Bruno Van Deuren

Neocortical localization of tactile/proprioceptive limb placing reactions in the rat

The present study was aimed at delineating the neocortical substrate of tactile/proprioceptive limb placing reactions in rats by means of behavioral tests that excluded the participation of facial stimuli in limb function. Using a photochemical technique, we made unilateral focal lesions in the frontal and parietal neocortex. Fore- and/or hindlimb placing deficits resulted from damage to a fronto-parietal region lying between the medial agranular cortex and the primary somatosensory (whisker barrel field) cortex. When the antero-posterior coordinate was varied from 4 mm anterior to 1 mm posterior to bregma, tactile/proprioceptive forelimb dysfunction was more pronounced after damage to the parietal forelimb area, but lesions confined to the frontal lateral agranular cortex also yielded clear-cut forelimb placing deficits. Damage to either area alone allowed for partial recovery of forelimb function. However, following combined, total destruction of both frontal and parietal forelimb areas, forelimb deficits did not recover. This resembled the irreversible hindlimb deficits after near-total destruction of the parietal hindlimb area. Damage to the medial agranular cortex left limb placing intact. Likewise, for as long as the medial edge of lesions to the whisker barrel field did not come closer than 3 mm to the midline, thus remaining outside the parietal hindlimb area, limb placing remained normal. This sharp medial and lateral delineation of the cortical substrate subserving tactile/proprioceptive limb placing coincides with the borders of a thick, dense subfield of large pyramidal neurons in the deeper parts of layer V. Limb placing remained intact when medial agranular cortex lesions damaged only 30% of that subfield, whereas 70% destruction of that layer following more laterally placed lesions in the parietal hindlimb area produced irreversible hindlimb dysfunction. The severity of hindlimb placing deficits was related to the amount of incursion by whisker barrel field lesions into the subfield of deep layer V large pyramidal neurons. Finally, very large lesions of the occipital cortex did not affect tactile/proprioceptive limb placing. We discuss the neocortical areal and laminar specificity of tactile/proprioceptive limb function in the context of recent neuroanatomical and electrophysiological findings, and their relevance to normal cortical function, recovery from neocortical stroke (including diaschisis), and age-related cortical dysfunction.

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.

A New Model of Photochemically Induced Acute and Reversible Demyelination in the Peripheral Nervous System

Acute photochemical demyelination accompanied by minor axonal degeneration was produced in rat sciatic nerve after topical application of the photosensitive dye Rose Bengal and focal illumination with cold light. Animals were sacrificed at different time periods after challenge and the exposed nerves prepared for light microscopic and ultrastructural evaluation. Important structural changes were already observed at 4-6 h. These included endoneurial swelling, diapedesis of neutrophils and monocytes, vacuolization and vesicularization of Schwann cell cytoplasm, lamellar separation of myelin sheaths, disintegration of axonal microtubules, and accumulation of vesicular material and mitochondria in the axoplasm. Disrupted myelin fragments were phagocytosed by macrophages which penetrated Schwann tubes at Day 3. Schwann cells proliferated and started to enwrap denuded segments of the axon. They were surrounded by redundant basal lamina, thrown into deep folds. Axons remained partly hypertrophic and contained many neurofilaments. A minority showed signs of degeneration. At Days 5-7 denudation was almost complete in the light-exposed nerve area but also in small distal nerve fascicles. After 1 month, axons in the illuminated area and distal to it were completely remyelinated although they had thinner sheaths. Exposure to increased light intensity resulted in deeper lesions and more extended anterograde damage, which also recovered within 1 month. All animals showed rapid functional deterioration which correlated with the severity and extent of structural damage. Recovery was slow and also depended on the degree of histologic damage. Neither control nerves nor sham-exposed nerves revealed signs of structural or functional changes.(ABSTRACT TRUNCATED AT 250 WORDS)

Ultrasound agents may open the blood-brain barrier in rats and aggravate pathologic consequences of experimental head trauma.

Unilateral intracarotid injection of contrast agents may considerably destabilize the blood–brain barrier in rats. This leads to vasogenic edema in the ipsilateral hemisphere. Mortality and extravasation increased significantly when administration of these ultrasound contrast agents was followed by mild traumatic brain injury. Direct administration to the cerebral circulation is, therefore, indicative for edema‐related pathology and may amplify the consequences of experimental neurotrauma.

