Do in vitro assays in rat primary neurons predict drug-induced seizure liability in humans?

Drug-induced seizures contribute to the high attrition rate of pharmaceutical compounds in development. The assessment of drug-induced seizure liability generally occurs in later phases of development using low throughput and intensive in vivo assays. In the present study, we evaluated the potential of an in vitro assay for detecting drug-induced seizure risk compared to evaluation in rats in vivo. We investigated the effects of 8 reference drugs with a known seizurogenic risk using micro-electrode array (MEA) recordings from freshly-dissociated rat primary neurons cultured on 48-well dishes for 28 days, compared to their effects on the EEG in anesthetized rats. In addition, we evaluated functional responses and mRNA expression levels of different receptors in vitro to understand the potential mechanisms of drug-induced seizure risk. Combining the functional MEA in vitro data with concomitant gene expression allowed us to identify several potential molecular targets that might explain the drug-induced seizures occurring in both rats and humans. Our data 1) demonstrate the utility of a group of MEA parameters for detecting potential drug-induced seizure risk in vitro; 2) suggest that an in vitro MEA assay with rat primary neurons may have advantages over an in vivo rat model; and 3) identify potential mechanisms for the discordance between rat assays and human seizure risk for certain seizurogenic drugs.

EEG in the FEAB model: measurement of electroencephalographical burst suppression and seizure liability in safety pharmacology.

INTRODUCTION: The purpose of this study was to explore the integration of electroencephalographical (EEG) measurements into the fentanyl/etomidate-anaesthetised Beagle (FEAB) model in order to detect burst suppression and/or seizure development caused by compounds, prior to new molecular entity (NME) declaration. Detecting such unfavourable side effects prevents their being found in conscious animals at a later stage of safety evaluation. In addition, this has the advantage of performing safety studies on the three vital organ systems (cardiovascular system, respiratory system and central nervous system) within one and the same animal model. METHODS: Dogs were anaesthetized and instrumented according to the FEAB model requirements, and in addition three needle electrodes were placed on the cranium and a one lead EEG signal was measured. The raw signal was analysed by the Narcotrend® (MonitorTechnik, Bad Bramstedt, Germany) for depth of anaesthesia registration, visually analysed for burst suppression ratio calculation after different anaesthetics (pentobarbital and etomidate), and spiking and seizure activity were quantified after intravenous administration of different proconvulsant agents: pentylenetetrazole (PTZ), bicuculline (BCC), bupropion (BUP) and pilocarpine (PIL). RESULTS: High doses of pentobarbital (60 mg/kg over 10 min) and etomidate (6 mg/kg over 10 min) induced dose-dependent burst suppression of 98 ± 2% and 61 ± 16%, respectively. Infusions of PTZ (1.5mg/kg/min), BCC (0.0625 mg/kg/min), BUP (0.5mg/kg/min) and PIL (5mg/kg/min) induced dose-dependent spiking and seizures: the thresholds were 34 ± 2, 0.15 ± 0.03, 10.0 ± 1 and 144 ± 9 mg/kg, respectively. In PTZ-treated dogs, spiking and seizures could be abolished with diazepam (2mg/kg i.v.) or with propofol (4 mg/kg i.v.). DISCUSSION: The present study showed that a one lead EEG can be used reliably in the FEAB model to estimate the depth of anaesthesia, and to detect burst suppression and seizure risk in safety pharmacology studies.

The Electro-Mechanical window: a risk marker for Torsade de Pointes in a canine model of drug induced arrhythmias.

BACKGROUND AND PURPOSE: In cardiovascular pharmacology, electrical and mechanical events can be distinguished, and the phrase 'electro-mechanical window' (EMw) describes the temporal difference between these events. We studied whether changes in EMw have potential predictive value for the occurrence of arrhythmias in fentanyl/etomidate-anaesthetized beagle (FEAB) dogs. EXPERIMENTAL APPROACH: The EMw was calculated as differences between the QT interval and QLVP(end) in FEAB dogs during atrial pacing, treatment with isoprenaline or atropine, body temperature changes and induction of Torsade de Pointes (TdP) in an LQT1 model. KEY RESULTS: The electrical systole (QT interval) was shorter than the duration of the mechanical event (QLVP(end) ), providing a positive EMw. Atrial pacing, atropine or body temperature changes had no major effects on EMw, despite large changes in QT duration. However, ß-adrenoceptor stimulation (with isoprenaline) decreased the EMw (from 90 to 5 ms) and in combination with HMR1556, a blocker of the slowly activating potassium current (I(Ks) ), induced a large negative EMw (-109ms) and TdP. Prevention of TdP by atenolol or verapamil was associated with a less negative EMw (-23 to -16ms). Mexiletine, a poorly effective long QT treatment, did not affect the EMw or prevent TdP induction. CONCLUSIONS AND IMPLICATIONS: The EMw is a marker, other than QT prolongation, of TdP risk in the FEAB model. Therefore, we suggest examining the EMw as a risk marker in cardiovascular safety studies and as a potential biomarker to improve clinical management of long QT syndrome patients, especially in patients with borderline QT prolongation.

