Takaaki Kirino

Induced Tolerance to Ischemia in Gerbil Hippocampal Neurons

Brief ischemia induced tolerance to subsequent ischemia in the hippocampal neurons. Male Mongolian gerbils were subjected to 2 min of ischemia in an awake condition. This ischemic insult only rarely produced neuronal damage in the gerbil brain. One day (n = 9), 2 days (n = 9), or 4 days (n = 10) following the first brief ischemia, the animals (double-ischemia group) were subjected to the second ischemia for 5 min. The single-ischemia group received a sham procedure instead of the first ischemia and was identically subjected to the second ischemia 1 day (n = 9), 2 days (n = 10), and 4 days (n = 13) following the sham procedure. One week following the second ischemia, all gerbils were perfusion fixed and the neuronal density in the hippocampal CA1 sector was measured. In double-ischemia groups, the neuronal density per 1-mm length of the pyramidal cell layer was 103.4 ± 93.1 (SD) in the 1-day subgroup, 125.6 ± 64.2 in the 2-day subgroup, and 176.2 ± 93.7 in the 4-day subgroup, while the density in normal gerbils was 254.7 ± 18.6. The average neuronal density in the single-ischemia group was much lower than that in the double-ischemia group (whole control group: 10.9 ± 27.4). Immunostaining using monoclonal antibody raised against 70-kDa heat-shock protein revealed an increase in 70-kDa heat-shock protein in the CA1 area following 2 min of ischemia. Very brief ischemia induces heat-shock proteins and, presumably, thereby renders neurons more tolerant to subsequent metabolic stress.

Delayed neuronal death in the rat hippocampus following transient forebrain ischemia

SummaryAn unusual, slowly progressing neuronal damage has been reported to occur in the gerbil hippocampus following ischemia (Kirino 1982). Delayed neuronal death following ischemia has also been noticed in the rat four-vessel occlusion model (Pulsinelli et al. 1982). By light microscopy this slow neuronal injury in the rat was not different from the previously known neuronal ischemic cell change. This report lead us to the question as to whether neurons in the rat hippocampus are damaged rapidly following an initial latent period or deteriorate slowly and progressively until they display overt changes. To clarify this point, observation was done on the hippocampal CA1 sector of the rat following ischemia. Rats were subjected to four-vessel occlusion, and those which developed ischemic symptoms were perfusion-fixed. Although the change appeared very slowly and lacked microvacuolation of the cytoplasm, neuronal alteration was practically not different from classical ischemic cell change. By electron microscopy, however, the change was detectable when the neurons still appeared intact by light microscopy. An increase in the membranous organelles and deposition of dark substances were the initial manifestations. It seemed that the CA1 neurons deteriorated very slowly and progressively, and that they retained partial viability in the initial phase of the change. In spite of the difference in light-microscopic findings, the mechanisms underlying delayed neuronal death in the rat and gerbil hippocampus seemed to be identical.

Fine structural nature of delayed neuronal death following ischemia in the gerbil hippocampus.

SummaryAn unusual, delayed neuronal death (DND) has been noticed in the hippocampus of the Mongolian gerbil following brief ischemia (Kirino 1982). On day 1 following 5–10min of ischemia, light microscopy showed the CA1 pyramidal cells unchanged. On day 2, the cells showed massive growth of membranous cytoplasmic organelles instead of overt cellular disintegration. These neurons were destroyed extensively by day 4 after ischemic insult. Following longer ischemia (20–30min), however, the changes in the CA1 pyramidal cells appeared faster and resembled the wellcharacterized ischemic cell change (ICC). To further clarify the differences between ICC and DND, gerbils were submitted to transient 5–30min ischemia. They were perfusion-fixed following a given survival period and then processed for electron microscopy. Following transient ischemia, specimens showed slow cell changes with growth of cisterns of the endoplasmic reticulum (ER). In some CA1 neurons, the cytoplasm was shrunken and darkly stained, but they also displayed accumulation of ER cisterns. Occasionally, the CA1 cells demonstrated highly shrunken dark perikarya, no different than in ICC. These results indicate that DND seems to be the typical disease process of the CA1 sector and that a severer insult makes the change faster and more similar to ICC. ICC seems to occur when the CA1 pyramidal cells are damaged so severely that they cannot react with proliferous activity.

Behavioral changes after focal cerebral ischemia by left middle cerebral artery occlusion in rats

Behavioral changes after occlusion of the left middle cerebral artery (MCA) in rats were investigated for 16 weeks. Impairment of motor coordination and incidence of neurological deficits including hemiplegia and abnormal posture were present for the first 2 and 4 weeks after MCA occlusion, respectively. Learning behavior in one-trial passive avoidance task was disturbed for the entire 16-week period when rats were trained at days 3 after MCA occlusion. Reacquisition was also impaired when rats were retrained on 8 weeks after MCA occlusion. Except for synchronized EEG at days 2 after MCA occlusion, significant changes in spontaneous movement and EEG were not observed in the MCA-occluded group. These results suggest that this rat model of MCA-occlusion is useful for quantitatively measuring functional changes in chronic phase of focal cerebral ischemia.

