been returned (severe shock), and then increased to 40-45 mmHg. Resuscitation was provided after 40-45 mmHg MAP had been maintained for 40 min. Soft tissue injury was achieved by midline laparotomy performed at the onset of hemorrhagic shock or without shock and was maintained for 30 min. Hemorrhagic shock caused an early S 100 B increase at the onset of decompensation. S 100 B remained increased for 24 h and was significantly higher after severe than after moderate shock. In contrast, soft tissue injury without hemorrhagic shock caused no S 100 B increase. The data presented demonstrate for the first time that the S 100 B increase is induced by hemorrhagic shock and is associated with the severity of shock.     

Die juvenile myoklonische Epilepsie wird häufig inadäquat behandelt

Zusammenfassung Die juvenile myoklonische Epilepsie (JME) ist ein h?ufiges, durch generalisierte myoklonische Anf?lle gut definiertes Epilepsie-Syndrom. Trotz der typischen Symptome und EEG-Ver?nderungen wird die juvenile myoklonische Epilepsie zu selten diagnostiziert und infolgedessen h?ufig mit inad?quaten Antiepileptika (AE), Natriumkanal-Blockern wie Carbamazepin, Oxcarbazepin und Phenytoin behandelt. Wir haben retrospektiv die Behandlung von 175 JME-Patienten unserer Epilepsieambulanz analysiert. Bei Erstvorstellung in unserer Spezialambulanz wurden 24% (42 von 175) der Patienten mit Natriumkanal-blockierenden AE behandelt, worunter nur ein Patient anfallsfrei war. Nach Umstellung auf zumeist Valproat und Lamotrigin wurden 42% dieser Patienten anfallsfrei. Diese Zahlen betonen die Wichtigkeit der Syndrom-Diagnose und einer ad?quaten AE-Wahl in der Behandlung der JME.      

Hemorrhage- and resuscitation-related alterations in gastrointestinal circulation: effect of a low dose of L-NMMA

The gastrointestinal tract, including its mucosal barrier, is most sensitive to ischemic insults. The present study was conducted to evaluate hemorrhage- and resuscitation-related regional alterations in gastrointestinal circulation in presence or absence of a low dose of N(G)-monomethyl-L-arginine (L-NMMA), a nonspecific nitric oxide synthase inhibitor. Organ-specific circulation was studied using the colored microsphere technique in rats subjected to prolonged hemorrhagic shock (180 min) followed by resuscitation with or without L-NMMA (2 mg/kg body weight) treatment at the end of resuscitation. We found an initial distal gradient in the intestinal blood flow with the highest rate in duodenum followed by jejunum, ileum, and colon. Hemorrhage resulted in the highest decrease in gastric blood flow. Resuscitation restored circulation in the intestinal tract to baseline levels except for gastric blood flow. L-NMMA treatment after completion of resuscitation did not deteriorate gastrointestinal blood flow. Our data show (a) a distal gradient in the intestinal blood flow from duodenum to colon, (b) that hemorrhage and resuscitation cause different degrees of alteration in gastric and intestinal blood flow, (c) that gastric perfusion does not recover after resuscitation, predisposing to further organ damage, and (d) that a low dose of L-NMMA does not deteriorate intestinal circulation in rats subjected to hemorrhage and resuscitation.     

Neuron-specific-enolase is increased in plasma after hemorrhagic shock and after bilateral femur fracture without traumatic brain injury in the rat