Characterization of an anesthetized dog model of transient cardiac ischemia and rapid pacing: a pilot study for preclinical assessment of the potential for proarrhythmic risk of novel drug candidates.

INTRODUCTION Preclinical proarrhythmic risk assessment of drug candidates is focused predominantly on arrhythmias arising from repolarization abnormalities. However, drug-induced cardiac conduction slowing is associated with significant risk of life-threatening ventricular arrhythmias, particularly in a setting of cardiac ischemia. Therefore, we optimized and characterized an anesthetized dog model to evaluate the potential proarrhythmic risk of drug candidates in ischemic heart disease patients. METHODS Anesthetized dogs were instrumented with atrial and ventricular epicardial electrodes for pacing and measurement of conduction times, and a balloon occluder and flow probe placed around the left anterior descending coronary artery (LAD) distal to the first branch. Conduction times, ECG intervals and incidence of arrhythmias were assessed serially at the end of each dose infusion (flecainide: 0.32, 0.63, 1.25, 2.5 and 5mg/kg, i.v.; dofetilide:1.25, 2.5, 5, 10 and 20 μg/kg, i.v.; or vehicle; n=6/group) both during normal flow (with and without rapid pacing) and during 5-min LAD occlusion (with and without rapid pacing). Compound X, a development candidate with mild conduction slowing activity, was also evaluated. RESULTS Flecainide produced pronounced, dose-dependent slowing of conduction that was exacerbated during ischemia and rapid pacing. In addition, ventricular tachycardia (VT) and fibrillation (VF) occurred in 4 of 6 dogs (3 VF @ 0.63 mg/kg; 1VT @ 2.5mg/kg). In contrast, no animals in the vehicle group developed arrhythmias. Dofetilide, a potent IKr blocker that does not slow conduction, prolonged QT interval but did not cause further conduction slowing during ischemia with or without pacing and there were no arrhythmias. Compound X, like flecainide, produced marked conduction slowing and arrhythmias (VT, VF) during ischemia and pacing. DISCUSSION This model may be useful to more accurately define shifts in safety margins in a setting of ischemia and increased cardiac demand for drugs that slow conduction.

Temporal changes in intracranial pressure in a modified experimental model of closed head injury

OBJECT The authors describe an experimental model of closed head injury in rodents that was modified from one developed by Marmarou and colleagues. This modification allows dual control of the dynamic process of impact compared with impulse loading that occurs at the moment of primary brain injury. The principal element in this weight-drop model is an adjustable table that supports the rat at the moment of impact from weights positioned at different heights (accelerations). The aim was to obtain reproducible pathological intracranial pressure (ICPs) while maximally reducing the incidence of mortality and skull fractures. METHODS Intracranial pressure was investigated in different experimental settings, including two different rat strains and various impact-acceleration conditions and posttrauma survival times. Identical impact-acceleration injuries produced a considerably higher mortality rate in Wistar rats than in Sprague-Dawley rats (50% and 0%, respectively). Gradually increasing severity of impact-acceleration conditions resulted in findings of a significant correlation between the degree of traumatic challenge and increased ICP at 4 hours (p < 0.001, R2=0.73). When the impact-acceleration ratio was changed to result in a more severe head injury, the ICP at 4, 24, and 72 hours was significantly elevated in comparison with that seen in sham-injured rats (4 hours: 19.7+/-2.8 mm Hg, p=0.004; 24 hours: 21.8+/-1.1 mm Hg, p=0.002; 72 hours: 11.9+/-2.5 mm Hg, p=0.009). Comparison of the rise in ICP between moderate and severe impact-acceleration injury at 4 and 24 hours revealed a significantly higher value after severe injury (4 hours: p=0.008; 24 hours: p=0.004). Continuous recordings showed that ICP mounted very rapidly to peak values, which declined gradually toward a pathological level dependent on the severity of the primary insult. Histological examination after severe trauma revealed evidence of irreversible neuronal necrosis, diffuse axonal injury, petechial bleeding, glial swelling, and perivascular edema. CONCLUSIONS This modified closed head injury model mimics several clinical features of traumatic injury and produces reliable, predictable, and reproducible ICP elevations with concomitant morphological alterations.