Marc Haseldonckx

Impaired autoregulation of cerebral blood flow in an experimental model of traumatic brain injury.

In order to study the pathophysiology and the intracranial hemodynamics of traumatic brain injury, we have developed a modified closed-head injury model of impact-acceleration that expresses several features of severe head injury in humans, including acute and long-lasting intracranial hypertension, diffuse axonal injury, neuronal necrosis, bleeding, and edema. In view of the clinical relevance of impaired autoregulation of cerebral blood flow after traumatic brain injury, and aiming at further characterization of the model, we investigated the autoregulation efficiency 24 h after experimental closed-head injury. Cortical blood flow was continuously monitored with a laser-Doppler flowmeter, and the mean arterial blood pressure was progressively decreased by controlled hemorrhage. Relative laser-Doppler flow was plotted against the corresponding mean arterial blood pressure, and a two-line segmented model was applied to determine the break point and slopes of the autoregulation curves. The slope of the curve at the right hand of the break point was significantly increased in the closed head injury group (0.751 +/- 0.966%/mm Hg versus -0.104 +/- 0.425%/mm Hg,p = 0.028). The break point tended towards higher values in the closed head injury group (62.2 +/- 20.8 mm Hg versus 46.9 +/- 12.7 mm Hg; mean +/- SD, p = 0.198). It is concluded that cerebral autoregulation in this modified closed head injury model is impaired 24 h after traumatic brain injury. This finding, in addition to other characteristic features of severe head injury established earlier in this model, significantly contributes to its clinical relevance.

Dorsal-ventral gradient in vulnerability of CA1 hippocampus to ischemia: a combined histological and electrophysiological study.

Transverse hippocampal slices were prepared after 7 days survival from rats subjected to 8 min of global incomplete ischemia by temporary occlusion of both carotid arteries and hypotension. The slices demonstrated a dorsal-ventral gradient in the amount of ischemic neuronal necrosis in the CA1 region. Histologically ischemic cell change decreased from 90% dorsoseptally to 10% ventrotemporally. Electrophysiological analysis of the number of slices with viable synaptic transmission in CA1 also revealed a septotemporal gradient in susceptibility to ischemia.

Protection With Lubeluzole Against Delayed Ischemic Brain Damage in Rats: A Quantitative Histopathologic Study

BACKGROUND AND PURPOSE Cerebral ischemia may lead to glutamate-induced excitotoxic damage in vulnerable brain areas. Lubeluzole is not an N-methyl-D-aspartate antagonist but prevents postischemic increase in extracellular glutamate concentrations. The present study examined whether lubeluzole, administered after global incomplete ischemia in rats, is capable of preserving the structural integrity of CA1 hippocampus. METHODS Ischemia was induced by bilateral carotid artery occlusion and severe hypotension for a duration of 9 minutes. Delayed neuronal cell death was histologically evaluated 7 days later. This was done by scoring acidophilic cell change and coagulative necrosis and by counting the number of surviving neurons in the CA1 subfield. Experiments were performed according to a paired design (13 animals per treatment group). RESULTS Posttreatment with lubeluzole (0.31 mg/kg i.v. bolus at 5 minutes and 0.31 mg/kg i.v. infusion during 1 hour) resulted in significant neuroprotection. Whereas in the untreated rats there were 42 (median) viable neurons per millimeter CA1 layer in the left and 69 in the right hemisphere, in the drug-treated rats 99 viable neurons per millimeter were found in the left (P = .002) and 113 in the right hemisphere (P = .013). Histological scores, reflecting altered staining properties of the hippocampal cells, correlated strongly with the quantitative data, reflecting the structural integrity of CA1 pyramidal neurons. CONCLUSIONS Lubeluzole, when administered after an ischemic insult in rats, protects vulnerable brain regions against delayed structural injury. The results support the potential clinical use of this new drug in stroke treatment.

The course of vasospasm following subarachnoid haemorrhage in rats. A vertebrobasilar angiographic study.

SummaryThe course of vasospasm following subarachnoid haemorrhage in rats was studied using vertebrobasilar angiography. Wistar and Sprague Dawley rats were compared with respect to vasospastic response after bleeding. A more pronounced vasospasm was found in Sprague Dawley rats. In order to avoid a possible toxic effect on the contrast medium, only one angiogram per animal was initially performed. However, a comparison with the results obtained in a separate series of non-challenged animals demonstrated a difficulty due to high variability in basilar artery size in the latter group. Therefore, vasospasm can be more readily shown if multiple angiograms are used in the same animal so that the vasospasm can be expressed as a percentage of the initial diameter of the basilar artery. It was found that multiple angiograms are well tolerated when nonionic contrast media are used.