The effect of changes in core body temperature on the QT interval in beagle dogs: a previously ignored phenomenon, with a method for correction.

BACKGROUND AND PURPOSE: Body core temperature (Tc) changes affect the QT interval, but correction for this has not been systematically investigated. It may be important to correct QT intervals for drug-induced changes in Tc. EXPERIMENTAL APPROACH: Anaesthetized beagle dogs were artificially cooled (34.2 degrees C) or warmed (42.1 degrees C). The relationship between corrected QT intervals (QTcV; QT interval corrected according to the Van de Water formula) and Tc was analysed. This relationship was also examined in conscious dogs where Tc was increased by exercise. KEY RESULTS: When QTcV intervals were plotted against changes in Tc, linear correlations were observed in all individual dogs. The slopes did not significantly differ between cooling (-14.85+/-2.08) or heating (-13.12+/-3.46) protocols. We propose a correction formula to compensate for the influence of Tc changes and standardize the QTcV duration to 37.5 degrees C: QTcVcT (QTcV corrected for changes in core temperature)=QTcV-14 (37.5 - Tc). Furthermore, cooled dogs were re-warmed (from 34.2 to 40.0 degrees C) and marked QTcV shortening (-29%) was induced. After Tc correction, using the above formula, this decrease was abolished. In these re-warmed dogs, we observed significant increases in T-wave amplitude and in serum [K(+)] levels. No arrhythmias or increase in pro-arrhythmic biomarkers were observed. In exercising dogs, the above formula completely compensated QTcV for the temperature increase. CONCLUSIONS AND IMPLICATIONS: This study shows the importance of correcting QTcV intervals for changes in Tc, to avoid misleading interpretations of apparent QTcV interval changes. We recommend that all ICH S7A, conscious animal safety studies should routinely measure core body temperature and correct QTcV appropriately, if body temperature and heart rate changes are observed.

A new method to calculate the beat-to-beat instability of QT duration in drug-induced long QT in anesthetized dogs.

INTRODUCTION: Instability of QT duration is a marker to predict Torsade de Pointes (TdP) associated with both congenital and drug-induced long QT syndrome. We describe a new method for the quantification of instability of repolarization. METHODS: Female, adult beagle dogs anesthetized with a potent morphinomimetic were treated with either solvent (n=7) or dofetilide (n=7). Poincaré plots with QT(n) versus QT(n+1) were constructed to visualize the beat-to-beat variation in QT intervals from the lead II ECG. Short-term instability (STI), long-term instability (LTI) and total instability (TI) were quantified by calculating the distances of 30 consecutive data-points from the x and y-coordinate to the "centre of gravity" of the data cluster. Dofetilide at 0.0025 to 0.04 mg/kg i.v. (plasma concentrations of 4+/-0.6 to 41+/-2.7 ng/ml), dose-dependently prolonged QT and QTcV (at 0.04 mg/kg i.v.: QT: 280+/-ms versus 236+/-5 ms with solvent; p<0.05 and QTcV: 290+/-9 ms versus 252+/-4 ms with solvent; p<0.05). Concomitantly, the compound induced an increase in the instability parameters in a similar dose-dependent manner (at 0.04 mg/kg i.v.: TI: 6.8+/-0.9 ms versus 1.7+/-0.3 ms; p<0.05, LTI: 3.6+/-0.5 ms versus 1.0+/-0.2 ms; p<0.05 and STI: 4.2+/-0.6 ms versus 1.0+/-0.2 ms; p<0.05). The increases induced by dofetilide were associated with a high incidence of early afterdepolarizations (EADs) in the endocardial monophasic action potential (in 6 out of the 7 compound-treated animals versus 0 out of the 7 solvent animals; p<0.05). CONCLUSION: Quantification of beat-to-beat QT instability by our method clearly detects changes in short-term, long-term and total instability induced by dofetilide, already at pre-arrhythmic doses. Dofetilide administration to anesthetized dogs prolongs ventricular repolarization, concomitantly increases beat-to-beat QT instability and induces early after depolarizations (EADs). As such, the use of these parameters in this in vivo model shows clear potential for risk identification in cardiovascular safety assessment.

