Unilateral Cortical Spreading Depression Research Articles

Effects of unilateral cortical inactivation on monoamine metabolism in symmetrical forebrain areas of white outbred mice

BACKGROUND: Clinical observations and animal experiments have shown the lateral specificity of the action of compounds that alter monoaminergic transmission. However, the mechanism of this phenomenon has not yet been studied.AIM:To evaluate the effect of unilateral cortical spreading depression on monoamine metabolism in white outbred mice. MATERIALS AND METHODS:Eighteen sexually mature male white outbred mice were studied. Functional inactivation of the cortex of one of the cerebral hemispheres was induced using unilateral epidural application of 1 × 1 mm filter paper moistened with 25% KCl solution. Then, 15 minutes after exposure, the animals were decapitated. The norepinephrine, dopamine, serotonin, and metabolite (i.e., dioxyphenylacetic (DOPAC), homovanilinic (HVA), and 5-hydroxyindolacetic (5-HIAA) acids) content of the cerebral cortex, hippocampus, olfactory tubercle, and striatum was measured using the HPLC method with an electrochemical detector. RESULTS: The inactivation of the left hemisphere was due to a bilateral decrease in norepinephrine in the hippocampus, an ipsilateral increase in extracellular metabolism of dopamine (HVA and/or HVA/dopamine) in the olfactory tubercle and striatum, and a contralateral increase of dopamine in the cortex and hippocampus. Furthermore, the DOPAC/dopamine ratio in the right olfactory tubercle decreased with left hemisphere inactivation. Right hemisphere inactivation did not cause bilateral effects. With inactivation of the right hemisphere on the inactivation side, norepinephrine in the hippocampus decreased and HVA in the striatum increased. In the left side, with the inactivation of the right hemisphere mice, dopamine in the hippocampus increased, as well as the DOPAC level and DOPAC/dopamine ratio in the olfactory tubercle. Serotonin metabolism (5-HIAA/serotonin) in the right hippocampus and left olfactory tubercle increased only at inactivation of the right hemisphere.CONCLUSIONS:The monoaminergic effects of functional inactivation of the left and right hemisphere cortex in white outbred mice are not mirror-symmetrical.

Changes in monoamine metabolism in the brain during unilateral cortical spreading depression in BALB/c mice

BACKGROUND: BALB/c mice can be adequate models for elucidating the actions of neurotropic drugs in conditions of abnormal interhemispheric interactions.
 AIM: To examine the effect of unilateral cortical spreading depression on monoamine metabolism in BALB/c mice.
 MATERIALS AND METHODS: Twenty-four adult male BALB/c mice were analyzed. Unilateral cortical spreading depression (functional inactivation of one of the cerebral hemisphere cortex) was induced by applying a 1 × 1 mm filter paper moistened with a 25% KCl solution. Fifteen minutes after exposure, the animals were decapitated. By using high-performance liquid chromatography with an electrochemical detector in the cerebral cortex, hippocampus, olfactory tubercle, and striatum, the levels of norepinephrine (NE), dopamine (DA), serotonin (5-HT) and their metabolites (dioxyphenylacetic [DOPAC], homovanilinic [HVA] and 5-hydroxyindolacetic acids) were measured.
 RESULTS: Unilateral cortical spreading depression was accompanied by a decrease in NE levels in the hippocampus and an increase in the DA extracellular metabolism (HVA and/or HVA/DA) in the olfactory tubercle and striatum on the side of the inactivated cortex. In addition to the listed effects, only functional inactivation of the right hemisphere caused a bilateral decrease in the NE level in the cortex and a decrease in the NE level and the DOPAC/DA ratio in the left (contralateral) hippocampus. No regular changes were noted in the posture of animals after the unilateral inactivation of the cerebral cortex.
 CONCLUSION:The results suggest that in BALB/c mice, the right hemisphere cortex plays a dominant role in regulating the activity of the noradrenergic system in the brain.

Transient loss of interhemispheric functional connectivity following unilateral cortical spreading depression in awake rats.

