Cyclosporin A and Brain Excitability Studied In Vitro

Summary: Purpose: Seizures are frequently observed after organ transplantations. This has been attributed to a direct effect of cyclosporin A (CsA) on the brain, although other mechanisms may also be of importance. The aim of this study was to investigate possible acute and direct effects of CsA on neuronal excitability.
Methods: Female rat hippocampal slices were perfused with CsA solutions containing 400 (n = 4), 1,000 (n = 4), 2,000 (n = 6), 8,000 (n = 8) μg/L CsA or control (n = 8) for 30 min, or penicillin, 2,000 IE/ml (n = 7). Actual concentrations of CsA were measured in the perfusate drawn from the slice chamber. To study CsA accumulation in the slices, uptake of radioactive CsA was measured in 12 living and 11 dead slices.
Results: Despite a significant accumulation of CsA in the living neuronal slices, no effects were observed on prevolley, field excitatory postsynaptic potential (EPSP), or population spike amplitude. Penicillin, however, led to epileptiform activity within 10 min in all cases. Concentrations of CsA in the perfusate from the slice chamber were about half the calculated levels, demonstrating that the slices had been exposed to actual CsA concentrations in the range of ε200–4,000 μg/L CsA.
Conclusions: Our results demonstrate a lack of acute effects of CsA on neuronal excitability within clinically relevant concentrations despite an active accumulation of the drug in the slices. Long-term effects on brain tissue, indirect metabolic effects, or synergistic effects may be responsible for the neurotoxicity of the drug.     

Kainic acid and penicillin: Differential effects on excitatory and inhibitory interactions in the CA1 region of the hippocampal slice

The effects of kainic acid (KA, 0.05-1.0 microM), and penicillin (PN, 3.4 mM) were studied in the CA1 region of rat hippocampal slices. Three components of the overall input/output function were taken: (1) the amplitude of the presynaptic compound action potential (prevolley) vs stimulation current applied to Schaffer collaterals, (2) the magnitude of the focally recorded synaptic potential (population EPSP) vs prevolley amplitude; and (3) the amplitude of the focally recorded population spike vs population EPSP magnitude. Recurrent inhibition was measured using the antidromic-orthodromic paired pulse method. KA caused a significant and reversible enhancement of all 3 component input/output functions while having no effect on paired pulse inhibition. PN caused a left shift in the EPSP-population spike relationship and decreased or abolished paired pulse inhibition; the other two measures of excitability were not changed. These results suggest that PN and KA differ fundamentally in the mechanisms by which they produce seizures: PN by removing inhibition while not affecting neuronal excitability per se; KA by exerting a generalized excitatory effect on neural membranes and on synaptic function while leaving recurrent inhibition unchanged.     

Perfusion with lithium modifies neurophysiological responses in the CA1 region of the hippocampal slice preparation

The effects of acute lithium exposure on extracellular electrophysiological responses in the CA1 region of the in vitro hippocampus were investigated. Field potentials were assessed while perfusing slices with normal media or media in which LiCl was substituted for NaCl in 30, 20, 10 and 2 mM amounts. Lithium concentration in the slice following 20 min perfusion with 20 mM lithium was determined to be about 14 mM. At the higher concentrations, lithium exposure depressed the presynaptic fiber volley and antidromic population spike. On the other hand, the population EPSP and orthodromic population spike were enhanced. No significant changes were found at 2 mM. The findings are compatible with one action of lithium being on the excitability of axons and synaptic terminals. Comparisons were drawn between previous studies involving chronic lithium exposure and the present results. In this acute preparation lithium effects, as reflected in the population EPSP, were in opposition to those found with chronic lithium exposure. Changes demonstrated in this preparation in fiber volley and antidromic population spike paralleled those found with chronic lithium exposure.     

Footshock treatment activates catecholamine synthesis in slices of mouse brain regions