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.

Intracranial pressure in a modified experimental model of closed head injury.

Intracranial pressure (ICP) was studied in a modified experimental model of closed head injury, in which the dynamic process of impact versus impulse loading was separately controlled. In this model, mortality of Wistar rats was considerably higher as compared to Sprague-Dawley rats subjected to similar traumatic conditions. Therefore Sprague-Dawley rats were used for all further experiments. Twenty-four rats, divided into 4 groups, underwent either sham or gradually increasing impact-acceleration trauma. Four hours after closed head injury, ICP measurements showed a significant correlation between the severity of the traumatic challenge and the resultant pressure rise (r2 = 0.731; p < 0.001). At the moment of impact there was a momentary blood pressure peak immediately followed by a transient period of hypotension. ICP measurements following directly to an impact-acceleration trauma, revealed an abrupt rise in ICP reaching pathological levels within 5 minutes. In conclusion, this modified model of closed head injury produces a predictable and reproducible pathologic ICP in Sprague-Dawley rats.

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)

Photochemically-induced cerebral infarction in the rat: comparison of NMR imaging and histologic changes.

The evolution of a photochemically induced cerebral thrombotic infarction was followed in rats during the first week after the insult by means of NMR imaging and histology. Heavily T2-weighted images provided an excellent lesion detection and a high specificity for the discrimination of different histological abnormalities. The T2-weighted images showed a brain lesion evolving during the first 24 h from a homogeneous hyperintense area, histologically corresponding to diffuse vasogenic and cytotoxic oedema with concomitant neuronal necrosis, to an iso-intense area with a hyperintense seam, which microscopically correlated with increased vascular permeability at the periphery of the lesion. The hyperintense seam was observed up to day 7, but at that time coincided with gliomesodermal repair reaction which could be verified histochemically and ultrastructurally. It may be concluded that NMR-micro-imaging at a moderately high field, enables early detection and adequate follow-up of small cerebral infarctions in rats.

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.

Microwave-enhanced silver staining of degenerating neuronal processes.

A simple and rapid method for light and electron microscopic visualization of degenerating neuronal processes and axon terminals is described. Hundred-micrometer vibratome sections of perfusion-fixed rat brain were incubated briefly in a 5% silver nitrate solution in a conventional microwave oven. After a rinse in 1% acetic acid, the sections were silver enhanced. Differentiation and counterstaining was done respectively in ethanol 100% and cresyl violet. In the light microscope, degenerating neuronal processes appeared as black dots against a clear background. Areas of calcification were also positively stained. The presence of silver deposits in degenerating presynaptic terminals and dendrites was confirmed ultrastructurally.

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.

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.

Flunarizine reduces cerebral infarct size after photochemically induced thrombosis in spontaneously hypertensive rats.

The cerebroprotective effect of flunarizine was studied in a minimally invasive model of photochemically induced cerebral infarction in spontaneously hypertensive rats. Intravenous administration of the photosensitizing dye rose bengal and intense focal illumination of the brain produced a deep cortical infarction that resulted from singlet oxygen-induced peroxidative injury to the endothelial membrane, subsequent platelet adhesion, and eventual thrombus formation. The infarct size was calculated from area measurements on consecutive histologic sections prepared from the brain cortex 4 hours after the onset of the insult. Oral treatment with 40 mg/kg flunarizine 3 hours before photoexcitation resulted in a significant reduction of the median infarct size from 11.75 mm3 in the untreated group to 6.40 mm3 in the treated group (n = 13, p less than 0.001). At this dose, flunarizine had no effect on systemic blood pressure. In a separate experiment the area of thrombotic obstruction was quantified 30 minutes after the onset of light exposure. Flunarizine did not significantly reduce early thrombus formation (2.28 mm3 in the untreated and 1.78 mm3 in the treated group) (n = 12, p = 0.2). The infarcted area at 4 hours was considerably larger than the initial thrombotic area. Protection with flunarizine against development of cortical infarction has been unequivocally shown. Although some effect may already be present at the early stage of lesion formation, the major protective action admittedly occurred in the later postinsult period when the lesion was expanding.(ABSTRACT TRUNCATED AT 250 WORDS)