Growing evidence shows a critical role of network disturbances in the pathogenesis of migraine. Unilateral pattern of neurological symptoms of aura suggests disruption of interhemispheric interactions during the early phase of a migraine attack. Using local field potentials data from the visual and motor cortices, this study explored effects of unilateral cortical spreading depression, the likely pathophysiological mechanism of migraine aura, on interhemispheric functional connectivity in freely behaving rats. Temporal evolution of the functional connectivity was evaluated using mutual information and phase synchronization measures applied to local field potentials recordings obtained in homotopic points of the motor and visual cortices of the two hemispheres in freely behaving rats after induction of a single unilateral cortical spreading depression in the somatosensory S1 cortex and sham cortical stimulation. Cortical spreading depression was followed by a dramatic broadband loss of interhemispheric functional connectivity in the visual and motor regions of the cortex. The hemispheric disconnection started after the end of the depolarization phase of cortical spreading depression, progressed gradually, and terminated by 5 min after initiation of cortical spreading depression. The network impairment had region- and frequency-specific characteristics and was more pronounced in the visual cortex than in the motor cortex. The period of impaired neural synchrony coincided with post-cortical spreading depression electrographic aberrant activation of the ipsilateral cortex and abnormal behavior. The study provides the first evidence that unilateral cortical spreading depression induces a reversible loss of functional hemispheric connectivity in the cortex of awake animals. Given a critical role of long-distance cortical synchronization in sensory processing and sensorimotor integration, the post-cortical spreading depression breakdown of functional connectivity may contribute to neuropathological mechanisms of aura generation.

Effect of Unilateral Inactivation of Brain Hemispheres on Hypoxic Resistance in Mice

The effects of unilateral cortical spreading depression on the resistance to acute hypoxia with hypercapnia were studied in male SHR mice. The life-span of mice with active right hemisphere was significantly longer than that of intact, but not of sham-operated (active control) animals. Mice with active left hemisphere differed significantly from intact and active control animals. It seems that the right hemisphere supports the optimal level of resistance to hypoxia with hypercapnia, while the left hemisphere performs the "antihypoxic" function. Additional analysis found no differences between the hemispheres in mice with low hypoxic resistance. The differences between the hemispheres increased with increasing the resistance to hypoxia.

Unilateral cortical spreading depression affects sleep need and induces molecular and electrophysiological signs of synaptic potentiation in vivo.

Cortical spreading depression (CSD) is an electrophysiological phenomenon first described by Leao in 1944 as a suppression of spontaneous electroencephalographic activity, traveling across the cerebral cortex. In vitro studies suggest that CSD may induce synaptic potentiation. One recent study also found that CSD is followed by a non-rapid eye movement (NREM) sleep duration increase, suggesting an increased need for sleep. Recent experiments in animals and humans show that the occurrence of synaptic potentiation increases subsequent sleep need as measured by larger slow wave activity (SWA) during NREM sleep, prompting the question whether CSD can affect NREM SWA. Here, we find that, in freely moving rats, local CSD induction increases corticocortical evoked responses and strongly induces brain derived neurotrophic factor (BDNF) in the affected cortical hemisphere but not in the contralateral one, consistent with synaptic potentiation in vivo. Moreover, for several hours after CSD, large slow waves occur in the affected hemisphere during rapid eye movement sleep and quiet waking but disappear during active exploration. Finally, we find that CSD increases NREM sleep duration and SWA, the latter specifically in the affected hemisphere. These effects are consistent with an increase in synaptic strength triggered by CSD, although nonphysiological phenomena associated with CSD may also play a role.

Interhemispheric difference in susceptibility to epileptogenesis: Evidence from the audiogenic kindling model in Wistar rats

Audiogenic kindling (AK) represents a model of naturally occurring epileptogenesis in which intensification of repeatedly induced audiogenic seizures results from propagation of epileptic activity from the brainstem to forebrain. Previously it has been shown that unilateral cortical spreading depression (SD) is a reliable earliest manifestation of mild AK produced by repetition of minimal audiogenic seizures (running) in Wistar rats. The unilateral triggering SD suggests the existence of asymmetry in the forebrain recruitment during the kindling and the present study examined whether epileptogenesis produced by this mild AK paradigm is a lateralized process. Twenty five running episodes were induced by brief sound stimulation in Wistar rats susceptible to audiogenic seizures. Behavioral and EEG correlates of AK development were assessed. Running behavior elicited by brief sound stimulation had an asymmetrical pattern with profound preference for one direction. Most rats expressing leftward running displayed full kindling development whereas the majority of rats with rightward running were resistant to AK. The EEG marker of AK, a cortical epileptiform discharge, was recorded only in rats with leftward running and the first discharge appeared in the left cortex. Cortical SD was recorded after repeated running seizures in all rats with reproducible audiogenic response irrespective of the running lateralization and propensity to kindling. Until the late kindling stages, SD was triggered unilaterally in the cortex ipsilateral to the running direction. These findings indicate intrinsically determined lateralization of epileptogenic process in the mild AK model and enhanced vulnerability of the left hemisphere to epileptogenesis.

