Brain Site (brain + site)

Distribution by Scientific Domains
Life Sciences75%

Selected Abstracts

VIQ-PIQ Discrepancies in Partial Epilepsy: On the Relation to Lat- eralities of Focal MRI Lesions, P3 Peaks, and Focal Spikes.

EPILEPSIA, Issue 2000
Osamu Kanazawa
Purpose: A number of previous ncurophysiological studies have indicated that the glutamatergic system is important in the induction of epileptiform activity and the dcvelopment of epileptogenesis. Clutamate transport is the primary mechanism of inactivation of syiiaptically released glutamate. GLAST is classified BS an astrocytic transporter and occurs in high concentrations in the ccrebcllum. The pathophysiologic rolc of GLAST in epilepsy is not known in detail. To investigate the role of thc astroglial glutamatc transporter GLAST in epileptogenesis, we compared amygdalu-kindling and pentylenctetrazolc (PTZ) induced seizures in GLAST-deficient mice (GLAST(-/-)) wild-type mice (GLAST(+/+)), and maternal C57Black6/J mice (C57). Purpose: Subtest IQ such as verbal IQ (VIQ) and performance IQ (PIQ) in WAIS or WISC are thought to represent neuropsychological functions of the left and right hemispheres, respectively. The P300 (P3) event-related potential reflects cognitive processes. We do not ye1 know the brain site of P3 origin or how epileptogenic foci (EF) influ- ence P3 potentials. To examine neuropsychological influence by partial epilepsy (PE), we studied VIQ-PIQ discrepancies in PE in relation to lateralities of focal MRI lesions, P3 peaks, and EF. Methods: Thirteen patients showed VIQ-PIQ discrepancies significant at the p7lt;O.O5 level, represented by a>l2-point spread for the WAIS in adults, and a 15-point spread in the WISC in children. We evoked P3 potentials in the individuals with discrepant IQ differences by asking them to keep a mental count of rare tones, including introduction of oddbail tones. EEGs were recorded by the international 10,20 system and P3 peaks were shown in a topographical view by offline analysis. Patients were divided into normal and abnormal groups according to MRI findings, and were examined for the laterali- ties of the dominant side in subtest IQ (conventionally, we regarded higher VIQ as left hemisphere dominant and higher PIQ as right hemisphere dominant), P3 peaks, and EF. We did not correlate results with lert or right handedness. Results: Five patients (38.5%) were in the normal group and 8 patients (61.5%) were in the abnormal group. Concordance of the lateralities in P3 peaks and dominant side in subtest IQ was shown in 1 patient (20%) in the normal group and 5 patients (62.5%) in the abnormal group. In the normal group, all patients showed contralateral P3 peak shift to EF, and all except I patient showed contralateral P3 peak shift to the dominant side in subtest IQ. The other 3 patients in the abnormal group showed unilateral focal cortical dysplasias (FCD), ipsilateral P3 shift, and contralateral dominant side in subtest IQ to the focal MRI lesions. Conclusion: In our partial epilepsy series with VIQ-PIQ discrepancies, concordance of the lateralities in P3 peaks and dominant side in subtest IQ was shown in < half of the patients. Epileptogenic foci seem to have 3 different grades of influence on P3 peak shift and dominant side in subtest IQ according to the severities of accompanying focal MRI lesions: 1. Without MRI lesions, EF can make P3 peak shift contralaterally, but the dominant side in the subtest IQ shift ipsilaterally; 2. With less severe focal MRI lesions such as hippocampal atrophy etc., EF can make not only P3 peaks but also the dominant side in the subtest IQ shift contralaterally; 3. With severe focal MRI lesions such as FCD, EF can make the dominant side in the subtest IQ shift contralaterally, but the P3 peak may shift ipsilaterally. Epileptogenic foci without MRI lesions seem to control ipsilateral P3 potentials. MRI lesions render a hemisphere unlikely to become dominant, but epileptogenic foci can coexist with apparently normal neuropsychological function. [source]

Effects of caudal hindbrain lactate infusion on insulin-induced hypoglycemia and neuronal substrate transporter glucokinase and sulfonylurea receptor-1 gene expression in the ovariectomized female rat dorsal vagal complex: Impact of estradiol

