GABA and Glutamate Levels in the Substantia Nigra Reticulata Following Repetitive Cerebral Ischemia in Gerbils

Repetitive cerebral ischemia produces more severe damage than a similar single duration insult. We have previously shown that, in gerbils, damage in the substantia nigra reticulata (SNr) is seen with repetitive insults rather than a single insult. We have also shown that there is a progressive decrease in the extracellular GABA in the striatum in the days preceding such damage, speculating that a loss of GABA may be in part responsible for this damage. This study evaluates the GABA levels in the SNr in animals exposed to repetitive ischemic insults. Each animal received a total of three ischemic insults of 3-min duration at hourly intervals.In vivomicrodialysis was carried out to analyze the GABA and glutamate dialysate levels on Days 1, 3, 5, 7, and 14 following the ischemic insult. In the control and treated (ischemic) animals, there was a significant increase in the GABA levels with the introduction of nipecotic acid on Days 1, 3, 5, and 14. However, on Day 7 there was a significant attenuation in the GABA response to nipecotic acid in the treated animals in comparison to the controls. The glutamate levels in the treated animals were similar to the control animals on Days 1, 3, 5, and 7. However, on Day 14 the glutamate levels were significantly lower than on previous days. Our experiments for the first time measure extracellular glutamate and GABA responses in the SNr in animals exposed to repetitive ischemic insults. Our experiments show that there is a significant decrease in the GABA concentrations at a time when ischemic damage is developing in this region. This confirms our hypothesis that a decrease in GABA may be one factor contributing to neuronal damage during the period following repetitive ischemic insults. Further, the rebound increase in GABA levels on Day 14 with a concomitant fall in glutamate levels would indicate that reparative processes are still active in the 2 weeks following the insult.     

Emphasized selective vulnerability after repeated nonlethal cerebral ischemic insults in rats.

BACKGROUND AND PURPOSE: We examined the density and distribution of brain damage after repeated periods of nonlethal ischemic insult in rats in comparison with damage after single lethal periods of ischemic insult. METHODS: Transient cerebral ischemia was induced by four-vessel occlusion for 3, 10, 20, and 30 minutes, and 3-minute periods of ischemia were repeated two, three, or five times at 1-hour intervals, followed by 7 days of survival. RESULTS: Three minutes of ischemia produced no brain damage, but 10-30 minutes of ischemia produced neuronal damage, depending on the length of ischemia, to the selectively vulnerable forebrain regions such as hippocampal CA1 and CA4 subfields, neocortex, striatum, and ventral thalamus, as well as to the brain stem structures (medial geniculate body, substantia nigra, and inferior colliculus) and cerebellar Purkinje cells. Two 3-minute periods of ischemic insult produced neuronal damage to the hippocampal CA1 subfield. Three and five 3-minute insults produced neuronal damage extensively to the selectively vulnerable forebrain areas. An intense cumulative effect of damage was observed in the ventral thalamus, whereas the substantia nigra and the inferior colliculus were resistant to repeated ischemic insults. CONCLUSIONS: Our data indicate that the density and distribution of neuronal damage after repeated ischemic insults are altered as compared with after single ischemia.     

Neuronal damage following non-lethal but repeated cerebral ischemia in the gerbil

Summary Brief, non-lethal transient forebrain ischemia in the gerbil can injure selectively vulnerable neurons when such ischemia is induced repeatedly. The influence of the number and interval of the ischemic insults on neuronal damage, as well as the time course of damage, following repeated 2-min forebrain ischemia were examined. A single 2-min forebrain ischemia were examined. A single 2-min ischemic insult caused no morphological neuronal damage. A moderate number of hippocampal CA1 neurons were destroyed following two ischemic insults with a 1-h interval, and destruction of almost all CA1 neurons resulted from three or five insults at 1-h intervals. Three and five insults also resulted in moderate to severe damage to the striatum and thalamus, depending on the number of episodes. Although three ischemic insults at 1-h intervals caused severe neuronal damage, this number of insults at 5-min and 4-h intervals caused destruction of relatively few neurons, and non neurons were destroyed at 12-h intervals. Following three ischemic insults at 1-h intervals, damage to the striatum, neocortex, hippocampal CA4 subfield and thalamus was observed at 6–24 h of survival, whereas damage to the hippocampal CA1 subfield appeared at 2–4 days. The results indicate that even a brief non-lethal ischemic insult can produce severe neuronal damage in selectively vulnerable regions when it is induced repeatedly at a certain interval. The severity of neuronal damage was dependent on the number and interval of ischemic episodes.     