11C-PK11195 PET for the In Vivo Evaluation of Neuroinflammation in the Rat Brain After Cortical Spreading Depression

Neurogenic inflammation triggered by extravasation of plasma protein has been hypothesized as a key factor in the generation of the pain sensation associated with migraine. The principal immune cell that responds to this inflammation is the parenchymal microglia of the central nervous system. Using a PET technique with (11)C-(R)-[1-(2-chlorophenyl)-N-methyl-N-(1-methyl-propyl)-3-isoquinolinecarboxamide] ((11)C-PK11195), a PET ligand for peripheral type-benzodiazepine receptor, we evaluated the microglial activation in the rat brain after generation of unilateral cortical spreading depression, a stimulation used to bring up an experimental animal model of migraine. We found a significant increase in the brain uptake of (11)C-PK11195, which was completely displaceable by the excess amounts of unlabeled ligands, in the ipsilateral hemisphere of the spreading depression-generated rats. Moreover, the binding potential of (11)C-PK11195 in the spreading depression-generated rats was significantly higher than that in the sham-operated control rats. These results suggest that as an inflammatory reaction, microglial cells are activated in response to the nociceptive stimuli induced by cortical spreading depression in the rat brain. Therefore, the (11)C-PK11195 PET technique could have a potential for diagnostic and therapeutic monitoring of neurologic disorders related to neuroinflammation such as migraine.

Unilateral cortical spreading depression induced by sound in rats

Cortical spreading depression (SD) is thought to underlie the migraine aura but the mechanisms of triggering SD in the human cortex remain unknown. Because growing evidence points to a key role of brainstem circuits in initiating migraine attacks, the present study examined whether recurrent episodes of brainstem activation in rats could induce cortical SD. Explosive running elicited by sounds in rodents with inherited hypersensitivity to acoustic stimuli (reflex audiogenic epilepsy), is known to reflect a transient aberrant activation of the brainstem. Repeated induction of such audiogenic responses enhances the excitability of the cortex, culminating in its epileptic activation (audiogenic kindling). In Wistar rats with inherited hypersensitivity to sounds, 15 brief episodes of running were induced by sound stimulation, and slow potential shifts as well as the EEG were recorded in the cortex. Single unilateral SD began to occur in the cortex following a running episode after the 5th to 15th test (mean 9.4 ± 1.2). Once appeared, SD was regularly recorded in subsequent tests. The side of the SD initiation closely correlated with the direction of running. Triggering SD was not associated with epileptic activation of the cortex in most rats. The present findings suggest that the sensory-induced brainstem excitation could be a potent trigger of SD in the hyperexcitable cortex, providing an experimental evidence of a possible causative role of the brainstem activation in initiating the migraine aura.

Cortical spreading depression induces the expression of iNOS, HIF-1α, and LDH-A

The mechanisms of tolerance to subsequent episodes of ischemia induced by cortical spreading depression (CSD) are not clear. The effects of CSD on the expression of inducible nitric oxide synthase (iNOS), hypoxia inducible factor-1α (HIF-1α), and lactate dehydrogenase-A (LDH-A) were evaluated in the present experiment. Unilateral CSD was induced in Sprague-Dawley rats by application of KCl on the right cortex and the mRNA levels of iNOS, HIF-1α, and LDH-A were evaluated at 15 min, 2 h, 4 h, 6 h or 24 h after CSD. RT-PCR analysis showed: 1) an increase of iNOS mRNA at 15 min, 2 h, 4 h; 2) an increase of HIF-1α mRNA at 6 h; 3) an increase of LDH-A mRNA at 4 h. In situ hybridization with specific digoxigenin-labeled oligonucleotides revealed that the mRNA levels were increased at 15 min–2 h for iNOS, 2–4 h for LDH-A and 6 h for HIF-1 after CSD. Immunohistochemistry analysis revealed that levels of iNOS and HIF-1α were increased, respectively, at 2 h and 6 h after CSD. These data suggest that CSD promotes the expression of iNOS, HIF-1α, and LDH-A in nervous cells giving a neuroprotective effect.