JOURNAL OF NEUROSCIENCE RESEARCH, Issue 3 2008
Kamlesh V. Vavaiya
Abstract The monocarboxylate, lactate, is produced by astrocytic glycolysis and is trafficked to neurons as a substrate fuel for aerobic respiration. This molecule is a critical monitored metabolic variable in hindbrain detection of cellular energy imbalance, because diminished uptake and/or oxidative catabolism of lactate in this part of the brain activates neural mechanisms that increase systemic glucose availability. Lactate-sensitive chemosensory neurons occur in the hindbrain dorsal vagal complex (DVC). Estradiol (E) enhances expression of the neuronal monocarboxylate transporter MCT2 in the DVC during insulin-induced hypoglycemia (IIH), evidence that this hormone may promote local lactate utilization during systemic glucose shortages. We investigated the hypothesis that E regulates basal and IIH-associated patterns of DVC MCT2 and neuronal glucose transporter gene expression and that caudal fourth ventricular (CV4) lactate infusion exerts divergent effects on blood glucose levels and DVC energy transducer gene profiles in hypoglycemic E- vs. oil (O)-implanted ovariectomized (OVX) rats. Insulin-induced decrements in circulating glucose were significantly augmented by lactate, albeit to a greater extent in the presence of E. DVC MCT2, GLUT3, GLUT4, glucokinase (GCK), and sulfonylurea receptor-1 (SUR1) mRNA levels did not differ between saline-injected OVX + E and OVX + O rats. IIH elevated MCT2 and GLUT3 gene profiles in both E- and O-implanted groups, but up-regulation of MCT2 transcripts was reversed by CV4 lactate infusion during hypoglycemia in E- but not O-implanted animals. DVC GLUT4 and GK mRNA were decreased by insulin alone in OVX + O but not OVX + E, but were suppressed by lactate plus insulin treatment in the latter group. Expression of the SUR1 subunit of the energy-dependent potassium channel KATP was significantly decreased by IIH in both E- and O-treated rats and further suppressed in response to lactate delivery during hypoglycemia in OVX + E. These data reveal that E does not control baseline DVC substrate fuel transporter or energy transducer gene profiles or local MCT2, GLUT3, or SUR1 transcriptional responses to IIH but prevents IIH-associated decreases in GLUT4 and GCK mRNA in this brain site. The results also show that, in the presence of E, intensifying effects of CV4 lactate infusion on hypoglycemia are correlated with reversal of IIH enhancement of DVC MCT2 gene expression, augmented IIH inhibition of SUR1 transcripts, and reductions in GLUT4 and GCK mRNA levels relative to baseline. This work implies that IIH may enhance specific neuronal lactate and glucose transport mechanisms in the female rat DVC and that, in the presence of E, caudal hindbrain lactate repletion may normalize neuronal lactate but not glucose internalization by local neurons. The results also suggest that putative IIH-associated reductions in KATP -mediated regulation of membrane voltage in this brain site may be causally related to diminished glucose availability. © 2007 Wiley-Liss, Inc. [source]

Orexin receptor subtype activation and locomotor behaviour in the rat

ACTA PHYSIOLOGICA, Issue 3 2010
W. K. Samson
Abstract Aim:, Orexin-producing neurones, located primarily in the perifornical region of the lateral hypothalamus, project to a wide spectrum of brain sites where they influence numerous behaviours as well as modulating the neuroendocrine and autonomic responses to stress. While some of the actions of orexin appear to be mediated via the type 1 receptor, some are not, including its action on the release of one stress hormone, prolactin. We describe here the ability of orexin to increase locomotor behaviours and identify the importance of both receptor subtypes in these actions. Methods:, Rats were tested for their behavioural responses to the central activation of both the type 1 (OX1R) and type 2 (OX2R) receptor (ICV orexin A), compared to OX2R activation using a relatively selective OX2R agonist in the absence or presence of an orexin receptor antagonist that possesses highest affinity for OX1R. Results:, Increases in locomotor activity were observed, effects which were expressed by not only orexin A, which binds to both the OX1R and the OX2R receptors, but also by the relatively selective OX2R agonist [(Ala11, Leu15)-orexin B]. Furthermore, the OX1R selective antagonist only partially blocked the action of orexin A on most locomotor behaviours and did not block the actions of [(Ala11, Leu15)-orexin B]. Conclusion:, We conclude that orexin A exerts its effects on locomotor behaviour via both the OX1R and OX2R and that agonism or antagonism of only one of these receptors for therapeutic purposes (i.e. sleep disorders) would not provide selectivity in terms of associated behavioural side effects. [source]

Analysis and use of FMRI response delays

HUMAN BRAIN MAPPING, Issue 2 2001
Ziad S. Saad
Abstract In this study, we implemented a new method for measuring the temporal delay of functional magnetic resonance imaging (fMRI) responses and then estimated the statistical distribution of response delays evoked by visual stimuli (checkered annuli) within and across voxels in human visual cortex. We assessed delay variability among different cortical sites and between parenchyma and blood vessels. Overall, 81% of all responsive voxels showed activation in phase with the stimulus while the remaining voxels showed antiphase, suppressive responses. Mean delays for activated and suppressed voxels were not significantly different (P < 0.001). Cortical flat maps showed that the pattern of activated and suppressed voxels was dynamically induced and depended on stimulus size. Mean delays for blood vessels were 0.7,2.4 sec longer than for parenchyma (P < 0.01). However, both parenchyma and blood vessels produced responses with long delays. We developed a model to identify and quantify different components contributing to variability in the empirical delay measurements. Within-voxel changes in delay over time were fully accounted for by the effects of empirically measured fMRI noise with virtually no measurable variability associated with the stimulus-induced response itself. Across voxels, as much as 47% of the delay variance was also the result of fMRI noise, with the remaining variance reflecting fixed differences in response delay among brain sites. In all cases, the contribution of fMRI noise to the delay variance depended on the noise power at the stimulus frequency. White noise models significantly underestimated the fMRI noise effects. Hum. Brain Mapping 13:74,93, 2001. © 2001 Wiley-Liss, Inc. [source]