Synthesis of catecholamines was measured in slices of frontal cortex, hypothalamus, striatum, hippocampus and brainstem by the accumulation of [³H]norepinephrine (NE) and [³H]dopamine (DA) following incubation with [³H]tyrosine.Following acute footshock (60 shocks, 0.3 mA 30 min), consistent increases in [³H]DA accumulation were seen in frontal cortex slices, but no significant effect was seen in striatal slices. The accumulation of [³H]NE was not altered consistently in frontal cortex, hypothalamus, hippocampus or brainstem. Brain slices from mice adrenalectomized 24–48 h before footshock showed similar results. However, in hypophysectomized mice, footshock did not increase the [³H]DA accumulation in slices of frontal cortex. Administration of dexamethasone before footshock prevented the footshock-induced increase in frontal cortex [³H]DA accumulation, but footshock then significantly increased [³H]NE accumulation in the hypothalamus and brainstem. Chronic footshock (5 days) had little effect on frontal cortex [³H]catecholamine accumulation but produced a consistent elevation of [³H]NE accumulation in slices from the hypothalamus.In confirmation that the slices data reflected in vivo metabolism, both dihydroxyphenylacetic acid and homovanillic acid were significantly elevated in the frontal cortex but not the striatum of mice receiving acute footshock.Since previous studies have shown that ACTH administered intracerebroventricularly also accelerated [³H]DA accumulation in frontal cortex slices, these results are consistent with the involvement of ACTH in the effects of footshock on frontal cortex DA. The effects of chronic footshock are consistent with the activation of hypothalamic tyrosine hydroxylase by corticosterone.     

Effects of low intensity radiofrequency electromagnetic fields on electrical activity in rat hippocampal slices

Slices of rat hippocampus were exposed to 700 MHz continuous wave radiofrequency (RF) fields (25.2-71.0 V m(-1), 5-15 min exposure) in a stripline waveguide. At low field intensities, the predominant effect on the electrically evoked field potential in CA1 was a potentiation of the amplitude of the population spike by up to 20%, but higher intensity fields could produce either increases or decreases of up to 120 and 80%, respectively, in the amplitude of the population spike. To eliminate the possibility of RF-induced artefacts due to the metal stimulating electrode, the effect of RF exposure on spontaneous epileptiform activity induced in CA3 by 4-aminopyridine (50-100 microM) was investigated. Exposure to RF fields (50.0 V m(-1)) reduced or abolished epileptiform bursting in 36% of slices tested. The maximum field intensity used in these experiments, 71.0 V m(-1), was calculated to produce a specific absorption rate (SAR) of between 0.0016 and 0.0044 W kg(-1) in the slices. Measurements with a Luxtron fibreoptic probe confirmed that there was no detectable temperature change (+/- 0.1 degrees C) during a 15 min exposure to this field intensity. Furthermore, imposed temperature changes of up to 1 degrees C failed to mimic the effects of RF exposure. These results suggest that low-intensity RF fields can modulate the excitability of hippocampal tissue in vitro in the absence of gross thermal effects. The changes in excitability may be consistent with reported behavioural effects of RF fields.     

Visual deprivation increases capability of layer II/III for epileptiform activity in the rat visual cortical slices

Effects of visual deprivation on the induction of epileptiform activity were studied in layer II/III of 29-39-day-old rat primary visual cortex. Field potentials were evoked by stimulation of layer IV in slices from control (CON) and dark-reared (DR) rats. Picrotoxin (PTX)-induced epileptiform activity was characterized by spontaneous and evoked epileptic field potentials (EFPs). The results showed that DR slices demonstrate greater susceptibility for induction of spontaneous EFP. PTX-induced changes in the characteristics of evoked field potentials also showed higher tendency of DR animals to generate epileptiform activity. In both groups, field potentials consisted of pEPSP(1) (population excitatory postsynaptic potential 1, i.e., first negativity) and pEPSP(2) (second negativity), respectively. There was no significant difference between the characteristics of field potentials in CON and DR slices. PTX significantly increased amplitude and duration of pEPSP(2), but it had no significant effect on pEPSP(1). Effects of PTX on pEPSP(2) were significantly higher in DR slices. It is concluded that visual deprivation results in a heightened potential in layer II/III of the rat visual cortex to generate PTX-induced epileptiform activity.     

Noradrenergic responses in rat hippocampus: evidence for medication by alpha and beta receptors in the in vitro slice

The effect of perfused norepinephrine (NE) on evoked potentials in CA1 of the in vitro rat hippocampus was examined. Weak and variable effects on population spike amplitude were observed, with lower doses of NE generally producing excitations and higher doses more often producing inhibitions. Clonidine, an alpha-receptor agonist, produced a dose-dependent inhibition of population spike amplitude; this inhibition was effectively antagonized by the alpha-antagonist, phentolamine. Isoproterenol (ISO), a beta-agonist, produced marked increases in population spike amplitude which could be antagonized by timolol, a beta-receptor antagonist. Phentolamine did not antagonize the excitations produced by ISO, and timolol had no effect on the inhibitions seen with clonidine. After pretreatment with either phentolamine or timolol, NE perfusion elicited robust and consistent elevations or reductions in the population spike, respectively. A potent cyclic AMP derivative, 8-p-chlorophenylthio cyclic AMP, produced large increases in population spike amplitude which appeared similar to the responses seen with beta-agonists. No changes in field EPSP amplitudes were observed with any of the drugs tested. Taken together, these results suggest that NE may interact with alpha-adrenergic receptors to decrease pyramidal cell excitability, and the beta-adrenergic receptors to increase pyramidal cell excitability; the beta-effect may involve cAMP.     

