‘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’.     

Regional impairment of protein synthesis following brief cerebral ischemia in the gerbil

Summary Regional cerebral protein synthesis following brief ischemia was investigated in the Mongolian gerbil, utilizing l-[methyl-¹⁴C]methionine autoradiography. Transient ischemia was induced for 1,2 or 3 min. At various recirculation periods up to 48 h, animals received a single dose of l-[methyl-¹⁴C]-methionine and then were terminated 35 min later. Sham-operated animals showed a normal pattern of amino acid incorporation into the proteins of the brain. Following 1-min ischemia, the pattern of protein synthesis was similar to that in the sham-operated gerbils. Ischemia for 2 min, however, caused marked inhibition of protein synthesis in the neocortex, striatum, hippocampal CA1 sector and the thalamus at 1 h of recirculation. Extensive recovery of protein synthesis was found in the neocortex, the striatum, the hippocampal CA1 sector and the thalamus at 5–24 h of recirculation, but, a slight inhibition was detectable in the hippocampal CA1 sector in one of six animals. This inhibition had fully recovered at 48 h of recirculation. Following 3-min ischemia, severe impairment of protein synthesis was found in the neocortex, striatum, the whole hippocampus and the thalamus. After 5–24 h of recirculation, the protein synthesis in these regions had gradually recovered, except that complete lack of amino acid incorporation was seen in the hippocampal CA1 subfield. This impairment of protein synthesis in the hippocampal CA1 sector was not recovered at 48h of recirculation. Morphological study indicated that 2-min ischemia did not produce any significant neuronal damage in the brain, whereas gerbils subjected to 3-min ischemia revealed a mild neuronal damage in the hippocampal CA1 sector. The present study indicates that even non-lethal ischemia can produce a severe inhibition of protein synthesis in the selectively vulnerable regions during the early stage of recirculation.     

Expression of neurotrophin receptors by proliferating glia in postischemic hippocampal CA1 sector of adult monkeys

Transient global cerebral ischemia elicits a nearly total neuronal cell death in the hippocampal CA1 sector, accompanied by a marked microglial and astroglial proliferation. The molecular mechanisms regulating the postischemic glial reaction in the primate brain remain obscure. Here we present in situ evidence that proliferating postischemic microglia in adult monkey CA1 sector express the neurotrophin receptor TrkA, while activated astrocytes were labeled for the TrkA ligand nerve growth factor (NGF) and the tyrosine kinase TrkB, a receptor for brain-derived neurotrophic factor (BDNF). These results implicate NGF and BDNF as regulators of postischemic glial proliferation in adult primate hippocampus.     

Immunohistochemical investigation of ischemic and postischemic damage after bilateral carotid occlusion in gerbils

We investigated progression and recovery of neuronal damage during and after global cerebral ischemia in gerbils after bilateral occlusion of the common carotid arteries, using the immunohistochemical method (reaction for tubulin and creatine kinase BB-isoenzyme). The earliest, but reversible, ischemic lesions occurred after 3 minutes' ischemia in the subiculum-CA1 and CA2 regions of the hippocampus. The lesions became irreversible after 4 minutes' ischemia. The ischemic and postischemic lesions in the cerebral cortex, thalamus, and caudoputamen were partially or completely reversible if the ischemic period was 5 minutes, whereas delayed degeneration occurred in the pyramidal cells of the medial CA1 region after reperfusion for 48 hours (delayed neuronal death). After 10 minutes' ischemia and subsequent reperfusion, delayed neuronal death extended from the medial to the lateral CA1 region; the ischemic and postischemic lesions in the cerebral cortex, thalamus, and caudoputamen also expanded during reperfusion. Our investigation demonstrates that selective vulnerability existed in global cerebral ischemia as in incomplete or regional ischemia and suggests that neurons in many areas of the brain possessed the potential for recovery, progressive deterioration, and even delayed neuronal death depending on the severity and duration of cerebral ischemia.     

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)     

'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'.     

