Food restriction attenuates ischemia-induced spatial learning and memory deficits despite extensive CA1 ischemic injury

The purpose of the present study was to examine whether short-term food restriction (40% less food over a 3-month period) can attenuate ischemia-induced CA1 neuronal degeneration, and whether this attenuation translated into improved recovery of functional impairments following global ischemia. There was a significant loss of pyramidal CA1 neurons in ischemic compared to sham-operated rats but no difference between the ad lib and food-restricted ischemic animals. Although the diet did not influence neuronal damage in ischemic animals, the performance of food-restricted ischemic rats in spatial task such as the radial arm maze was significantly better than that of ad lib fed ischemic rats. Food-restricted ischemic rats made equivalent numbers of working memory errors as sham-operated animals and took the same time to complete a standard 8-arm radial arm maze task. They also displayed higher activity level in the open field compared to ad libitum fed ischemic rats, and spent considerably more time in the open arms of the elevated plus maze compared to the other groups, suggesting decreased anxiety in these ischemic rats. The relative sparing of spatial memory performance in food-restricted ischemic animals suggests that food restriction facilitates functional recovery.     

In vivo administration of corticotropin-releasing hormone at remote intervals following ischemia enhances CA1 neuronal survival and recovery of spatial memory impairments: a role for opioid receptors

The contribution of corticotropin-releasing hormone (CRH) in the modulation of ischemia-induced cell death in vivo remains unclear. We characterized the impact of pre-ischemic administration of CRH (0, 0.1, 1, 5 microg, i.c.v., 15 min prior to vessel occlusion) on neuronal damage following global ischemia in rats. The injection of 5 microg CRH led to a 37% increase in CA1 neuronal survival compared to vehicle-treated ischemic animals, while pre-treatment with alpha-helical CRH (9-41) abolished this neuronal protection. A second objective aimed to determine whether CRH protection is maintained over weeks when the peptide is administered at remote time intervals following ischemia. Compared to vehicle-treated ischemic animals, administration of CRH 8h following global ischemia led to a 61% increase in CA1 neuronal survival observed 30 days post-ischemia. Neuronal protection translated into significant improvement of ischemia-induced spatial memory deficits in the radial maze. Finally, our findings demonstrated that selective blockade of kappa- and delta-opioid receptors (using nor-binaltorphimine and naltrindole, respectively) prior to CRH administration significantly reduced CA1 neuronal protection. These findings represent the first demonstration of enhanced neuronal survival following in vivo CRH administration in a global model of ischemia in rats. They also support the idea that CRH-induced neuroprotection involves opioid receptors activation.     

Ischemia-induced hyperactivity: effects of dim versus bright illumination on open-field exploration and habituation following global ischemia in rats

The current study reports the impact of different illumination conditions on exploratory activity following global ischemia in rats. Exploratory activity was tested at different post-ischemic intervals under bright (450 lux) or dim (40 lux) light exposure. A 30 min testing period performed 5 days post-reperfusion examined within-session open-field habituation in ischemic and sham-operated animals. Additional animals were tested in the open-field under the two illumination conditions for shorter 10 min tests on days 3, 6, and 9 following reperfusion. Our findings demonstrated illumination-related activity profile in the open-field in ischemic animals. While ischemic rats showed increased activity when tested under bright open-field illumination, reduced activity was observed under dim illumination as compared to sham-operated controls. Further, habituation deficits were not apparent in animals subjected to global ischemia under any illumination condition. Similar behavioral profiles and habituation were observed in ischemic animals when exposed to repetitive open-field tests at days 3, 6, and 9 following reperfusion. CA1 neuronal injury (approximately 75% as compared to sham rats) was comparable in all ischemic groups at day 12 following reperfusion. The present findings suggest that differences in initial behavioral reactivity of sham and ischemic rats to bright versus dimly lighted environments may contribute to differences in open-field exploration reported between these groups. They also challenge the notion that deficits in exploration in ischemic animals are mainly attributable to processes related to habituation, or that hyperactivity represents a reliable predictor of CA1 neuronal injury. These observations may help explain discrepant ischemia-induced behavioral effects reported in the open field.     