Cyclic AMP accumulation in cerebral cortical slices: effect of carbamazepine, phenobarbital, and phenytoin.

Recent investigations have suggested that abnormal increases in brain cyclic 3',5'-adenosine monophosphate (cAMP) may play a role in epileptogenesis. Therefore, the effect of three commonly used antiepileptic drugs on cAMP accumulation in rat cortex slices was investigated. Ouabain, a depolarizing agent which produces seizures when applied to rat cortex, produced a five- to sevenfold increase in cAMP accumulation, and both carbamazepine and and phenytoin inhibited this increase. Ouabain stimulation may be mediated by the release of endogenous adenosine, and carbamazepine antagonized adenosine stimulation of cAMP accumulation whereas phenytoin did not. Carbamazepine had no effect on adenosine efflux. The augmentation of cAMP accumulation by norepinephrine was inhibited by carbamazepine and phenobarbital but slightly increased by phenytoin. If increases in brain cAMP are involved in epileptogenesis, the antagonism of cAMP accumulation by antiepileptic drugs may play a role in their anticonvulsant action.     

Noradrenergic responses in rat hippocampus: Evidence for mediation by α and β receptors in the in vitro slice

The effect of perfused norepinephrine (NE) on evoked potentials in CA1 of the in vitro rat hippocampus was examined. Weak and variable effects on population spike amplitude were observed, with lower doses of NE generally producing excitations and higher doses more often producing inhibitions. Clonidine, an α-receptor agonist, produced a dose-dependent inhibition of population spike amplitude; this inhibition was effectively antagonized by the α-antagonist, phentolamine. Isoproterenol (ISO), a β-agonist, produced marked increases in population spike amplitude which could be antagonized by timolol, a β-receptor antagonist. Phentolamine did not antagonize the excitations produced by ISO, and timolol had no effect on the inhibitions seen with clonidine. After pretreatment with either phentolamine or timolol, NE perfusion elicited robust and consistent elevations or reductions in the population spike, respectively. A potent cyclic AMP derivative, 8-p-chlorophenylthio cyclic AMP, produced large increases in population spike amplitude which appeared similar to the responses seen with β-agonists. No changes in field EPSP amplitudes were observed with any of the drugs tested. Taken together, these results suggest that NE may interact with α-adrenergic receptors to decrease pyramidal cell excitability, and with β-adrenergic receptors to increase pyramidal cell excitability; the β-effect may involve cAMP.     

Serotonin and Carbachol Induced Suppression of Synaptic Excitability in Rat CA1 Hippocampal Area: Effects of Corticosteroid Receptor Activation

Serotonin (5HT) and the cholinergic analogue carbachol (CCh) act on neurons in the hippocampal CA1 area through pre- and post-synaptic receptors. Previously, it was shown that post-synaptic actions of 5HT and CCh are affected by corticosteroids: predominant activation of high affinity mineralocorticoid receptors resulted in small hyperpolarizing responses to 5HT and small depolarizing responses to CCh; additional activation of low affinity glucocorticoid receptors led to increased 5HT and CCh responses. In the present study, we examined the consequences of steroid modulation of these post-synaptic membrane effects and/or possible pre-synaptic effects by 5HT and CCh for the excitability in the CA1 area, using extracellular field potential or intracellular recordings from individual pyramidal neurons. Steroid treatment by itself did not affect the amplitude or paired pulse properties of synaptic responses. In slices from adrenally intact rats, both 5HT (3–30 μM) and CCh (1–10 μM) induced a dose-dependent suppression of the synaptic field responses evoked in the CA1 area by stimulation of the Schaffer collaterals. No changes in these transmitter effects were observed after adrenalectomy. The 5HT induced suppression of the population spike amplitude was, however, reduced after selective occupation of mineralocorticoid receptors. Intracellularly, no significant steroid dependent modulation of (pre-synaptic) 5HT evoked changes in synaptic responses was observed. These data suggest that the steroids modulate post-synaptic but not pre-synaptic 5HT effects and that this modulation is reflected in the excitability of the CA1 region. The CCh induced suppression of the population spike was not affected by corticosteroid receptor activation, indicating that the previously found steroid modulation of post-synaptic CCh effects has no clear consequences for the CA1 excitability.     