Fiberoptic intracranial pressure monitoring in rats

An adaptation of a fiberoptic intracranial pressure monitoring system for clinical use is described. The method allows easy and reliable acute and chronic intracranial pressure registration in anesthetized as well as conscious rats. The disposable fiberoptic probes, originally designed for human use, can be re-used limitlessly. The fiberoptic method is compared with conventional monitoring procedures under different experimental conditions. The validity of intraparenchymal and epidural measurements is discussed. The importance of chronic intracranial pressure registration in conscious laboratory animals is stressed.

Purine nucleoside phosphorylase: a histochemical marker for glial cells

The distribution of purine nucleoside phosphorylase activity has been investigated histochemically in rat and guinea-pig brain. At the light microscopical level, enzyme activity was most pronounced in glial cells in various anatomical regions of the rat brain. In contrast, the guinea-pig brain presented only a weak activity. Endothelial cells of both species were also reactive. These findings were confirmed by electron microscopy. Based upon anatomical position and morphologic characteristics, positive glial cells were identified as astrocytes. Precipitate-rich astrocytic processes could be easily demonstrated in between barely reactive neuronal fibers and around microvessels. A minority of astrocytes was devoid of reaction product. The present method may offer a valuable tool for the histopathological study of several types of disorders in which glial cells play a functional role.

Haemodynamic, intracranial pressure and electrocardiographic changes following subarachnoid haemorrhage in rats

SummaryExperimental induction of subarachnoid haemorrhage in rats resulted in acute haemodynamic changes. Heart rate decreased concomitantly with a rise in arterial blood pressure. Intracranial pressure increased and consequently cerebral perfusion pressure dropped. These changes as well as the observed electrocardiographic (ECG) changes were comparable to those reported in patients. Apart from blood also saline, when introduced into the cisterna magna, was able to elicit such abnormalities. The haemodynamic and electrocardiographic changes, which result from subarachnoid haemorrhage, may even become aggravated, when repetitive injections of blood or saline are given into the cisterna magna and when cerebral angiography is performed prior to induction of the subarachnoid haemorrhage. Chronic intracranial pressure monitoring during the 48 hours following subarachnoid haemorrhage revealed no significant rise in pressure.A thorough control of the experimental conditions is thus of utmost importance in order to give a valid interpretation of the observed anomalies.

Cerebroprotective effects of flunarizine in an experimental rat model of cardiac arrest

A rat cardiopulmonary arrest model was used to study the effects of flunarizine on survival and on the development of postischemic brain damage. Ischemia was induced by a combination of hypovolemia and intracardiac injection of a cold potassiumchloride solution. To validate the model; survival rate and histological damage were assessed after ischemic periods ranging from 5 to 20 minutes. A 6-minute cardiac arrest period was withheld for further therapeutic investigations. In one group (n = 12), flunarizine was administered successively in doses of 0.5 mg/kg intravenous at 5 minutes, 10 mg/kg intraperitoneal at 1 hour, and 20 mg/kg orally at 16 and 24 hours after recirculation. The second group (n = 13) received only the vehicle. Flunarizine, although not affecting mortality; significantly reduced the mean number of ischemic neurons in CA1 hippocampus from 83% in the control to 44% in the drug-treated series (P = 0.014). The results are indicative of the usefulness of this cardiac arrest model to study morphologic aspects of cerebral injury. The results obtained with flunarizine show the effectiveness of this drug even when it is administered after a severe ischemic insult such as global complete ischemia.

Favourable effect of flunarizine on the recovery from hemiparesis in rats with intracerebral hematomas.

In 25 rats, an intracerebral hematoma was created in the foreleg area of the motor cortex by injection of 50 microliters blood. After the lesion, 13 were treated with flunarizine and 12 with the solvent. Neurological testing was performed by measuring the running time on a rotating platform. In animals with hemiparesis, the flunarizine group (n = 7) showed a significantly (P less than 0.05) better recovery than the control group (n = 8). No significant differences occurred in animals without neurological deficits (flunarizine: n = 6, control: n = 4). So the effect of the drug is not due to a non-specific activation; it may partially cure neurological deficits caused by intracerebral hematoma.