Persistent behavioral impairments and neuroinflammation following global ischemia in the rat

Cognitive deficits associated with cardiac arrest have been well documented; however, the corresponding deficits in animal models of global ischemia have not been comprehensively assessed, particularly after long‐term, clinically relevant survival times. We exposed male Sprague–Dawley rats to 10 min of bilateral carotid artery occlusion + systemic hypotension (40–45 mmHg) or sham surgery, and used histopathological assessments for short‐term survival animals (16 days) and both behavioral and histopathological assessments for long‐term survival animals (270 days). Analyses revealed significant long‐term deficits in ischemic animals’ learning, memory (T‐maze, radial arm maze), working memory (radial arm maze), and reference memory (Morris water maze, radial arm maze) abilities that were not associated with a general cognitive decline. Histological results showed significant increases in glial fibrillary acidic protein, neuron glia 2, OX‐42 and ED‐1 staining, as well as significant decreases in microtubule‐associated protein 2 staining and cornu ammonis area 1 (CA1) cell counts 16 days post‐ischemia. The pattern at 270 days was similar, but notably there was a persistent elevation of ED‐1 staining, suggesting recent cell death as well as significant atrophy of CA1. Whereas previous work has primarily reported transient changes in behavior after global ischemia, this study describes disturbances in several different functional domains following CA1 cell loss at clinically relevant survival times. Moreover, the histopathological outcome is suggestive of a spontaneous repopulation of CA1, but this was not sufficient to offset the behavioral impairments arising from the ischemic insult.     

The effect of rapid preconditioning on the microglial, astrocytic and neuronal consequences of global cerebral ischemia

Previous studies indicated preconditioning of the brain with sublethal ischemic insults separated by many hours, protected tissues from a subsequent lethal insult. We recently reported neuroprotection by a rapid preconditioning paradigm where a sublethal ischemic insult preceded test ischemia by only 30 min. We hypothesize that neuroprotection caused by the rapid ischemic preconditioning (IPC) will result in lowered microglial, reactive astrocytes and increased normal neuronal cell counts. Wistar rats underwent normothermic (36.5–37 °C) global cerebral ischemia, produced by bilateral carotid artery ligation after lowering mean systemic blood pressure. The preconditioning ischemic insult lasted 2 min and was associated with a sufficient amount of time to provoke anoxic depolarization. After a 30-min reperfusion period, 10-min test ischemia was produced, and histopathology was assessed 3 and 7 days later. Normal neuronal cell counts for control rats at 3 days survival were significantly lower (by 58%) than in IPC animals. Although there was a trend toward protection in IPC rats at 7 days, the difference in normal neuronal cell count between the IPC and control groups was not significant. IPC rats at 3 days but not 7 days of survival showed a significantly lower microglial cell count (by 56%) than control rats. These results showed that the protection induced through IPC at 3 days of survival produced lower numbers of microglia, while maintaining normal neuronal cells. No significant differences between control and IPC groups were found in astrocytic cell count at any time of reperfusion in any region of the hippocampus studied. The beneficial effects of IPC may, therefore, involve anti-inflammatory processes that target microglial activation after cerebral ischemia. Received: 1 July 1998 / Revised: 30 September 1998 / Accepted: 21 October 1998     

ATP-sensitive potassium channels (K(ATP)) in retina: a key role for delayed ischemic tolerance

The objectives of the present study were to determine the localization of K(ATP) channels in normal retina and to evaluate their potential roles in ischemic preconditioning (IPC) in a rat model of ischemia induced by increased intraocular pressure (IOP). Brown Norway rats were subjected to sublethal 3-, lethal 20- and 40-min ischemia and the functional recovery was evaluated using electroretinography. The time interval between ischemic insults ranged from 1 to 72 h. The effects of K(ATP) channel blockade on IPC protection were studied by treatment with 0.01% glipizide. IPC was mimicked by injection of K(ATP) channel openers of 0.01% (-)cromakalim or 0.01% P1060 72 h before 20-min ischemia. Co-expression of K(ATP) channel subunits Kir6.2/SUR1 was observed in the retinal pigment epithelium, inner segments of photoreceptors, outer plexiform and ganglion cell layers and at the border of the inner nuclear layer. In contrast to a 20- or 40-min ischemia, a 3-min ischemia induced no alteration of the electroretinogram (ERG) and constituted the preconditioning stimulus. An ischemic challenge of 40 min in preconditioned rats induced impairment of retinal function. However, animals preconditioned 24, 48 and 72 h before 20-min ischemia had a significant improvement of the ERG. (-)Cromakalim and P1060 mimicked the effect of IPC. Glipizide significantly suppressed the protective effects of preconditioning. In conclusion, activation of K(ATP) channels plays an important role in the mechanism of preconditioning by enhancing the resistance of the retina against a severe ischemic insult.     