Unilateral cortical spreading depression is an early marker of audiogenic kindling in awake rats

Spreading depression (SD), a self-propagating wave of reversible cellular depolarization, is thought to play an important role in brain pathophysiology. SD and seizures are closely related events but little is known about involvement of SD in chronic epileptogenesis. Here we show that cortical SD is the first and highly reproducible manifestation of audiogenic kindling induced by repeated sound stimulation of WAG/Rij rats with genetic audiogenic and absence epilepsy. Repetition of sound-induced running seizures in freely moving rats led to an appearance and gradual intensification of post-running facial and forelimb clonic convulsions coupled with afterdischarge in the fronto-parietal cortex. Before the development of these traditional manifestations of audiogenic kindling, an unilateral cortical SD wave began to be triggered by audiogenic seizures. Once cortical SD appeared, it became a permanent component of subsequent seizures. SD was always recorded in the hemisphere ipsilateral to the running direction. Only at the late stages of audiogenic kindling SD developed bilaterally. To estimate the contribution of SD in postictal effects of audiogenic seizures, we compared cortical activity after seizures induced SD or not. It was found that only seizures with cortical SD were followed by postictal suppression of spontaneous spike-wave discharges displayed by WAG/Rij rats. The results show that (1) cortical SD is readily triggered by brief sensory-induced seizures in awake animals; (2) SD may be responsible for postictal changes in cortical activity; (3) unilateral initiation of SD suggests asymmetrical recruitment of the cortex into seizure network during audiogenic kindling.

Delayed, but prolonged increases in astrocytic clusterin (ApoJ) mRNA expression following acute cortical spreading depression in the rat: evidence for a role of clusterin in ischemic tolerance

Clusterin is a sulfated glycoprotein produced by neurons and by resting and activated astrocytes that has several putative functions, including protective responses to brain injury. Cortical spreading depression (CSD) is a powerful yet largely benign stimulus that acutely is capable of providing long-lasting ischemic tolerance. The current study investigated possible alterations in expression of clusterin mRNA in the cerebral cortex of the rat at various times after unilateral CSD. Using semiquantitative in situ hybridization histochemistry, significant increases (30–100%; P≤0.05) in clusterin mRNA were detected in layers I–III and IV–VI of the ipsilateral cortex at 1, 2, 7 and 14 (layers I–III only) days after CSD. Transcript levels in the ipsilateral cortex were again equivalent to contralateral (control) levels at 28 days after CSD. These molecular anatomical studies also revealed that both neurons and nonneuronal cells (presumed reactive astrocytes) increased their expression of clusterin mRNA following CSD. Notably the time-course of increases in clusterin mRNA after CSD (1–14 days) overlaps that during which CSD reportedly provides neuroprotection against subsequent cerebral ischemia. These findings along with other evidence suggest that increased clusterin production and secretion, particularly by astrocytes, could be neuroprotective—perhaps via one or more of its putative actions that include inhibition of complement activation and cytolysis, effects on chemotaxis and apoptosis, and actions as an anti-stress protein chaperone.

Atrial natriuretic peptide expression is increased in rat cerebral cortex following spreading depression: possible contribution to sd-induced neuroprotection