Influence of the acute stress on agonist-stimulated phosphoinositide hydrolysis in the rat cerebral cortex.

1. The present study was carried out in order to elucidate the influence of the acute stress on alpha 1-adrenergic, serotonin-2 (5-HT2) and muscarinic cholinergic (M-Ach) receptors-mediated phosphoinositide (PI) hydrolysis in rat cerebral cortex slices. 2. In rat cerebral cortex slices, noradrenaline (NA), serotonin (5-HT) and carbachol stimulated [3H]inositol-monophosphate (IP1) accumulation in a concentration-dependent manner. 3. The forced swimming test (FST) for 15 min induced a significant reduction of 5-HT-stimulated [3H]IP1 accumulation, but this stress situation did not produce a significant alteration of NA- and carbachol-stimulated [3H]IP1 accumulation. 4. The FST for 15 min did not affect the density and affinity of alpha 1-adrenergic, 5-HT2 and M-Ach receptors. 5. In a mild acute stress situation, the intracellular signal transduction mediated by 5-HT was promptly inhibited as compared to the signal transduction mediated by NA or carbachol. This inhibition may be induced by an acute uncoupling of 5-HT2 receptor-mediated intracellular signal transduction.     

Domoic acid-induced hippocampal CA1 hyperexcitability independent of region CA3 activity.

Domoic acid (DOM) is a potent agonist of AMPA and kainic acid (KA) receptors in the CNS and is known to produce seizures acutely, and lasting excitotoxic damage in several brain regions. While the excitotoxic effects of DOM are well documented, its seizurogenic properties are less clear. In this study, we assessed the acute effects of DOM and KA in region CA1 of intact rat hippocampal slices (CA3-on) and in slices lacking region CA3 (CA3-off). Orthodromic Schaffer collateral-evoked CA1 field potentials (population spikes and somal EPSP's) were monitored during DOM and KA (10-500 nM) administration. In CA3-off slices both KA and DOM produced immediate increases in CA1 population spike amplitude. With prolonged exposure, lasting dose-dependent reductions in spike amplitude and EPSP slope were observed, possibly due to depolarising conduction block following excessive AMPA/KA receptor activation; DOM was several-fold more potent than KA in this regard. Population spike threshold did not vary with DOM, but in CA3-on slices a dose-dependent steepening of the I/O curve and increase in maximum spike amplitude was seen. CA1 hyperexcitability, as evidenced by the appearance of prominent second and third population spikes, was equivalently increased across a range of DOM concentrations in both CA3-on and CA3-off slices and, in general, DOM-induced CA1 hyperexcitability was not enhanced by the presence of CA3 for any of the other variables assessed in this study. These findings show that DOM directly promotes neuronal hyperactivity in region CA1, presumably due to tonic AMPA and/or KA-receptor mediated depolarization, and further suggests that DOM-induced hyperactivity in the recurrently networked, AMPA/KA-receptor rich region CA3 does not contribute to the onset and spread of limbic seizures during relatively mild DOM intoxication.     

Effect of morphine on catecholamine - stimulated cyclic AMP production in cortex slices from rats and mice

Morphine (10 micro M) blocked noradrenaline-stimulated cyclic AMP production in slices of cerebral cortex from normal rats but not in slices from rats pretreated with 6-hydroxydopamine (6-OHDA). In contrast, morphine failed to prevent noradrenaline-stimulated cyclic AMP production in mouse cortex slices. Levorphanol weakly antagonized the rise in cyclic AMP produced by noradrenaline in both normal and 6-OHDA-treated mouse cortex. Morphine had no effect on the adrenaline-stimulated cyclic AMP accumulation in mouse cortex but it entirely prevented the rise in cyclic AMP produced by isoprenaline. This effect was no observed in brain slices from 6-OHDA-treated mice. It is concluded that in slices of rat cortex, morphine stimulates postulated presynaptic, 6-OHDA-sensitive, opiate receptors associated with noradrenergic nerve terminals. These opiate receptors alter postsynaptic alpha - and beta - adrenoceptor activity. In the mouse, morphine appears to stimulate presynaptic opiate receptors that modify exclusively beta - adrenoceptor-mediated cyclic AMP production.     