缺血预处理后Fas蛋白表达与迟发性神经元凋亡的关系初步探讨

目的动态观察缺血预处理后大鼠大脑皮层和海马CA1区神经元凋亡与Fas蛋白表达变化情况,初步探讨缺血预处理后Fas蛋白表达与迟发性神经元凋亡的关系。方法四血管阻断法复制全脑缺血模型,动物随机分为非缺血对照组、预处理对照组、缺血预处理组和缺血组。采用尼氏和TUNEL染色法观察皮层及海马CA1区神经元存活数和凋亡细胞数,免疫组化方法检测Fas蛋白在缺血预处理后表达变化情况。结果缺血组缺血6h在皮质及海马CA1区Fas阳性表达细胞计数升高,12h达高峰;缺血预处理组缺血12h阳性细胞计数升高,24h达高峰。缺血组缺血6h出现凋亡细胞,48h凋亡细胞数达到高峰;缺血预处理组凋亡细胞数较缺血组明显减少。缺血组缺血7d神经元数明显减少,12周时神经元大量减少;缺血预处理组缺血7d时神经元数无明显变化,但12周时神经元同样大量减少。结论全脑缺血可能通过诱导Fas蛋白的表达增多,启动细胞凋亡,导致缺血后神经元凋亡的发生;缺血预处理虽可延缓缺血后神经元的凋亡,但无法提供真正的长时期的神经元保护作用,其有限的保护作用可能是通过延缓Fas蛋白的表达而减缓了神经元凋亡的进程。     

Effects of hypothermia and hyperthermia on attentional and spatial learning deficits following neonatal hypoxia-ischemic insult in rats

We previously reported that rats exposed to neonatal hypoxic-ischemic (HI) insult showed selective and long-lasting learning and memory impairments in the plus maze, 8-arm radial maze, choice reaction time (CRT) task, and water maze, and that they showed severe brain injury to areas such as parietal cortex, hippocampus, striatum and thalamus. In this study, we examined the effects of hypothermia and hyperthermia on learning and memory deficits following neonatal HI insult. Seven-day-old Wistar rats were subjected to left carotid artery ligation followed by 2 h of hypoxia (8% O2/92% N2) under three different temperature conditions: 27 degrees C (hypothermia), 33 degrees C (normothermia) and 37 degrees C (hyperthermia) in temperature-controlled chambers. Hypothermia significantly reduced attentional deficits in the CRT task and spatial learning deficits in the water maze, and protected against severe brain injury in comparison with the control temperature. On the other hand, hyperthermia aggravated the behavioral deficits and brain injury. These outcomes clearly show that temperature regulation during HI insult plays an important role in the induction of behavioral and histological changes following neonatal HI insult in rats.     

A novel version of the 8-arm radial maze: effects of cerebral ischemia on learning and memory

A novel version of the 8-arm radial maze task was developed to quantify spatial learning and memory in rats subjected to transient cerebral ischemia (TCI) using the 4-VO model. This maze uses the rat's natural behavior of avoiding open, illuminated areas, and preference for a darkened, enclosed shelter. Ischemic rats were required to escape from the central area into the darkened goal box. Ischemia was induced before or after training to examine its influence on acquisition and retention of cognition, respectively. During the acquisition test, latency of ischemic rats to find the goal box, and working memory performance were significantly impaired (P < 0.005-0.001). The performance for retention of cognition was also disrupted by ischemia (P < 0.05-0.01). There was no correlation between the degree of CA1 pyramidal cell loss and behavioral deficits. The present data reveal that the aversive version of the 8-arm radial maze is sensitive to the cognitive effects of ischemia. Since it excludes the need for food deprivation or immersion of the animal in water, the method should provide a sensitive and more practical behavioral test with which to evaluate the effects of ischemic brain damage on cognition.     

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.     