Selective vulnerability in the gerbil hippocampus following transient ischemia

Summary Following brief ischemia, the Mongolian gerbil is reported to develop unusual hippocampal cell injury (Brain Res 239:57–69, 1982). To further clarify this hippocampal vulnerability, gerbils were subjected to ischemia for 3, 5, 10, 20, and 30 min by bilateral occlusion of the common carotid arteries. They were perfusion-fixed after varying intervals of survival time ranging from 3 h up to 7 days. Following brief ischemia (5–10min), about 90% of the animals developed typical hippocampal damage. The lesion was present throughout the extent of the dorsal hippocampus, whereas damage outside the hippocampus was not observed. Each sector of the hippocampus showed different types of cell reaction to ischemia. Ischemic cell change was seen in scattered CA4 neurons, and reactive change was found in CA2, whereas CA1 pyramidal cells developed a strikingly slow cell death process. Ischemia for 3 min did not produce hippocampal lesion in most cases. Following prolonged ischemia (20–30min), brain injury had a wide variety in its extent and distribution. These results revealed that the gerbil brief ischemia model can serve as an excellent, reliable model to study the long-known hippocampal selective vulnerability to ischemia. Delayed neuronal death in CA1 pyramidal cells was confirmed after varying degrees of ischemic insult. These findings demonstrated that the pathology of neuronal injury following brief ischemia was by no means uniform nor simple.     

Postictal blockade of ischemic hippocampal neuronal death in primates using selective cathepsin inhibitors

This paper is to study the participation of cathepsin in ischemic neuronal death of the monkey hippocampal cornu ammonis (CA) 1 sector and also to clarify whether its selective inhibitor epoxysuccinyl peptides such as CA-074 and E-64c can inhibit the neuronal death or not. In the preceding reports, we demonstrated mu-calpain activation and subsequent rupturing of the lysosomal membrane of postischemic CA1 neurons and also increase of enzyme activity of cathepsins B and L in monkeys undergoing a complete 20-min whole brain ischemia. Here, morphological, immunohistochemical and enzymatical analyses were performed to examine the efficacy of two selective cathepsin inhibitors in the postictal blockade of delayed neuronal death in the monkey hippocampus. Both inhibitors could significantly decrease enzyme activities of cathepsins B and L in all hippocampal sectors. When CA-074 was intravenously administered immediately after the ischemic insult, approximately 67% of CA1 neurons were saved from delayed neuronal death on day 5 after ischemia. In contrast, when E-64c was similarly administered, approximately 84% of CA1 neurons were saved from delayed neuronal death on day 5. The surviving neurons showed mild central chromatolysis and negligible immunoreactivity for cathepsins B and L. These observations indicate that the use of cathepsin inhibitors may become novel strategy for prevention of ischemic delayed neuronal death in the primate hippocampus.     

Ischemic tolerance to memory impairment associated with hippocampal neuronal damage after transient cerebral ischemia in rats

When rats were trained preoperatively with a three-panel runway task and were then exposed to 10-min ischemia by the method of 4-vessel occlusion, they showed no increase in the number of errors (attempts to pass through two incorrect panels of the three panel-gates at four choice points), having normal retention of memory performance learned before the ischemic insult. Next, we investigated the abilities of ischemic rats to acquire the three-panel runway task and to learn a subsequent reversal task, where the correct panel-gate locations were changed. Rats with 5-min ischemia exhibited performance as good as that of control rats, but rats exposed to 10- and 20-min ischemia showed more errors than control rats during 10 acquisition sessions and 5 subsequent reversal sessions, each of which (consisting of 6 trials) was given once a day. Marked neuronal degeneration was observed in the hippocampal CA1 sector from the rats with 10- and 20-min ischemia. Exposure to sublethal 5-min ischemia followed by 10-min ischemia at a 2-h interval had no effect on either the memory impairment during acquisition and reversal tests or the hippocampal CA1 damage. When rats were exposed to 5-min ischemia 2 days before lethal 10-min ischemia, they showed acquisition and subsequent reversal learning as good as that of control rats. Preconditioning with sublethal 5-min ischemia followed by 2 days of reperfusion also prevented the neuronal destruction of the hippocampal CA1 sector induced by 10-min ischemia. These findings suggest that postischemic hippocampal CA1 neuronal damage does not affect retention of spatial memory acquired before ischemia, but produces a significant impairment of acquisition and subsequent reversal learning. The present results also demonstrate that preconditioning with sublethal ischemia can develop tolerance to subsequent lethal ischemia to prevent the learning impairment related to the hippocampal CA1 neuronal damage.     