Calcium deposits in the thalamus following repeated cerebral ischemia and long-term survival in the gerbil

We investigated the long-term changes in the gerbil brain following three episodes of 2-min forebrain ischemia at 1-h intervals in comparison with a 6-min period of ischemia. The animals were sacrificed after 1 month and 6 months. Following either ischemic insult, the hippocampal CA1 region showed a loss of pyramidal neurons together with a diffuse calcium accumulation as shown by alizarin red S staining. Three 2-min ischemic insults additionally produced neuronal damage in the striatum and thalamus. The thalamic damage was accompanied by an accumulation of small calcium granules after 1 month and large calcium concretions after 6 months. Calcium staining in the striatum was weak. Thus, the thalamic neuronal damage was accompanied by an active process of calcification, which has not been described in experimental cerebral ischemia models. The observations show that repeated ischemic insults produce different long-term effects in different brain regions.     

Neuronal damage and calcium accumulation following repeated brief cerebral ischemia in the gerbil

We investigated the distribution of neuronal damage following brief cerebral transient ischemia and repeated ischemia at 1-h intervals in the gerbil, using light microscopy and 45Ca autoradiography as a marker for detection of ischemic damage. The animals were allowed to survive for 7 days after ischemia induced by bilateral carotid artery occlusion. Following 2-min ischemia, neuronal damage determined by abnormal calcium accumulation was not observed in the forebrain regions. Following 3-min ischemia, however, abnormal calcium accumulation was recognized only in the hippocampal CA1 sector and part of the striatum. Two 2-min ischemic insults caused extensive abnormal calcium accumulation in the dorsolateral part of striatum, the hippocampal CA1 sector, the thalamus, the substantia nigra and the inferior colliculus. The ischemic insults were more severe than that of a single 3-min ischemia. However, three 1-min ischemic insults caused abnormal calcium accumulation only in the striatum. On the other hand, three 2-min ischemic insults caused severe abnormal calcium accumulation in the brain. The abnormal calcium accumulation was found in the dorsolateral part of striatum, the hippocampal CA1 sector, the thalamus, the medial geniculate body, the substantia nigra and the inferior colliculus. Gerbils subjected to three 3-min ischemic insults revealed most severe abnormal calcium accumulation. Marked calcium accumulation was seen not only in the above sites, but also spread in the neocortex, the septum and the hippocampal CA3 sector. Morphological study after transient or repeated ischemia indicated that the distribution and frequency of the neuronal damage was found in the sites corresponding to most of the regions of abnormal calcium accumulation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cortical activity, ionic homeostasis, and acidosis during rat brain repetitive ischemia

Recent data strongly suggest that repetitive ischemic episodes have an adverse cumulative effect on development of edema and tissue damage. We wanted to assess further whether special risks such as exacerbation of extracellular acidification reflecting progressive exhaustion of the capacity to buffer H+ in the extracellular space are associated with repeated short ischemic insults. We monitored spontaneous electrical activity, extracellular direct-current potential, extracellular H+ activity, and tissue PCO2 in the cerebral cortex of rats subjected to four cycles of 3-minute ischemia produced by four-vessel occlusion with 27-minute reperfusion after each insult. Except for electrical activity, which failed to recover fully from the first ischemic insult, all parameters returned to a level close to normal after each reperfusion. Changes during ischemia did not evolve with repetition of the insult. Electrical silence occurred within approximately 20 seconds after the onset of each ischemic episode and always preceded the steep drop of direct-current potential, indicating ischemic depolarization. Each four-vessel occlusion immediately initiated a steep rise of tissue PCO2 and extracellular H+ activity, with extracellular H+ activity reaching a maximum within approximately 145 seconds. Changes in extracellular H+ activity during each recirculation period consistently included an additional and short-lasting increase associated with repolarization, a rapid decrease closely related to that of tissue PCO2, and a slow progressive return to normal. These results suggest that short, repetitive ischemic episodes severe enough to produce cell membrane depolarization and maximum acidosis of the neuronal microenvironment do not have a deleterious cumulative effect on the studied parameters, in particular, on interstitial acidosis.     