Cortical spreading depression (CSD) is characterised by slowly propagating waves of cellular depolarization and depression and involves transient changes in blood flow, ion balance and metabolism. In cerebral ischaemia, peri-infarct CSD-like depolarization potentiates infarct growth, whereas preconditioning with a CSD episode protects against subsequent ischaemic insult. Thus, many of the long-lasting molecular changes that occur in CSD-affected tissue are presumed to be part of a ‘neuroprotective cascade.’ 3′,5′-Cyclic guanosine monophosphate (cGMP) has been shown to be a neuroprotective mediator and the nitric oxide system, which increases cGMP production by soluble guanylate cyclase, is up-regulated by CSD. Atrial and C-type natriuretic peptide (ANP/CNP) are present in cerebral cortex and their actions are mediated via particulate guanylate cyclase receptors and cGMP production. Therefore, in further efforts to characterise the role of cGMP-related systems in CSD and neuroprotection, this study investigated possible changes in cortical natriuretic peptide expression following acute, unilateral CSD in rats. Using in situ hybridisation, significant 20–80% increases in ANP mRNA were detected in layers II and VI of ipsilateral cortex at 6 h and 1–14 days after CSD. Ipsilateral cortical levels were again equivalent to control contralateral values after 28 days. Assessment of cortical concentrations of ANP immunoreactivity by radioimmunoassay revealed a significant 57% increase at 7 days after CSD. Despite using a sensitive signal-amplification protocol, authentic ANP-like immunostaining was readily detected in subcortical nerve fibres, but was not reliably detected in normal or CSD-affected neocortex, suggesting the presence of very low levels, and/or active or differential processing of the peptide. Cortical CNP mRNA levels are not altered by CSD, indicating the specificity of the observed effects. Overall, these novel findings demonstrate a prolonged increase in cortical ANP expression after an acute episode of CSD. The overlap between the described time course of CSD-induced protection against ischaemic insult and demonstrated increases in ANP levels, suggest that ANP (like nitric oxide) may contribute to CSD-induced neuroprotection, via effects on cGMP production and other signal-transduction pathways.

Prolonged induction of neuronal NOS expression and activity following cortical spreading depression (SD): implications for SD- and NO-mediated neuroprotection.

Cortical spreading depression (CSD) is associated with various short- and long-term physiological and neurochemical changes and has been shown to confer an increased susceptibility to accompanying ischemic injury or provide protection against a subsequent experimental ischemia. Nitric oxide is involved in the processes of ischemic injury and under certain conditions mediates cellular protection. To investigate the possibility that CSD-induced alterations in nitric oxide synthase (NOS) expression and activity occur and might be associated with the time-dependent enhancement or prevention by CSD of ischemic damage, this study examined the spatiotemporal changes in nNOS expression and activity in cerebral cortex following CSD. Anesthetized rats had unilateral CSD induced by a 10-min topical application of KCl and were killed at various times thereafter. CSD increased both nNOS mRNA and protein levels throughout layers II-III of cortex. nNOS mRNA in the affected neocortex was significantly increased by 30-90% at 2, 7, and 14 days (P < or = 0.05) compared with contralateral levels, but was not significantly above control values at 1-6 h, 1 day, and 28 days after CSD induction. Levels of [3H]-L-N(G)-nitroarginine binding to NOS were increased by 40-170% 7, 14, and 28 days (P < or = 0.01) after CSD in a similar, but delayed, profile to nNOS mRNA. Levels of nNOS-immunoreactivity were also increased in both neurons and astrocytes of ipsilateral cortex 7 and 14 days after CSD--confirmed by double-immunofluorescence localization. Ex vivo NOS activity in layers I-III of ipsilateral cortex was also increased by 30-50% (P < or = 0.01) at 7 and 14 days after CSD, times coincident with reported maximal ischemic protection. These results demonstrate that nNOS is up-regulated by cellular depolarization/depression occurring during CSD, or by resultant stimuli and suggest that "CSD-conditioned" cortex may be capable of producing appropriate levels of NO to mediate or contribute to protective/adaptive responses to subsequent physical ischemic injury.

Cortical spreading depression reversibly disrupts convulsive motor seizure expression in amygdala-kindled rats

To determine the role of the frontal cortex in the generalization of limbic seizures, we first produced unilateral cortical spreading depression to reversibly suppress neuronal activity in the motor cortex and then triggered an amygdala-kindled seizure. Three minutes following induction of unilateral spreading depression, stimulation of the ipsilateral kindled amygdala produced only a brief electrographic seizure, and completely failed to produce the bilateral electrographic and clonic convulsive seizures that were normally present during control trials. A very different outcome occurred when unilateral spreading depression was induced in the cortex contralateral to the kindled amygdala. In these cases, the electrographic amygdala seizures were normal and bilateral like control trials, yet the clonic convulsive seizures were lateralized and appeared to be controlled by the non-depressed, kindled hemisphere. These lateralized convulsions were identical to those observed following forebrain commissurotomy, when direct communication between the frontal cortices was permanently severed. The results of the present study further define the pathways of temporal lobe seizure propagation, and highlight the important contribution frontal cortical regions provide to both the electrographic and convulsive expression of amygdala-kindled seizures by amplifying local seizures and projecting them into downstream brainstem and spinal cord circuits.