The density and distribution of ischemic brain injury in the rat following 2–10 min of forebrain ischemia

Summary The density and distribution of brain damage after 2–10 min of cerebral ischemia was studied in the rat. Ischemia was produced by a combination of carotid clamping and hypotension, followed by 1 week recovery. The brains were perfusion-fixed with formaldehyde, embedded in paraffin, subserially sectioned, and stained with acid fuchsin/cresyl violet. The number of necrotic neurons in the cerebral cortex, hippocampus, and caudate nucleus was assessed by direct visual counting.Somewhat unexpectedly, mild brain damage was observed in some animals already after 2 min, and more consistently after 4 min of ischemia. This damage affected CA4 and CA1 pyramids in the hippocampus, and neurons in the subiculum. Necrosis of neocortical cells began to appear after 4 min and CA3 hippocampal damage after 6 min of ischemia, while neurons in the caudoputamen were affected first after 8–10 min.Selective neuronal necrosis of the cerebral cortex worsened into infarction after higher doses of insult. Damage was worst over the superolateral convexity of the hemisphere, in the middle laminae of the cerebral cortex. The caudate nucleus showed geographically demarcated zones of selective neuronal necrosis, damage to neurons in the dorsolateral portion showing an all-or-none pattern. Other structures involved included the amygdaloid, the thalamic reticular nucleus, the septal nuclei, the pars reticularis of the substantia nigra, and the cerebellar vermis.Supported by the Swedish Medical Research Council (projects 12X-03020, 14X-263) and the National Institutes of Health of the United States Public Health Service (grant no. 5 R01 NS07838). Dr. Auer is the recipient of a Medical Research Council of Canada Fellowship.     

Heterogeneous hyperactivity and distribution of ischemic lesions after focal cerebral ischemia in Mongolian gerbils

Various types of poststroke hyperactivity exist in humans, but studies of each mechanism using animal models are scarce. We aimed to analyze the heterogeneity of postischemic hyperlocomotion and to identify the ischemic lesions responsible for postischemic hyperlocomotion in rodent models of focal ischemia. Mongolian gerbils underwent right common carotid artery occlusion (CCAO) for 10 or 20 min. At 24 h, 2 days, and 7 days postischemia, we performed quantitative and qualitative locomotor analysis and correlated these results with the extent of ischemic lesions. Intermittent explosive hyperlocomotion was induced transiently in a 10‐min CCAO group at 24 h after ischemia and continual unexplosive hyperlocomotion persisted for 7 days in the 20‐min CCAO animals. Selective neuronal death, confined to the hippocampal cornu ammonis 1 (CA1), was observed in the 10‐min CCAO group and widespread cortical and basal ganglia infarction was observed in the 20‐min CCAO group. Amyloid precursor protein was transiently observed in the hippocampus at 24 h postischemia in the 10‐min CCAO animals, while it was widely distributed over the ischemic regions throughout the 7 days postischemia in the 20‐min CCAO animals. Incidence maps and correlation analysis revealed hippocampal neuronal death of the CA1 sector and widespread hemispheric infarction, including the cortex, as the region responsible for the 10‐min and 20‐min CCAO‐induced hyperactivity, respectively. Two distinct types of locomotor hyperactivity were observed that varied with regard to the distribution of the ischemic lesion, that is, hippocampal neuronal death and widespread infarction involving the cortex. These two types of locomotor hyperactivity appear to be models of the different types of poststroke hyperactivity seen in stroke patients.     

Immunohistochemical localization of lysosomal cysteine protease cathepsins B and L in monkey hippocampal neurons after transient ischemia

The mechanism by which hippocampal neurons are selectively vulnerable to ischemic injury remains unclarified. Neuronal lysosomes are known to contain the cysteine protease cathepsins, which may be involved in the mechanism of delayed neuronal death. In this study, the expression and localization of cathepsins in the postischemic hippocampal neurons of the monkey were examined. Enzymatic activities and protein levels of cathepsins B and L were increased after ischemia in both the vulnerable CA1 sector and the remaining resistant sectors. Immunohistochemical analysis suggested that lysosomal enzymes of CA1 were localized mainly in the neuropil and not in the neuronal cell bodies, while the enzymes of CA2–4 sectors were located within the neurons and associated with the perinuclear lysosomal granules. Thus, it was concluded that distributional differences of cathepsins B and L after transient ischemia could be related to selective CA1 neuronal death in the hippocampus.     