Mild hypothermia as a treatment for central nervous system injuries Positive or negative effects？

Besides local neuronal damage caused by the primary insult,central nervous system injuries may secondarily cause a progressive cascade of related events including brain edema,ischemia,oxidative stress,excitotoxicity,and dysregulation of calcium homeostasis.Hypothermia is a beneficial strategy in a variety of acute central nervous system injuries.Mild hypothermia can treat high intracranial pressure following traumatic brain injuries in adults.It is a new treatment that increases survival and quality of life for patients suffering from ischemic insults such as cardiac arrest,stroke,and neurogenic fever following brain trauma.Therapeutic hypothermia decreases free radical production,inflammation,excitotoxicity and intracranial pressure,and improves cerebral metabolism after traumatic brain injury and cerebral ischemia,thus protecting against central nervous system damage.Although a series of pathological and physiological changes as well as potential side effects are observed during hypothermia treatment,it remains a potential therapeutic strategy for central nervous system injuries and deserves further study.     

Changes in extracellular glutamate concentration produced in the rat striatum by repeated ischemia.

BACKGROUND AND PURPOSE: Evidence suggesting that ischemia-induced neuronal damage may be linked to an extracellular overflow of glutamate has accumulated, and previous studies have shown that repetitive ischemic insults may have a cumulative effect. The purpose of this study was to investigate changes in the extracellular glutamate concentration produced by repeated brief ischemic episodes of varied severity. METHODS: Four consecutive 3- or 5-minute periods of bilateral hemispheric ischemia were produced in rats, each ischemic period followed by 27 minutes of reperfusion. Extracellular glutamate in the striatum was monitored using microdialysis, and the electroencephalogram and extracellular direct current potential were recorded in the same tissue site to assess the severity of ischemia. RESULTS: The results suggest that the kinetics of the increase in the extracellular glutamate concentration produced by a brief ischemic episode are similar, irrespective of whether it is a single insult or part of a repeated sequence. In all cases, the extracellular glutamate concentration increased throughout ischemia and returned to its preischemic level early during reperfusion. The pattern of changes in the ischemia-induced glutamate overflow during repetitive insults varied with the severity of ischemia, in common with the pattern of changes in the direct current potential, supporting the concept that ionic changes associated with anoxic depolarization are a major determinant of ischemia-induced glutamate overflow. CONCLUSIONS: There may be no cumulative effect of brief repeated episodes of ischemia on the extracellular glutamate concentration, even though repeated 5-minute ischemic episodes apparently caused progressive deterioration of ionic homeostasis in some cases.     

Autoradiographic analysis of second-messenger systems in the gerbil hippocampus following repeated brief ischemic insults.

Using [3H]inositol 1,4,5-triphosphate (IP3), [3H]phorbol 12,13-dibutyrate (PDBu) and [3H]forskolin, we performed quantitative autoradiography to determine sequential alterations in second-messenger systems in the gerbil hippocampus following repeated brief ischemic insults. Changes following three 2-min ischemic insults were compared with those following single 2- or 6-min ischemia. [3H]IP3 binding was extremely sensitive to ischemic insult, and more than 80% of the binding sites were lost after destruction of CA1 pyramidal cells following 6-min ischemia and three 2-min ischemic insults. Furthermore, a 30% reduction was observed after 2-min ischemia which leads to no neuronal loss. [3H]PDBu binding in the CA1 subfield decreased by 1 day after three 2-min ischemic insults and by 4 days after 6-min ischemia, and 40-50% reductions were observed at 1 month. In contrast, [3H]forskolin binding was relatively preserved. [3H]PDBu and [3H]forskolin binding transiently increased early in the reperfusion period. We also observed a difference in the pattern and severity of alterations between repeated ischemic insults and single ischemia.     

反复性脑缺血大脑皮质LTC_4、cAMP和OFR的代谢变化

目的：研究反复脑缺血大脑皮质白三烯（ＬＴＣ４）、环腺苷酸（ｃＡＭＰ）和氧自由基（ＯＦＲ）的代谢变化与神经元损伤的关系。方法：对比观察大鼠反复性与单次性脑缺血大脑皮质ＬＴＣ４、ｃＡＭＰ、超氧化物歧化酶（ＳＯＤ）和丙二醛（ＭＤＡ）的含量变化及相应的病理改变。结果：反复缺血及再灌流早期ＬＴＣ１、ｃＡＭＰ的含量明显升高,ＳＯＤ活性显著降低,ＭＤＡ延迟性持续显著增高,皮质神经元损害显著重于单次缺血组。结论：ＬＴＣ４、ｃＡＭＰ和 ＯＦＲ均参与了反复缺血性脑损害的病理机制,可能与 Ｃａ＋＋介导的花生四烯酸（ＡＡ）瀑布效应有关。     

