Discovery and optimization of 2-aryl oxazolo-pyrimidines as adenosine kinase inhibitors using liquid phase parallel synthesis.

Adenosine kinase inhibition is an attractive therapeutic approach for several conditions for example, neurodegeneration, seizures, ischemia, inflammation and pain. Several nucleosidic and non-nucleosidic inhibitors are available. Using a virtual screening approach, we have discovered that 2-aryl oxazolo-pyrimidines are adenosine kinase inhibitors. Subsequent high throughput derivatization enabled the optimization of this new inhibitor chemotype resulting in highly potent derivatives. A variety of analogues were produced by applying liquid phase parallel synthesis to vary the 7-amino residues as well as the 2-aryl moiety.

Effect of phenytoin on sodium and calcium currents in hippocampal CA1 neurons of phenytoin-resistant kindled rats.

About 20-30% of patients with epilepsy continue to have seizures despite carefully monitored treatment with antiepileptic drugs. The mechanisms explaining why some patients' respond and others prove resistant to antiepileptic drugs are poorly understood. It has been proposed that pharmacoresistance is related to reduced sensitivity of sodium channels in hippocampal neurons to antiepileptic drugs such as carbamazepine or phenytoin. In line with this proposal, a reduced effect of carbamazepine on sodium currents in hippocampal CA1 neurons was found in the rat kindling model of temporal lobe epilepsy (TLE), i.e. a form of epilepsy with the poorest prognosis of all epilepsy types in adult patients. To address directly the possibility that neuronal sodium currents in the hippocampus play a crucial role in the pharmacoresistance of TLE, we selected amygdala-kindled rats with respect to their in vivo anticonvulsant response to phenytoin into responders and nonresponders and then compared phenytoin's effect on voltage-activated sodium currents in CA1 neurons. Furthermore, in view of the potential role of calcium current modulation in the anticonvulsant action of phenytoin, the effect of phenytoin on high-voltage-activated calcium currents was studied in CA1 neurons. Electrode-implanted but not kindled rats were used as sham controls for comparison with the kindled rats. In all experiments, the interval between last kindled seizure and ion channel measurements was at least 5 weeks. In kindled rats with in vivo resistance to the anticonvulsant effect of phenytoin (phenytoin nonresponders), in vitro modulation of sodium and calcium currents by phenytoin in hippocampal CA1 neurons did not significantly differ from respective data obtained in phenytoin responders, i.e. phenytoin resistance was not associated with a changed modulation of the sodium or calcium currents by this drug. Compared to sham controls, phenytoin's inhibitory effect on sodium currents was significantly reduced by kindling without difference between the responder and nonresponder subgroups. Further studies in phenytoin-resistant kindled rats may help to elucidate the mechanisms that can explain therapy resistance.

Supraspinal vs spinal sites of the antinociceptive action of the subtype-selective NMDA antagonist ifenprodil.

The N-methyl-D-aspartate (NMDA) antagonist ifenprodil and several structurally related compounds are highly selective for the NR2B-containing receptor subtype. This selectivity could provide an explanation for the reported difference of the analgesic and side-effect profile of ifenprodil-like compounds from other NMDA antagonists. In this work, we have queried if the ifenprodil-induced antinociception can be attributed to the block of NMDA receptors in the spinal cord. Ifenprodil and some other NMDA antagonists (MK-801, memantine) were tested in a model of inflammatory pain (Randall-Selitto) in rats. The in vivo NMDA antagonism was assessed in anaesthetised rats on responses of spinal dorsal horn (DH) neurones to iontophoretic NMDA and in the model of single motor unit (SMU) wind-up. Ifenprodil, MK-801 and memantine dose-dependently increased nociceptive thresholds in the Randall-Selitto model. Antinociceptive doses of the channel blockers selectively antagonised NMDA responses of DH neurones and inhibited wind-up. In contrast, antinociceptive doses of ifenprodil did not show any NMDA antagonism in electrophysiological tests. Although ifenprodil did not inhibit the SMU responses to noxious stimuli in spinalised rats, it markedly and dose-dependently inhibited nociceptive SMU responses in sham-spinalised rats. These results argue against the spinal cord being the principal site of antinociceptive action of ifenprodil; supraspinal structures seem to be involved in this effect.

The new antiepileptic drugs lamotrigine and felbamate are effective in phenytoin-resistant kindled rats.