Postischemic changes of [3H]nimodipine and [3H]ryanodine binding in the gerbil striatum and hippocampus

Sequential alterations of [³H]nimodipine and [³H]ryanodine binding in gerbils were investigated in selectively vulnerable regions, such as the striatum and hippocampus, 1 h to 7 days after 10 min of transient cerebral ischemia. [³H]Nimodipine binding showed no significant changes in the striatum and hippocampus up to 48 h after ischemia. Seven days after ischemia, however, a severe reduction in [³H]nimodipine binding was observed in the dorsolateral striatum, hippocampal CA1 (stratum oriens, stratum pyramidale and stratum radiatum) and hippocampal CA3 sector. On the other hand, [³H]ryanodine binding showed a significant increase in the hippocampus 1 h after ischemia. Five hours after ischemia, a significant reduction in [³H]ryanodine binding was observed only in the hippocampal CA1 sector. Thereafter, the striatum and hippocampus showed no significant alterations in [³H]ryanodine binding up to 48 h after ischemia. After 7 days, a marked reduction in [³H]ryanodine binding was observed in the striatum and hippocampus which were particularly vulnerable to ischemia. These results demonstrate that postischemic alteration in [³H]nimodipine and [³H]ryanodine binding is produced with different processes in the hippocampus. They also suggest that the mechanism for striatal cell damage caused by transient cerebral ischemia may, at least in part, differ from that for hippocampal neuronal damage. Furthermore, our findings suggest that abnormal calcium release from intracellular stores may play a pivotal role in the development of hippocampal neuronal damage.     

Effect of calcium antagonists on postischemic protein biosynthesis in gerbil brain.

BACKGROUND AND PURPOSE: Prolonged inhibition of protein synthesis precedes delayed neuronal death in the CA1 sector of the hippocampus after transient cerebral ischemia. Organic calcium antagonists have been recommended for alleviation of ischemic neuronal damage. The present study was undertaken to investigate whether these drugs improve the recovery of protein biosynthesis after interruption of cerebral blood flow. METHODS: Cerebral protein synthesis was measured biochemically and autoradiographically in gerbils submitted to 5 minutes of bilateral occlusion of the common carotid arteries followed by 2 hours or 2 days of recirculation. Flunarizine (25 mg/kg) or nimodipine (1.5 mg/kg) were applied intraperitoneally shortly after ischemia. RESULTS: Treatment with either calcium antagonist did not markedly influence postischemic recovery of protein synthesis in the resistant regions of the brain and did not prevent the persisting inhibition in the vulnerable stratum pyramidale of the CA1 sector of the hippocampus. CONCLUSIONS: The postischemic application of the organic calcium antagonists nimodipine and flunarizine does not promote postischemic recovery of protein synthesis. The beneficial effects of these drugs must, therefore, be based on other mechanisms.     

Neuronal damage and calcium accumulation following transient cerebral ischemia in the rat

The purpose of this study was to examine the distribution of neuronal damage following transient cerebral ischemia in the rat model of four-vessel occlusion utilizing light microscopy as well as⁴⁵Ca-autoradiography. Transient ischemia was induced for 30 min. The animals were allowed to survive for 7 d after ischemia. In the animals subjected to ischemia, the most frequently and seriously damaged areas were the paramedian region of hippocampus, the hippocampal CA1 sector, and the dorsolateral part of striatum, followed by the inferior colliculus, the substantia nigra, the frontal cortex, and the thalamus, which were moderate damaged. Furthermore, the cerebellar Purkinje neurons, the hippocampal CA4 sector, the medial geniculate body, and the hippocampal CA3 sector were slightly affected.⁴⁵Ca-autoradiographyic study also revealed calcium accumulation in the identical sites of ischemic neuronal damage, except for the frontal cortex. Regional cerebral blood flow during 10 min of ischemia was severely decreased in selectively vulnerable areas. The blood flow in the medial geniculate body, the substantia nigra, the inferior colliculus, and the cerebellum was less pronounced than that in the selectively vulnerable areas. The present study demonstrates that transient cerebral ischemia can produce significant neuronal damage not only in the selectively vulnerable regions, but also in the brainstem.     