反复性脑缺血大脑皮质LTC4、cAMP和OFR的代谢变化

目的：研究反复脑缺血大脑皮质白三烯（LTC4）、环腺苷酸（cAMP)和氧自由基（OFR）的代谢变化与神经元损伤的关系。方法：对比观察大鼠反复性与单次性脑缺血大脑皮质LTC4、cAMP、超氧化物歧化酶（SOD）和丙二醛（MDA）的含量变化及相应的病理改变。结果：反应缺血及再灌注早期LTC、cAMP的含量明显升高,SDO活性显著降低,MDA延迟性持续显著增高,皮质神经元损害显著重于单次缺血组。结论：LTC4、cAMP和OFR均参与了反复缺血性脑损害的病理机制,可能与Ca^ ＋介导的花生四烯酸（AA)瀑布效应有关。     

Effect of hyperthermia on calbindin-D 28k immunoreactivity in the hippocampal formation following transient global cerebral ischemia in gerbils

Calbindin D-28K(CB), a Ca2+-binding protein, maintains Ca2+ homeostasis and protects neurons against various insults. Hyperthermia can exacerbate brain damage produced by ischemic insults. However, little is reported about the role of CB in the brain under hyperthermic condition during ischemic insults. We investigated the effects of transient global cerebral ischemia on CB immunoreactivity as well as neuronal damage in the hippocampal formation under hyperthermic condition using immunohistochemistry for neuronal nuclei(Neu N) and CB, and Fluoro-Jade B histofluorescence staining in gerbils. Hyperthermia(39.5 ± 0.2°C) was induced for 30 minutes before and during transient ischemia. Hyperthermic ischemia resulted in neuronal damage/death in the pyramidal layer of CA1–3 area and in the polymorphic layer of the dentate gyrus at 1, 2, 5 days after ischemia. In addition, hyperthermic ischemia significantly decreaced CB immunoreactivity in damaged or dying neurons at 1, 2, 5 days after ischemia. In brief, hyperthermic condition produced more extensive and severer neuronal damage/death, and reduced CB immunoreactivity in the hippocampus following transient global cerebral ischemia. Present findings indicate that the degree of reduced CB immunoreactivity might be related with various neuronal damage/death overtime and corresponding areas after ischemic insults.     

Gamma-vinyl GABA prevents hippocampal and substantia nigra reticulata damage in repetitive transient forebrain ischemia

GABAergic inhibitory mechanisms may offer protection to neurons after global ischemia. We tested the effects of γ-vinyl GABA, a GABA-transaminase inhibitor, via continuous infusion in the third ventricle (Alza pumps) in a gerbil model of repetitive forebrain ischemia. We used two episodes of 3 min duration with a ’reperfusion’ interval of 1 h between the insults. Histological analysis was done with silver staining 5 days after the insult. Our results show that there is significant protection of the hippocampus CA1 region and substantia nigra reticulata in treated animals compared to controls. An increase in GABA levels, decrease in glutamate, or mild hypothermia, may be potential mechanisms for this protection. GABAergic agents may prove useful agents in repetitive ischemia.     

Increased neuronal injury in transgenic mice with neuronal overexpression of human cyclooxygenase-2 is reversed by hypothermia and rofecoxib treatment

Cyclooxygenase-2 (COX-2) is up-regulated during ischemia. However, the role of COX-2 in neuronal injury is still unclear. In this study we tested whether neuronal overexpression of human COX-2 in a transgenic mouse model potentiates neuronal injury after global ischemic insult. Further, we tested whether the neuronal injury could be ameliorated by intra-ischemic mild hypothermia (33-34 degrees C) alone or in combination with diet treatment of rofecoxib, a COX-2 specific inhibitor. Global ischemia with intra-ischemic normothermia (36-37 degrees C) resulted in significantly higher neuronal damage in the CA1 region of hippocampus of transgenic mice than in wild type controls, confirming a deleterious role of COX-2 in ischemic neuronal damage. Hypothermia significantly reduced neuronal damage in both transgenic mice and wild type controls to the same extent, suggesting that the aggravating effect of COX-2 could be largely eliminated by hypothermia. When hypothermia was combined with rofecoxib treatment, neuronal damage was further reduced in response to global ischemia. The results suggest that COX-2 inhibition by prophylactic treatment with rofecoxib coupled with hypothermia at the time of acute stroke insult could be an effective therapeutic approach in early stages of stroke treatment in high risk patients.     