Changes in synaptic efficacy in rat brain slices following extremely low-frequency magnetic field exposure at embryonic and early postnatal age

An earlier study demonstrated changes in synaptic efficacy and seizure susceptibility in adult rat brain slices following extremely low-frequency magnetic field (ELF-MF) exposure. The developing embryonic and early postnatal brain may be even more sensitive to MF exposure. The aim of the present study was to determine the effects of a long-term ELF-MF (0.5 and 3 mT, 50 Hz) exposure on synaptic functions in the developing brain. Rats were treated with chronic exposure to MF during two critical periods of brain development, i.e. in utero during the second gestation week or as newborns for 7 days starting 3 days after birth, respectively. Excitability and plasticity of neocortical and hippocampal areas were tested on brain slices by analyzing extracellular evoked field potentials. We demonstrated that the basic excitability of hippocampal slices (measured as amplitude of population spikes) was increased by both types of treatment (fetal 0.5 mT, newborn 3 mT). Neocortical slices seemed to be responsive mostly to the newborn treatment, the amplitude of excitatory postsynaptic potentials was increased. Fetal ELF-MF exposure significantly inhibited the paired-pulse depression (PPD) and there was a significant decrease in the efficacy of LTP (long-term potentiation induction) in neocortex, but not in hippocampus. On the other hand, neonatal treatment had no significant effect on plasticity phenomena. Results demonstrated that ELF-MF has significant effects on basic neuronal functions and synaptic plasticity in brain slice preparations originating from rats exposed either in fetal or in newborn period.     

Time-dependent changes in cortical excitability after prolonged visual deprivation

Transcranial magnetic stimulation applied to the occipital cortex can elicit phosphenes. Changes in the phosphene threshold provide a measure of visual cortex excitability. Phosphene threshold was measured in participants blindfolded for five consecutive days to assess the effects of prolonged visual deprivation on visual cortical excitability. After 48 h of blindfolding, an acute decrease in phosphene threshold was observed, followed by a significant increase by day 5. Phosphene threshold returned to preblindfold levels within 2 h of light re-exposure. Thus, light deprivation is characterized by a transient increase in visual cortical excitability, followed by a sustained decrease in visual cortex excitability that quickly returns to baseline levels after re-exposure to light.     

The effects of moderate changes of extracellular K+ and Ca2+ on synaptic and neural function in the CA1 region of the hippocampal slice

The effects of moderate changes of the concentration of ions on the function of mammalian central nervous tissue have not exactly been determined. We placed tissue slices from rat hippocampal formation in an interface chamber for study in vitro. Extracellular potentials were recorded in stratum radiatum and stratum pyramidale in response to stimuli of varying intensity applied to the Schaffer collateral bundle. The overall input-output relationship of excitatory synaptic transmission was gauged by expressing postsynaptic population spike amplitude as a function of presynaptic volley amplitude. The components of the transmission process were also examined by plotting the maximal rate of rise (slope) of the focally recorded synaptic potential (fEPSP) as a function of presynaptic volley amplitude, and the population spike amplitude as a function of the fEPSP slope. Raising the concentration of K+ from the normal level of 3.5 mM to 5 mM caused an average increase of 48% in the population spike evoked by a given presynaptic volley. This was due to an increased electrical excitability of pyramidal cells, as indicated by an increase of the population spike evoked by a given magnitude of fEPSP. Conversely, lowering [K+]o from 3.5 to 2 mM caused a decrease of the population spike relative to a given magnitude of either the presynaptic volley or the fEPSP. Changing [K+]o within these limits caused no significant change of the fEPSP evoked by a given presynaptic volley. Raising [Ca2+]o from 1.2 to 1.8 mM caused a 35% increase in both the fEPSP and the population spike evoked by a given presynaptic volley, and lowering [Ca2+]o to 0.8 mM caused a decrease of both these functions. The amplitude of the population spikes evoked by given fEPSPs changed surprisingly little (but consistently) when [Ca2+]o was varied within these limits. We conclude that moderate changes of [K+]o influence mainly the electric excitability of hippocampal pyramidal cells, with little effect on transmitter release or on the response of the postsynaptic membrane to transmitter, while moderate changes of [Ca2+]o affect the release of excitatory synaptic transmitter more than they affect postsynaptic membrane function.     