A reversible type of neuronal injury following ischemia in the gerbil hippocampus.

The Mongolian gerbil is known to develop delayed neuronal death in the hippocampus following brief forebrain ischemia (Brain Res 239: 57-69, 1982). The effect of pentobarbital on this slow process of neuronal damage was examined. Immediately following 5 min of bilateral carotid occlusion, pentobarbital (10, 20, or 40 mg/kg) was injected. The control animals received saline injection. Seven days following ischemic insult, animals were perfusion-fixed and the neuronal density in the hippocampal CA1 subfield was counted. Most of the neurons in the CA1 sector survived ischemic insult when pentobarbital was given, whereas most of control group neurons were lost without the treatment. The average neuronal density of 20 mg/kg group was 168.2 +/- 12.3 (SEM) per 1 mm linear length of the CA1 subfield. The density in 40 mg/kg group was 181.1 +/- 14.9. The neuronal density in the whole control group was 34.3 +/- 5.1. The density of unoperated normal gerbils was 212.3 +/- 3.9. This result indicates that the neuronal damage of delayed neuronal death is reversible. On the other hand, when pentobarbital was injected 1 hr following ischemia, it showed no effect. The cell change in the CA1 sector, reversible at the initial stage, seems to rapidly become irreversible, while neurons still remain intact morphologically.

Selective vulnerability of the hippocampus to ischemia--reversible and irreversible types of ischemic cell damage.

Publisher Summary The hippocampus, among those vulnerable regions, is the area where anatomic, physiologic, and behavioral can be studied. For understanding the basic mechanism of ischemic neuronal damage, the hippocampus has proven to be one of the most suitable systems for experimental study. There is ample time to examine the CAI neurons before these cells totally lose their viability. Most of the population of nerve cells in the particular location in the hippocampus behaves almost synchronously and therefore it is easier to focus the attention than in a system where the neuronal change is scattered more sparsely. The chapter discusses the “vascular theory” that seems to be unsatisfactory to explain the cell damage in a circumscribed region of the hippocampus. In contrast, there is increasing evidence that the ischemic damage to hippocampal neurons is related to the chemical characteristics and interconnection of individual neurons in the complex circuitry of the brain.

Atrophy of the ipsilateral substantia nigra following middle cerebral artery occlusion in the rat

Following occlusion of the left middle cerebral artery in the rat, marked atrophy was observed in the ipsilateral substantia nigra in and after the second week. The mechanism of this neuropathological change in the substantia nigra, which is remote from the site of infarction, may be explained by transsynaptic, neurotransmitter-mediated disinhibition as a result of infarction of the striatum.

Progressive shrinkage of the thalamus following middle cerebral artery occlusion in rats.

Permanent middle cerebral artery occlusion in rats results in infarction in the ipsilateral cortex and caudate nucleus-putamen. In this ischemia model, severe shrinkage of the ipsilateral half of the thalamus was observed several months after surgery. We examined the serial profile of this phenomenon in 40 rats at intervals from 2 weeks to 6 months after the operation. The area of the ipsilateral half of the thalamus as a percentage of the area of the contralateral half was 87% at 2 weeks, 77% at 1 month, 54% at 3 months, and 54% at 6 months. Such severe morphologic change distant from the original ischemic focus has not been reported in models of experimental focal ischemia. Retrograde degeneration is thought to play an important role in this phenomenon.

Thalamic atrophy following cerebral infarction in the territory of the middle cerebral artery.

We investigated shrinkage of the ipsilateral thalamus following infarction in the territory of the middle cerebral artery in 33 patients who were admitted less than or equal to 2 days after the stroke and who were followed by computed tomography for greater than 1 year with no recurrences. The thalamic area was measured on the computed tomograms, and the ratio of the ipsilateral area to the contralateral area was calculated. All values were compared with values from the initial computed tomogram taken less than or equal to 2 days after the stroke. The values of the ratio on follow-up computed tomograms decreased gradually in 15 patients. In these cases, the area of the ipsilateral thalamus was significantly reduced after 1 year (p less than 0.01) and marked atrophy was observed. These results demonstrate the significance of remote changes over a long period of time after focal cerebral infarction.

Disturbance of Membrane Function Preceding Ischemic Delayed Neuronal Death in the Gerbil Hippocampus

Slice preparations were made from the hippocampus of gerbils after 5 min of ischemia by carotid artery occlusion and the membrane properties of pyramidal neurons were examined. A majority of CA1 neurons lost the capacity for long-term potentiation following tetanic stimulation of the input fibers. CA3 pyramidal neurons, in contrast, preserved responses similar to those in the normal gerbil. Following ischemia, CA1 pyramidal neurons showed increased spontaneous firing that was highly voltage dependent and was blocked by intracellular injection of the Ca2+ chelator, EGTA. Thirty-five percent of CA1 neurons showed an abnormal slow oscillation of the membrane potential after 24 h following ischemia. Intracellular injection of GTPγS or IP3 produced facilitation of the oscillations followed by irreversible depolarization. Our results indicate that ischemia-damaged CA1 neurons suffer from abnormal Ca2+ homeostasis, involving IP3-induced liberation of Ca2+ from internal stores.