We evaluated the anticonvulsant efficacy of the antiepileptic drugs (AEDs) lamotrigine (LTG) and felbamate (FBM) in amygdala kindled rats that had been preselected with respect to their response to phenytoin. Anticonvulsant response was tested by determining the afterdischarge threshold (ADT), i.e., a sensitive measure for drug effects on focal seizure activity. By repeated testing with the phenytoin prodrug fosphenytoin, 3 groups of kindled rats were separated: rats in which consistent anticonvulsant effects were obtained (phenytoin responders), rats which showed no anticonvulsant response (phenytoin nonresponders), and rats with variable responses (variable phenytoin responders). The latter, largest group was used to evaluate at which doses LTG and FBM exerted significant anticonvulsant effects on ADT 1 h after i.p. drug administration. Effective doses were then used for drug testing in phenytoin responders and nonresponders. Both LTG and FBM proved to be effective anticonvulsant drugs in the kindling model by markedly increasing the ADT. Seizure severity and duration recorded at ADT currents were hardly reduced, indicating that both drugs predominantly affect induction of focal seizures and not seizure spread from the focus. In phenytoin nonresponders, LTG and FBM significantly increased ADT, which is in line with their proven efficacy in patients with refractory partial epilepsy in whom phenytoin has failed. However, LTG and, more markedly, FBM were clearly more efficacious in increasing ADT in phenytoin responders than in nonresponders, substantiating that the difference in phenytoin response between these groups of kindled rats extends to other AEDs. The data in this study reveal that phenytoin nonresponders are a unique model for the search for new AEDs with improved efficacy in refractory partial epilepsy.

Anticonvulsant efficacy of topiramate in phenytoin-resistant kindled rats.

PURPOSE: We evaluated the anticonvulsant efficacy of topiramate (TPM), a structurally novel antiepileptic drug (AED), in amygdala kindled rats that had been preselected with respect to their response to phenytoin (PHT). METHODS: Anticonvulsant response was tested by determining the afterdischarge threshold (ADT; i.e., a sensitive measure for drug effects on focal seizure activity). By repeated testing with the PHT prodrug fosphenytoin (FOS) three groups of kindled rats were separated: rats in which consistent anticonvulsant effects were obtained (PHT responders), rats that showed no anticonvulsant response (PHT nonresponders), and rats with variable responses (variable PHT responders). The latter, largest group was used to evaluate at which doses and pretreatment times TPM exerted significant anticonvulsant effects on ADT. For this purpose, TPM was tested at four doses (20, 40, 80, 160 mg/kg i.p.) and two pretreatment times (1 and 4 h). The most effective treatment protocol was then used for TPM testing in PHT responders and nonresponders. RESULTS: TPM proved to be an effective AED in the kindling model. At 40 mg/kg, significant ADT increases were obtained after both 1 and 4 h after administration. In addition to the effect on focal seizure threshold, seizure severity and duration recorded at ADT were decreased by TPM, indicating that this drug acts on both seizure threshold and seizure spread. In PHT nonresponders, TPM significantly increased ADT, which is in line with its proven efficacy in patients with refractory partial epilepsy in whom phenytoin has failed. However, TPM was more efficacious in increasing ADT in PHT responders than in nonresponders, substantiating that the difference between these groups of kindled rats extends to other AEDs. Repeated testing of kindled rats with TPM indicated that, similar to PHT, there are individual kindled rats without anticonvulsant response to TPM (i.e., TPM nonresponders). CONCLUSIONS: The data of this study substantiate that PHT nonresponders are a unique model for the search of new AEDs with improved efficacy in refractory partial epilepsy.

Kindling alters the anticonvulsant efficacy of phenytoin in Wistar rats.