反复性脑缺血神经元选择性易损性的实验研究

目的　研究反复性脑缺血神经元选择性易损性。方法应用４５Ｃａ放射自显影及光镜对比观察大鼠反复性与单次性脑缺血神经元损害的密度和分布。结果　单次缺血易损部位主要为海马、新皮层、纹状体、丘脑、小脑、脑干等;反复缺血易损区的分布与单次缺血基本相似,但下丘和小脑对反复缺血抵抗,而丘脑腹侧和海马呈现显著的累积性损害。结论　反复性脑缺血神经元选择性易损性及其机制均有别于单次性脑缺血。     

Repeated focal cerebral ischemia in gerbils is associated with development of infarction.

We induced repeated focal cerebral ischemia in gerbils. Single 5-min ischemia produced neuronal damage limited to the ipsilateral CA1 and CA4 hippocampus. Two 5-min ischemic insults spaced at a 1-h interval caused selective neuronal damage to the CA1, CA3 and CA4 hippocampus, striatum, neocortex, and thalamus. Three 5-min ischemic insults at 1-h intervals produced infarction. Thus, repeated focal ischemia produced cumulative brain damage by conversion of sublethal damage into selective neuronal damage and of the neuronal damage into infarction.     

Neuronal damage following repeated brief ischemia in the gerbil

The effect of repetition of brief ischemia, which causes no morphological brain damage when given as a single insult, was studied. Two-minute forebrain ischmia was induced in gerbils singly and 3 or 5b times at 60-min intervals. Although 2-min ischemia induced no neuronal damage, 3 or 5 repeated ischemic insults caused neuronal damage in the selectively vulnerable regions, the severity being dependent on the number of episodes.     

'Ischemic tolerance' phenomenon detected in various brain regions.

We investigated the effects of mild and non-lethal ischemic insult on neuronal death following subsequent lethal ischemic stress in various brain regions, using a gerbil model of bilateral cerebral ischemia. Single 10-min ischemia consistently caused neuronal damage in the hippocampal CA1, CA2, CA3 and CA4, layer III/IV of the cerebral cortex, dorsolateral part of the caudoputamen and ventrolateral part of the thalamus. On the other hand, in double ischemia groups, 2-min ischemic insult 2 days before 10-min ischemia exhibited significant protection in the CA1 and CA3 of the hippocampus, the cerebral cortex, the caudoputamen and the thalamus. Five-min ischemic insult 2 days before 10-min ischemia also showed protective effect in the same areas as those of 2-min ischemia except for the CA1 region of the hippocampus, while 1-min ischemic insult exhibited no protective effect in any brain regions. In the immunoblot analysis, both 2- and 5-min ischemia caused increased synthesis of heat shock protein 72 (HSP 72) in the hippocampus, but 1-min ischemia did not. The present study demonstrated that the 'ischemic tolerance' phenomenon was widely found in the brain and also suggested that ischemic treatment severe enough to cause HSP 72 synthesis might be needed for induction of 'ischemic tolerance'.     

Evidence for neuroprotective effects of endogenous brain-derived neurotrophic factor after global forebrain ischemia in rats.

The levels of brain-derived neurotrophic factor (BDNF) vary between different forebrain areas and show region-specific changes after cerebral ischemia. The present study explores the possibility that the levels of endogenous BDNF determine the susceptibility to ischemic neuronal death. To block BDNF activity the authors used the TrkB-Fc fusion protein, which was infused intraventricularly in rats during 1 week before and 1 week after 5 or 30 minutes of global forebrain ischemia. Ischemic damage was quantified in the striatum and hippocampal formation after 1 week of reperfusion using immunocytochemistry and stereological procedures. After the 30-minute insult, there was a significantly lower number of surviving CA4 pyramidal neurons, neuropeptide Y-immunoreactive dentate hilar neurons, and choline acetyltransferase- and TrkA-positive, cholinergic striatal interneurons in the TrkB-Fc-infused rats as compared to controls. In contrast, the TrkB-Fc treatment did not influence survival of CA1 or CA3 pyramidal neurons or striatal projection neurons. Also, after the mild ischemic insult (5 minutes), neuronal death in the CA1 region was similar in the TrkB-Fc-treated and control groups. These results indicate that endogenous BDNF can protect certain neuronal populations against ischemic damage. It is conceivable, though, that efficient neuroprotection after brain insults is dependent not only on this factor but on the concerted action of a large number of neurotrophic molecules.