Effect of cortical spreading depression on the levels of mRNA coding for putative neuroprotective proteins in rat brain.

Previous studies have demonstrated that cortical spreading depression (CSD) induces neuronal tolerance to a subsequent episode of ischemia. The objective of the present investigation was to determine whether CSD alters levels of mRNA coding for putative neuroprotective proteins. Unilateral CSD was evoked in male Wistar rats by applying 2 mol/L KCl over the frontal cortex for 2 hours. After recovery for 0, 2, or 24 hours, levels of several mRNA coding for neuroprotective proteins were measured bilaterally in parietal cortex using Northern blot analysis. Levels of c-fos mRNA and brain-derived neurotrophic factor (BDNF) mRNA were markedly elevated at 0 and 2 hours, but not 24 hours after CSD. Tissue plasminogen activator (tPA) mRNA levels were also significantly increased at 0 and 2 hours, but not 24 hours after CSD. Levels of the 72-kDa heat-shock protein (hsp72) mRNA were not significantly increased by CSD, except for a small elevation (20%) at 2 hours recovery. Levels of the 73-kDa heat-shock cognate (hsc73) mRNA were slightly, but significantly, increased at 2 and 24 hours of recovery. Finally, levels of mRNA for protease nexin-1 and glutamine synthetase were not significantly altered by CSD at any time studied. The current results support the hypothesis that neuronal tolerance to ischemia after CSD may be mediated by increased expression of FOS, BDNF, or tPA, but not by increased expression of hsp72, hsc73, nexin-1, or glutamine synthetase.

Increased striatal proenkephalin mRNA subsequent to production of spreading depression in rat cerebral cortex: activation of corticostriatal pathways?

Cortical Spreading Depression (CSD) is a slowly propagating wave of depolarization and negative interstitial DC potential, that when induced in the rat brain extends across the entire homolateral hemisphere. Despite evidence that CSD does not penetrate into subcortical regions, neurochemical changes in areas anatomically connected to cortex have been reported. In this study in situ hybridization histochemistry was used to examine the levels of cholecystokinin (CCK), proenkephalin (ENK) and prodynorphin (DYN) mRNA in cortex and forebrain basal ganglia following KCl-induced CSD. Unilateral CSD was induced by topical application of 3 M KCl (∼10 μl) onto the right parietal cortex for 10 min and rats were then killed 1–6 h and 1–28 days later. CCK mRNA levels were increased ( P<0.01) in the ipsilateral neocortex 3 h after CSD (13% above levels in contralateral side), reached a peak at 2 days (∼70%) and were still elevated at 7 (30%) but not, 14 or 28 days later. Unilateral CSD also produced a rapid and sustained increase ( P<0.05) in ENK mRNA in ipsilateral piriform cortex (from 3 h to 2 days; 70–250% above contralateral), and a delayed increase in caudate putamen and olfactory tubercle at 1 and 2 days (∼25% in both regions), but levels were again equivalent to control at 7 days and beyond. In contrast, no marked changes in neocortical ENK mRNA, or DYN mRNA in both cortex and basal ganglia, were observed under these conditions. These findings demonstrate that CSD has specific, rapid and long-lasting effects on neuropeptide expression in neocortex and subcortical areas. CSD-induced changes in mesostriatal ENK mRNA are proposed to reflect synaptic activation of local neurons via cortical afferent projections.

Transient neuronal depolarization induces tolerance to subsequent forebrain ischemia in rats.