Neuron-specific enolase (NSE) is an acknowledged marker of traumatic brain injury. Several markers originally considered reliable in the setting of traumatic brain injury have been challenged after having been studied more extensively. The aim of our experimental study was to determine whether NSE is a reliable marker of traumatic brain injury early after trauma. Hemorrhagic shock was achieved by bleeding anesthetized rats to a mean arterial pressure (MAP) of 30-35 mmHg through a femoral catheter until incipient decompensation. MAP was maintained at 30-35 mmHg until 40% of shed blood had been administered as Ringer's solution and was then increased and maintained at 40-45 mmHg for 40 min by further administration of Ringer's solution, mimicking the phase of inadequate preclinical resuscitation. Blood samples were drawn at the end of the 40-min period of inadequate resuscitation. Femur fracture was achieved in anesthetized rats by bilateral application of forceps. Blood samples were drawn 30 and 60 min after fracture. Hemorrhagic shock caused NSE increase versus laboratory controls at the end of inadequate resuscitation (P < 0.01). Bilateral femur fracture caused NSE increase versus laboratory controls 30 min after fracture, which was significant 60 min after fracture (P < 0.01). During femur fracture, MAP remained at a level that is not associated with shock in rats. Our findings show for the first time that NSE increases after hemorrhagic shock as well as after femur fracture without hemorrhagic shock in rats. From a clinical point of view, these findings indicate that NSE cannot be considered a reliable marker of traumatic brain injury early after trauma in cases associated with hemorrhagic shock and/or femur fracture.     

Nitric oxide synthase inhibitors affect nitric oxide synthesis in normoxic but not in ischemic organs during intestinal ischemia and early reperfusion

Inhibition of endogenous nitric oxide (NO) synthesis during early intestinal ischemia/reperfusion (I/R(i)) enhances remote organ damage related to I/R(i). However, the effects of NO synthase (NOS) inhibitors on NO formation in various organs have not yet been specified. We therefore investigated the effects of N-G-monomethyl-L-arginine (L-NMMA), a nonspecific NOS inhibitor, and L-arginine, the NOS substrate, on NO formed in ischemic intestine versus normoxic remote organs (lung and liver). We used electron paramagnetic resonance spectroscopy and a specific NO trap to assay NO in blood, intestine, lung, and liver of rats subjected to local I/R(i), with and without L-NMMA and L-arginine supplementation. We found that I/R(i) increased NO levels in the intestine and blood, but not in the remote organs lung and liver. Administration of L-NMMA before I/R(i) decreased I/R(i)-independent basal NO levels in normoxic lung and liver without influencing I/R(i)-induced increase in NO levels in intestinal tissue or in blood. L-arginine supplementation increased circulating levels of NO, with sensitivity to L-NMMA, without affecting NO levels in normoxic or ischemic tissue. Our data suggest that NOS activity controls the NO generated in normally perfused remote organs during early I/R(i). Hence NOS inhibitors, when administered during I/R(i), decrease physiological NO levels in normoxic remote organs without affecting increased NO levels originating from ischemic intestine. This may explain the harmful effect of nonspecific NOS inhibitors during early I/R(i). In addition, the generation of NO in remote organs is not limited by tissue L-arginine concentrations and, therefore, not influenced by exogenous L-arginine. The protective effect of L-arginine supplementation during I/R(i) is probably related to increasing intravascular NO formation.     

Right temporal cerebral dysfunction heralds symptoms of acute mountain sickness

Acute mountain sickness (AMS) can occur during climbs to high altitudes and may seriously disturb the behavioral and intellectual capacities of susceptible subjects. During a Himalayan expedition 32 mountaineers were examined with electroencephalography (EEG) and transcranial doppler sonography (TCD) to assess relative changes of middle cerebral artery velocity in relation to end-expiratory CO2 (EtCO2), peripheral saturation (SaO2), and symptoms of AMS. We tested the hypothesis that O2 desaturation and EtCO2 changes precede the development of AMS and result in brain dysfunction and compensatory mechanisms which can be measured by EEG and TCD, respectively. Contrary to our hypothesis, we found that subjects who later developed symptoms of AMS between 3,440 m and 5,050 m altitude exhibited an increase of slow cerebral activity in the right temporal region already at 3,440 m. Cerebral blood flow increased in these mountaineers in the right middle cerebral artery at 5,050 m. These findings indicate that regional brain dysfunction, which can be documented by EEG, heralds the appearance of clinical symptoms of AMS. Each author will disclose any financial involvement or otherwise support that may potentially bias his/her work. Received in revised form: 5 April 2006