Cerebral ischemia: Are the memory deficits associated with hippocampal cell loss?

The long-standing notion that damage restricted to the hippocampal formation is sufficient to produce a significant global memory deficit derives from clinical data. Specifically, it is based on the observation that transient global ischemia, which leads to partial cell loss within the hippocampal formation but not in other brain areas important for memory, can produce global amnesia in humans. This view is, however, challenged by a number of experimental findings. First, in both monkeys and rats, there is evidence that ischemia disrupts delayed object recognition, a memory process found to be largely intact following selective hippocampal lesions. These findings indicate that damage confined to the hippocampal formation cannot account for all aspects of the ischemia-induced memory impairments. Second, although some groups of hippocampal neurons are the most prone to degeneration following ischemia, a wide array of extra-hippocampal damage has been observed in all species, for which the precise extent and distribution may well be underestimated by conventional histological evaluations of ischemic brains. Partial neuronal degeneration reported in regions such as the rhinal areas, medial dorsal thalamic nucleus, or cingulate cortex may contribute to varying degrees to ischemia-induced memory deficits. Third, experimental studies have failed to generate a general consensus on the correlation between extent of hippocampal cell loss and memory performance. In sum, the experimental studies do not, as yet, support the view that hippocampal damage is solely responsible for ischemia-induced memory deficits. Rather, they suggest that both the intra- and extra-hippocampal damage contribute to the pattern of memory impairments observed following ischemia. Consequently, although animals with global and focal ischemia represent valuable models for neuropathological and therapeutic studies, they may not be so useful in assessing the role of the hippocampal formation and its sub-components in memory processes. © 1996 Wiley-Liss, Inc.     

Temporal profile of the effects of pretreatment with brief cerebral ischemia on the neuronal damage following secondary ischemic insult in the gerbil: cumulative damage and protective effects

We examined the response of the gerbil brain to secondary ischemic insult following pretreatment with brief ischemia at intervals of 5 min, 1 and 6 h, 1, 2, 4, 7 and 14 days. Two minutes of bilateral carotid artery occlusion produced no histopathological brain damage, whereas 3 min of occlusion caused a moderate to severe reduction in the number of hippocampal CA1 pyramidal cells. Two-minute occlusion followed by 3-min occlusion at 5-min, 1- and 6-h intervals resulted in almost complete destruction of CA1 neurons. Additional neuronal damage was observed in the striatum at a 1-h interval and in the thalamus and the neocortex at 1- and 6-h intervals. The neuronal damage was most severe at a 1-h interval. Two-minute ischemia followed by 3-min ischemia at intervals of 1, 2, 4 and 7 days, however, caused a marked protective effect, and the hippocampal CA1 neurons were preserved. The protective effect was not observed at a 14-day interval and following pretreatment with 1-min ischemia. Thus, pretreatment with brief ischemia leads to complex responses of the brain to secondary ischemic insult; cumulative damage at intervals of 1-6 h and protective effects at intervals of 1-7 days.     

Ischemic preconditioning in 18- to 20-month-old gerbils: long-term survival with functional outcome measures.

BACKGROUND AND PURPOSE: In young animals, ischemic preconditioning protects CA1 hippocampal neurons against global ischemia. However, cerebral ischemia occurs most frequently in individuals aged >/=65 years. This study examined the protection provided by ischemic preconditioning in a population of aged (18- to 20-month-old) gerbils. METHODS: One group of animals was exposed to two 1.5-minute episodes of global ischemia separated by 24 hours and followed 72 hours later by a 5-minute occlusion of both carotid arteries. A second group was given 2 episodes of preconditioning only. Two other groups were exposed to 5 minutes of ischemia or sham surgery. The animals survived 10, 30, or 60 days. Functional and histological assessments were used to determine the extent of protection. RESULTS: Ten days after ischemia there was >80% protection of CA1 neurons in ischemic preconditioned animals compared with 6% in ischemic gerbils. Nevertheless, these preconditioned animals were impaired in open-field tests of habituation. In addition, CA1 dendritic field potentials were smaller in amplitude compared with those in sham animals. While there was a complete loss of staining for CA1 microtubule-associated protein-2 in ischemic animals, staining in ischemic preconditioned animals was normal. This suggests that dendritic abnormalities per se were not responsible for the observed functional deficits. CA1 cell survival declined to approximately 75% of sham values (P<0.05) at 60 days after ischemia. CONCLUSIONS: Ischemic preconditioning provided substantial neuroprotection in aged gerbils. Nonetheless, the striking dissociation between histological and functional protection provided by ischemic preconditioning in aged animals emphasizes the need to use functional end points and long-term survival when assessing neuroprotection. Although functional recovery was evident with increasing survival time, CA1 cell death continued, thereby raising the possibility that the level of neuroprotection attained was not permanent.     