Postischemic glucose metabolism is modified in the hippocampal CA1 region depleted of excitatory input or pyramidal cells

During early postischemic reperfusion, the vulnerable brain regions (e.g., hippocampal CA1) show a relatively high deoxyglucose accumulation. To investigate if this accumulation is a marker for the later-occurring regional cell death and to determine its cellular localization, we studied the glucose metabolism in the CA1 region post ischemia after removal of its pre- or postsynaptic components. A 20-min period of cerebral ischemia was used for selective removal of the main postsynaptic component in CA1 pyramidal cells, and a bilateral intraventricular injection of kainic acid for removal of the majority of presynaptic axon terminals in this region (and postsynaptic terminals and cell bodies in CA3). The glucose metabolism was studied in these two lesion types and in sham-operated animals before and after a period of ischemia. There was a 60% reduction of metabolism after ischemia in the nonvulnerable regions, whereas CA1 and sometimes CA3 showed a columnar pattern of high and low metabolism. CA1 and CA3 devoid of the postsynaptic component showed increased postischemic metabolism. The latter was due to the presence of macrophages, as demonstrated by an enzyme histochemical stain for nonspecific esterase. CA1 with no presynaptic component showed a postischemic depression of the glucose metabolism similar to the rest of the brain. It is suggested that the level of the postischemic glucose metabolism in the ischemia-vulnerable regions is determined by the presence of both synaptic components. The presence of macrophages in a region gives rise to apparently normal values of glucose metabolism.     

大鼠脑缺血再灌流后海马氨基酸水平变化与神经元损害的关系探讨

目的探讨脑缺血再灌流后海马氨基酸递质变化与神经元损害的关系。方法建立大鼠前脑缺血再灌流模型,测定海马ＣＡ１区和ＣＡ３／齿状回区游离氨基酸含量,观察阻断隔－海马通路对海马神经元损害和氨基酸水平的影响。结果（１）海马结构中仅ＣＡ１区神经元明显损害,但ＣＡ１区和ＣＡ３／齿状回区的Ｇｌｕ、Ａｓｐ和ＧＡＢＡ含量无差异。（２）阻断隔－海马通路可明显减轻海马神经元损害,但对海马氨基酸水平变化无影响。结论脑缺血再灌流后,氨基酸递质水平的异常变化不是海马ＣＡ１区神经元选择性易损的唯一决定因素,隔－海马通路末梢释放的神经递质也参与海马神经元损害过程。     

Naftidrofuryl protects neurons against ischemic damage

The effects of naftidrofuryl on postischemic neuronal damage and on local cerebral blood flow (LCBF) were examined in a rat model of forebrain ischemia (occlusion of carotid arteries and hypotension). Ischemia was induced for 10 min. LCBF was measured after 2 and 10 min of recirculation. A histological evaluation of cell loss in the hippocampal areas was performed 7 days after ischemia. Naftidrofuryl (10 mg/kg) was administered intraperitoneally 15 min before ischemia. The drug reduced the percentage of necrotic neurons in the CA1 and CA4 sector of the hippocampus, while the LCBF of these hippocampal sections was not significantly altered. Thus, naftidrofuryl is suggested to protect hippocampal neurons against ischemic damage mainly by a direct effect on brain parenchyma.     

Confocal laser scanning microscopy used to monitor intracellular Ca changes in hippocampal CA 1 neurons during energy deprivation

An increase in intracellular calcium during cerebral ischemia has been proposed as a common final pathway underlying the events leading to neuronal death. Intracellular calcium has been measured with ion selective electrodes during energy deprivation (ED) in hippocampal slices and with fluorescent techniques in neuronal cultures. In the present study, we describe a novel method to visualize and quantify changes in intracellular calcium in brain slices using Confocal Laser Scanning Microscopy (CLSM). CA 1 pyramidal neurons in hippocampal slices were filled by intracellular injection with a 1:2 mixture of the fluorescent dyes Fluo 3 and Fura Red. The neurons were then visualized using CLSM, and the ratio of the fluorescence from each probe used to quantify intracellular calcium concentrations before and during ED. The free intracellular calcium concentration was 60 nM prior to ED and increased to 24 μM during ED. These results demonstrates that CLSM and fluorescent probes can be used in functional neuronal networks in addition to cell cultures as previously described.