Minor cortical injury has previously been shown to improve survival in animals subjected to ischemic insults. Although the mechanism by which an ischemia-tolerant state is achieved is not clear, transient neuronal depolarization is thought to play a central role in the development of the tolerance. One way of producing transient neuronal depolarization is by the induction of cortical spreading depression (CSD). The present study was conducted to evaluate the effect of preischemic transient depolarization, induced by CSD, on postischemic neuronal outcome in rats. Unilateral CSD was induced by application of KCl to the frontal cortex (CSD hemisphere) in three groups of isoflurane-anesthetized rats (CSD groups; n = 8/group). Sham animals (n = 12) did not undergo CSD. In a fifth group (n = 8), ketamine was administered during KCl application to inhibit CSD. One, three, or seven days after CSD, animals were subjected to forebrain ischemia produced by bilateral carotid artery occlusion. Injury to the striatum, hippocampus, and cortex was evaluated in hematoxylin and eosin-stained brain sections 3 days after ischemia. Preischemic CSD reduced postischemic injury in the ipsilateral cortex. The ratio of the number of injured neurons in the CSD hemisphere to that in the non-CSD hemisphere was significantly less in the groups subjected to CSD 1 day (0.51 +/- 0.33), 3 days (0.56 /- 0.22), and 7 days (0.40 +/- 0.17) before ischemia than in the sham operated group (1.11 +/- 0.47). In the ketamine group (CSD inhibition), there were no differences in the extent of injury in the two hemispheres (ratio = 0.84 +/- 0.47). Injury to the striatum and hippocampus was similar among the groups. Within each group, injury to these subcortical structures in the CSD hemisphere was not different from that in the non-CSD hemisphere. The data suggest that preischemic depolarization induced by CSD results in an adaptive response that reduces the vulnerability of cortical neurons to subsequent ischemic injury (ischemic tolerance).

Subcortical cerebral blood flow and metabolic changes elicited by cortical spreading depression in rat.

Changes in cerebral cortical perfusion (CBFLDF), local cerebral blood flow (lCBF) and local cerebral glucose utilization (lCGU) elicited by unilateral cortical spreading depression (SD) were monitored and measured in separate groups of rats anesthetized with alpha-chloralose. CBFLDF was recorded with laser Doppler flowmetry, while lCBF and lCGU were measured by the quantitative autoradiographic [14C]iodoantipyrine and [14C]-2-deoxyglucose methods, respectively. SD elicited a wave of hyperemia after a latency of 2 to 3 min followed by an oligemic phase. Ninety minutes following the onset of SD cortical (frontal, parietal and occipital) lCBF and lCGU were essentially the same as on the contralateral side and in sham-treated rats. However, alteration in the lCBF and lCGU in upper and lower brainstem persisted. The present results demonstrate, for the first time, that long-lasting cerebrovascular and metabolic alterations take place within the subcortical regions following SD. These regions provide an attractive site to integrate observations in man concerning spreading depression and the aura of migraine with the other features of the syndrome.

Cortical and thalamic lesions in rats with genetic absence epilepsy.

In generalized, non-convulsive, absence epilepsy, spike-and-wave discharges (SWD) are recorded in both the cortex and the thalamus. The effect of various cortical and thalamic lesions on the occurrence of spontaneous SWD was examined in rats from a strain with genetic absence epilepsy. Cortical ablations suppressed SWD recorded in the thalamus. KCl induced unilateral cortical spreading depression and transiently suppressed SWD in the ipsilateral cortex and thalamus; SWD recovered simultaneously in both structures. Bilateral thalamic lesions of the anterior nuclei, the ventromedial nuclei, the posterior area, or lesion of the midline nuclei did not suppress cortical SWD. However, large lesions of the lateral thalamus, including the specific relay and reticular nuclei, definitely suppressed ipsilateral SWD, and pentylenetetrazol, THIP or gammabutyrolactone failed to restore the cortical SWD. These results demonstrate that the neocortex and the specific thalamic nuclei are both necessarily involved in the generation of SWD in absence epilepsy.

Influence of unilateral cortical spreading depression on intraspecies aggression and sociability of isolated mice.

1. In male mice of the BALB/c line, it was shown with the aid of spreading depression that aggressive forms of behavior are controlled primarily by the left hemisphere, and intraspecies sociability (investigation of a partner), by the right. 2. Interhemispheric asymmetry of the control of behavior is more strongly expressed in high aggressive mice than in low aggressive and unaggressive individuals.