Characterizing learning deficits and hippocampal neuron loss following transient global cerebral ischemia in rats

The 2-vessel-occlusion + hypotension (2VO + H) model of transient global cerebral ischemia results in neurodegeneration within the CA1 field of the hippocampus, but previous research has failed to demonstrate robust or reliable learning/memory deficits in rats subjected to this treatment. In the present study, sensitive behavioral protocols were developed in an effort to characterize the cognitive impairments following 2VO + H more precisely. Adult rats were exposed to 10 min of bilateral carotid occlusion with simultaneous hypotension. Following recovery, 2VO + H and control rats were subjected to a series of behavioral tests (locomotor activity, sensorimotor battery, water maze [cued, place, learning set], object recognition, and radial arm maze) over an extended recovery period followed by an assessment of neuronal loss in the dorsal hippocampus. The 2VO + H treatment was associated with long-lasting spatial learning deficits in the absence of other behavioral impairments and with neurodegeneration in dorsal hippocampal CA1. Water maze protocols that placed higher memory demands upon the rats (relatively "hard" vs. "easy") were more sensitive for detecting ischemia-induced deficits. We have shown that the use of appropriate behavioral tests (e.g., a relatively difficult place learning task) allowed for the observation of robust spatial learning deficits in a model previously shown to induce relatively subtle behavioral effects. Thus, the 2VO + H model induces both hippocampal neuronal loss and long-term learning deficits in rats, providing a potentially useful model for evaluating therapeutic efficacy.     

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.     

Improvement of passive avoidance task after grafting of fetal striatal cell suspensions in ischemic striatum in the rat

Behavioral recovery and cell survival/growth after grafting of fetal striatal cell suspensions in the ischemic striatum of rats were investigated. Ischemia was induced by one hour intraluminal occlusion of the right middle cerebral artery under halothane anesthesia. During the ischemia rats usually manifested signs of hemiparesis and sometimes rotations. Behavioral function was measured by a passive avoidance task and radial arm maze test at 1-2 weeks and 6-7 weeks after ischemia. The size of the ischemic lesions depended on each animal, but the ischemic animals showed deficits in both passive avoidance task and radial maze test. Two weeks after ischemia, fetal striatal cells, marked with DiI, were transplanted into the ischemic striatum. The transplantation improved the ischemia-induced deficit in the passive avoidance task but not in radial maze test. Although there were variations in the size of the grafts, many DiI-positive cells with dendritic outgrowth were detected under fluorescent microscopy. Immunohistochemical study revealed that many choline acetyltransferase (ChAT) positive cells and GABA-positive cells survived in the grafts. However, striosome-matrix compartments were not evident inside the grafts. Thus, partial recoveries in both cytoarchitectural and behavioral aspects were obtained by striatal cell grafts, suggesting that neural transplantation could be a useful approach in reconstructing ischemic brain function.     

Repeated unilateral carotid occlusion in Mongolian gerbils: quantitative analysis of cortical neuronal loss

Summary To develop an experimental model which enables quantitative analysis of chronic neuronal loss in the cerebral cortex, repeated ischemic insult was performed using unilateral carotid artery occulusion in Mongolian gerbils. The effect of the time interval between the repeated ischemic insult on the survival rate of the animals and the amount of cortical neuronal loss were examined. The time course of the cortical neuronal damage in repeated ischemic insult was also studied. We repeated the occlusion four times; i.e., one 10-min and three 7-min occlusion (total 31 min of ischemia). The number of animals surviving for 3 weeks after the last biochemic insult was minimum (15.4%) for animals undergoing occlusions at 1-h intervals and maximum (100%) at 24- and 48-h intervals. The number of ischemic neuronal deaths was also dependent upon the time interval, and it was so pronounced as to allow analysis at intervals of 12 hr or 24 hr in the absence of infarction in the cortex. The number of neuronal deaths could not be determined for animals with occlusion at 1-h intervals due to the production of a large infarction, with which the 3-week survival rate was minimum. The temporal profile of cortical neuronal loss in the repeated ischemic insult at 24-h intervals indicated that the number of cortical neurons significantly decreased until 7 days after the start of the ischemic procedure. This model is useful for clarifying the pathophysiology of chronically developing ischemic neuronal death.     

