Perforant path stimulation in rats produces seizures, loss of hippocampal neurons, and a deficit in spatial mapping which are reduced by prior MK-801.

Severe temporal lobe epilepsy in humans is often associated with loss of neurons in the hippocampus and memory deficits. In Experiment 1, 60 min of continuous electrical stimulation of the perforant path sufficient to produce seizures resembling status epilepticus and loss of hilar and pyramidal cells in the hippocampus, produced a deficit in spatial mapping in the Morris water tank. In particular, the previously stimulated rats took longer and swam farther to find a hidden, but not a visually cued, platform, and, in contrast to the unstimulated control rats, were not disrupted by movement of the platform to a new location. In Experiment 2, a single injection of the non-competitive NMDA receptor antagonist, MK-801 (1.0 mg/kg), just prior to the perforant path stimulation reduced the seizures, hippocampal neuronal loss, and deficit in spatial mapping. These data suggest that temporal lobe seizures can induce deficits in spatial memory by selectively destroying neurons within the hippocampus, and that the mechanism by which this occurs involves the activation of NMDA receptors, and, perhaps, consequent excitotoxicity.

Interleukin-1 receptor antagonist attenuates regional neuronal cell death and cognitive dysfunction after experimental brain injury.

The effect of systemic administration of human recombinant interleukin-1 receptor antagonist (rhIL-1ra) on behavioral outcome and histopathologic damage after lateral fluid-percussion brain injury of moderate severity was evaluated. In study 1, brain-injured Sprague Dawley rats received timed subcutaneous injections beginning 15 minutes after injury of either 100 mg/kg rhIL-1ra (high dose, total dose = 1900 mg/kg), 10 mg/kg rhIL-1ra (low dose, total dose = 190 mg/kg), or vehicle over 7 days. No effect of low-dose rhIL-1ra was observed in study 1. High-dose rhIL-1ra significantly attenuated posttraumatic neuronal loss in the injured hippocampal CA3 region (P < 0.05), dentate hilus (P < 0.05), and cortex (P < 0.05) but impaired recovery of motor function at 7 days after trauma (P < 0.05). In study 2, rats were pretrained to learn a visuospatial task in a Morris water maze, subjected to fluid-percussion brain injury or sham treatment, and randomly assigned to receive multiple subcutaneous injections at timed intervals of 100 mg/kg rhIL-1ra (total dose = 900 mg/kg) or vehicle over 42 hours, followed by continuous infusion of a lower concentration of rhIL-1ra (20 mg/kg/day, total dose = 100 mg/kg), or vehicle for 5 days using subcutaneously implanted osmotic minipumps. Postinjury administration of rhIL-1ra significantly attenuated cognitive deficits compared with vehicle-treated animals at 42 hours (P < 0.05) but did not affect motor function at 48 hours, 1 week, and 2 weeks. These results suggest that inhibitors of cytokine pathways may be therapeutically useful for the treatment of brain trauma.

Insulin-like growth factor-1 (IGF-1) improves both neurological motor and cognitive outcome following experimental brain injury.

We evaluated the efficacy of insulin-like growth factor-1 (IGF-1) in attenuating neurobehavioral deficits following lateral fluid percussion (FP) brain injury. Male Sprague-Dawley rats (345-425 g, n = 88) were anesthetized and subjected to FP brain injury of moderate severity (2.4-2.9 atm). In Study 1, IGF-1 (1.0 mg/kg, n = 9) or vehicle (n = 14) was administered by subcutaneous injection at 15 min postinjury and similarly at 12-h intervals for 14 days. In animals evaluated daily for 14 days, IGF-1 treatment attenuated motor dysfunction over the 2-week period (P < 0.02). In Study 2, IGF-1 (4 mg/kg/day, n = 8 uninjured, n = 13 injured) or vehicle (n = 8 uninjured, n = 13 injured) was administered for 2 weeks via a subcutaneous pump implanted 15 min postinjury. IGF-1 administration was associated with increased body weight and mild, transient hypoglycemia which was more pronounced in brain-injured animals. At 2 weeks postinjury (P < 0.05), but not at 48 h or 1 week, brain-injured animals receiving IGF-1 showed improved neuromotor function compared with those receiving vehicle. IGF-1 administration also enhanced learning ability (P < 0.03) and memory retention (P < 0.01) in brain-injured animals at 2 weeks postinjury. Taken together, these data suggest that chronic, posttraumatic administration of the trophic factor IGF-1 may be efficacious in ameliorating neurobehavioral dysfunction associated with traumatic brain injury.

Aggregates of a beta-amyloid peptide are required to induce calcium currents in neuron-like human teratocarcinoma cells: relation to Alzheimer's disease.

We report that human hNT cells display neuron-like calcium channel activation. Patch-clamp experiments show that exposure of hNT cells to the Alzheimer-related amyloid peptide beta AP(25-35) induces large and irreversible inward calcium currents at -80 mV in whole cell mode, with a linear current-voltage relationship. This behavior is suggestive of ionophore formation. An analogous peptide with scrambled sequence has no effect. These ionophore effects by the beta AP(25-35) peptide, the first report in a human cell-line, are very rapid effects. The currents are large and stable, and are blocked by Al3+ but not by Cd2+. Filtration removes a peptide aggregate from the amyloid peptide beta AP(25-35) solution and thereby abolishes the inward current. The residual soluble peptide has no effect. These data suggest that the initial step of the neurotoxic effect of beta AP(25-35) may be due to the insertion of the aggregated peptide into the cellular membrane as a Ca2(+)-carrying ionophore. The relevance of calcium-mediated cell death, especially in Alzheimer's disease, is discussed.