Cysteamine pre-treatment reduces pentylenetetrazol-induced plasticity and epileptiform discharge in the CA1 region of rat hippocampal slices

The effects of prior treatment of cysteamine, a somatostatin inhibitor, on pentylenetetrazol (PTZ) induced epileptic and plastic changes in CA1 excitability were examined. Population spikes were evoked by activation of Schaffer collaterals with a range of stimulation intensities. Changes in the population spike and epileptiform amplitudes were used as indices to quantify the effects of PTZ exposure in the control and cysteamine pre-treated slices. Cysteamine pre-treatment decreased baseline CA1 population spike amplitude following high intensity stimulation of Schaffer collaterals. Following PTZ application directly to the slices, cysteamine diminished the increased population spike and epileptiform amplitudes which were normally observed following collateral stimulation. Magnesium-free medium induced epileptiform activity was also significantly reduced with cysteamine pre-treatment. It is concluded that somatostatin may be involved in PTZ-induced epileptic and plastic changes in CA1 excitability.     

Modulation of motor cortex excitability in the left hemisphere during action observation: a single- and paired-pulse transcranial magnetic stimulation study of self- and non-self-action observation

Motor system excitability was tested by transcranial magnetic stimulation (TMS), and F-wave and H-reflex evaluation in different action observation tasks. Our aim was to investigate the effects produced by self- versus non-self-hand movement observation (MO). No significant differences were found between the self- and non-self-conditions. Movement observation significantly modulated motor cortex excitability, producing an increase in the amplitude of motor evoked potentials (MEPs) with a single magnetic pulse and a reduction in intracortical inhibition (ICI) with paired-pulse stimulation. No significant changes were found in motor cortex excitability during the observation of geometric objects. Motor imagery produced similar effects to those of action observation; no significant differences in modulation of motor system excitability between motor imagery and action observation were found in those muscles involved in actual motor execution. No significant effect on spinal excitability was found in any of the test conditions.     

Long-term increases in the evoked population spike in the CA1 region of rat hippocampus induced by beta-adrenergic receptor activation.

The effects of the selective beta-adrenergic receptor agonist isoproterenol (ISO) were characterized in the CA1 region of the rat hippocampal slice preparation. As has been previously described, 500 nM ISO increased the amplitude of the evoked population spike response without having any effect upon field EPSP (fEPSP) responses. However, the increase in the population spike response was quite persistent and was not reversed by greater than 30 min of washout in the majority of the slices tested; we have termed this prolonged increase beta-adrenergic potentiation (BAP). As with the acute effect of ISO, BAP is confined to an increase in the population spike response and not the fEPSP. In input-output curves, this was clearly observed as a persistent leftward shift in the EPSP-population spike relationship. Similar long-term increases in the population spike could also be elicited by superfusion of the slices for 10 min with 20-25 microM norepinephrine (NE). Although both the acute and the long-term effects of ISO were blocked by pretreatment with timolol, a beta-adrenergic antagonist, the long-term effects were not reversed by superfusion with timolol following ISO treatment, demonstrating that the prolonged effects were not due to slow washout of ISO from the tissue. BAP was not blocked by pretreatment with 50 microM 2-amino-5-phosphonovaleric acid, an NMDA receptor antagonist that blocks hippocampal long-term potentiation and the long-lasting changes in synaptic responses induced in the dentate gyrus by NE and ISO.(ABSTRACT TRUNCATED AT 250 WORDS)     

Signaling components in rat hippocampal slices: Effects of protease inhibition

We performed extracellular recording in the CA1 field of acute hippocampal slices of Wistar rats and measured presynaptic volley, EPSP slope, and population spike amplitude after the stimulation of the Schaffer collaterals of different intensities. A comparison of the maximum responses in slices that were preincubated with caspase-3 (Z-DEVD-FMK) or cathepsin B (Z-FA-FMK) inhibitors did not show any significant differences in the indices studied. It is difficult to reveal the effects of caspase inhibitors because its substrates in different compartments can participate in signal transmission. We approximated the relationships between the presynaptic volley, fEPSP slope, and population spike amplitude and the stimulus intensity using several functions. The parameters of these functions were calculated for each slice individually. Mathematical modeling suggests that all function parameters are typical of different mechanisms of neuronal responses. The correlations between the theoretical functions and experimental data were highly significant for the majority of slices. This method confirmed the possibility of synaptic potentiation after caspase-3 inhibition under both excitotoxic and nonpathological in vitro conditions. In the presence of cathepsin B inhibitors, the approximating functions had parameters that reflected the increased excitability of CA1 pyramidal neurons. The majority of the other parameters did not differ in the control, Z-DEVD-FMK and Z-FA-FMK groups, or were significantly the same.