Characterization of spinal HSP72 induction and development of ischemic tolerance after spinal ischemia in rats

Induction of heat shock protein (HSP72) has been implicated in the development of ischemic tolerance in several tissue organs including brain and spinal cord. In the present study, using an aortic balloon occlusion model in rats, we characterized the effect of transient noninjurious (3 or 6 min) or injurious intervals (10 min) of spinal ischemia followed by 4-72 h of reflow on spinal expression of HSP72 and GFAP protein. In a separate group of animals, the effect of ischemic preconditioning (3 or 6 min) on the recovery of function after injurious interval of spinal ischemia (10 min) was studied. After 3 min of ischemia, there was a modest increase in HSP72 protein immunoreactivity in the dorsal horn neurons at 12 h after reperfusion. After 6 min of ischemia, a more robust and wide spread HSP72 protein expression in both dorsal and ventral horn neurons was detected. The peak of the expression was seen at 24 h after ischemia. At the same time point, a significant increase in spinal tissue GFAP expression was measured with Western blots and corresponded morphologically with the presence of activated astrocytes in spinal segments that had been treated similarly. After 10 min of ischemia and 24 h of reflow, a significant increase in spinal neuronal HSP72 expression in perinecrotic regions was seen. Behaviorally, 3 min preconditioning ischemia led to the development of a biphasic ischemic tolerance (the first at 30 min and the second at 24 h after preconditioning) and was expressed as a significantly better recovery of motor function after exposure to a second 10-min interval of spinal ischemia. After 6 min ischemic preconditioning, a more robust ischemic tolerance at 24 h after preconditioning then seen after 3-min preconditioning was detected. These data indicate that 3 min of spinal ischemia represents a threshold for spinal neuronal HSP72 induction, however, a longer sublethal interval (6 min) of preconditioning ischemia is required for a potent neuronal HSP72 induction. More robust neurological protection, seen after 6 min of preconditioning ischemia, also indicates that HSP72 expression in spinal interneurons seen at 24 h after preconditioning may represent an important variable in modulating ischemic tolerance observed during this time frame.     

Characterization of postischemic behavioral deficits in gerbils with and without hypothermic neuroprotection

Five minutes of global ischemia in gerbil results in delayed hippocampal CA1 neuronal degeneration, which is accompanied by working memory impairments and hyperactivity in novel environments. In this study, postischemic activity was characterized in familiar and in novel environments to determine whether hyperactivity was due to impaired spatial habituation or another form of motor hyperactivity. This study also determined whether 6-h delayed hypothermia, which reduces CA1 neuronal injury, would attenuate functional impairments. Gerbils were subjected to 5 min of normothermic ischemia or sham operation 2 days following implantation of brain temperature probes. One of two ischemic groups was cooled (>48 h) starting at 6-h postischemia. Locomotor activity in a familiar cage was measured for 6 days while activity in three novel environments was intermittently measured on days 4, 5 and 6. Open field behavior and working memory in a T-maze were also assessed. Untreated ischemia caused marked hyperactivity in the familiar cage on day 1, which reverted to near-normal by day 2. Nonetheless, these gerbils showed hyperactivity during novel environment sessions on days 4–6. This maze behavior, which predicted hippocampal CA1 injury, was not due to different habituation rates nor baseline hyperactivity. Conversely, open field sessions on day 8 revealed ischemic habituation rate deficits. Ischemia also impaired working memory in the T-maze. Delayed hypothermia, which reduced neuronal loss in the CA1 sector to 12% from 81%, reduced all functional impairments. Ischemic gerbils quickly developed spontaneous locomotion hyperactivity that returned to near-normal after 1 day. This motor hyperactivity did not explain the elevated activity found with delayed testing in novel environments. Regardless, only the open field test on day 8 revealed a habituation-like deficit.