We have previously shown that subgroups can be selected from large groups of amygdala kindled Wistar rats which either respond consistently or do not respond to the anticonvulsant effect of phenytoin. Phenytoin nonresponders were proposed as a model for pharmaco-resistant temporal lobe epilepsy. In the present study we examined whether the differences of individual rats in response to phenytoin are already present before kindling or are a consequence of kindling. For this purpose, 52 rats were once tested with phenytoin, then kindled, and then repeatedly tested with phenytoin for selection of subgroups. For subgroup selection after kindling, the phenytoin prodrug fosphenytoin was used because of its water solubility and its improved tolerability and absorption after i.p. administration in rats. Before kindling, phenytoin significantly increased the afterdischarge threshold (ADT), i.e. a sensitive measure of focal seizure activity, but there was large individual variation with only 32 of the 52 rats reacting with an ADT increase, while the remaining rats showed either no effect or ADT decreases. After kindling, the selection resulted in 16 rats with consistent ADT increases in response to phenytoin and ten nonresponders (the remaining 26 rats showed variable responses). Unexpectedly, in rats which were responders after kindling, phenytoin exerted no significant anticonvulsant effect before kindling, while kindled nonresponders were very sensitive to phenytoin before kindling, indicating that the kindling process was responsible for the loss of anticonvulsant efficacy in kindled nonresponders and the development of phenytoin's efficacy in kindled responders. The present results substantiate that kindled subgroups of Wistar rats with different response to phenytoin are a valuable source for studying the mechanisms underlying the development of pharmaco-resistant limbic seizures.

Anticonvulsant efficacy of gabapentin and levetiracetam in phenytoin-resistant kindled rats.

We evaluated the anticonvulsant efficacy of the new antiepileptic drugs (AEDs) gabapentin and levetiracetam in amygdala kindled rats that had been preselected with respect to their response to phenytoin. Anticonvulsant response was tested by determining the afterdischarge threshold (ADT), i.e. a sensitive measure for drug effects on focal seizure activity. By repeated testing with the phenytoin prodrug fosphenytoin, three groups of kindled rats were separated: rats in which consistent anticonvulsant effects were obtained (phenytoin responders), rats which showed no anticonvulsant response (phenytoin nonresponders), and rats with variable responses (variable phenytoin responders). The latter, largest group was used to evaluate at which doses gabapentin and levetiracetam exerted significant anticonvulsant effects on ADT 1 h after i.p. drug administration. Effective doses were then used for drug testing in phenytoin responders and nonresponders. Both gabapentin and levetiracetam proved to be effective anticonvulsant drugs in the kindling model by significantly increasing the ADT. In addition, both drugs markedly decreased seizure severity recorded at ADT currents, indicating that these drugs affect seizure threshold in the epileptic focus and seizure spread from the focus in the kindling model. When the threshold for secondary generalized seizures (GST) was determined in addition to ADT, gabapentin and levetiracetam strikingly increased this threshold compared to predrug control. In phenytoin nonresponders, gabapentin and levetiracetam significantly increased ADT and GST, which is in line with their proven efficacy in patients with refractory partial epilepsy in whom older AEDs have failed. In phenytoin responders, gabapentin tended to be more efficacious in increasing ADT and GST than in nonresponders, substantiating that the difference between these groups of kindled rats extends to other AEDs. In contrast to gabapentin, levetiracetam was more efficacious in increasing ADT in nonresponders than in responders. The data of this study substantiate that phenytoin nonresponders are a unique model for the search of new AEDs with improved efficacy in refractory partial epilepsy.

Anticonvulsant effect of fosphenytoin in amygdala-kindled rats: comparison with phenytoin.

Phenytoin has been reported to exert variable anticonvulsant effects in the kindling model of complex partial seizures. Phenytoin is only water soluble at a pH of more than 10, and it has been suspected that poor absorption of the drug is responsible for its lack of effect in some experiments. Recently, fosphenytoin, a prodrug of phenytoin, has been developed by phosphorylating phenytoin which makes the drug water soluble at physiological pH while it is rapidly transformed to phenytoin after injection. This study examined the anticonvulsant profile and the absorption after intraperitoneal injection of fosphenytoin, compared to its parental drug phenytoin. The pharmacokinetic parameters of phenytoin and fosphenytoin were compared by determining plasma levels of phenytoin after i.p. injection of 50 mg/kg phenytoin or the equivalent dose of 84 mg/kg of fosphenytoin in non-kindled female Wistar rats. After both injections the maximal plasma concentration of phenytoin was about 30 microg/ml. The relative bioavailability of fosphenytoin was 83%. In contrast to phenytoin, failed injections resulting in non-detectable plasma concentration of phenytoin were almost absent after fosphenytoin. In fully kindled female Wistar rats, fosphenytoin dose-dependently increased the focal seizure (afterdischarge) threshold. Seizure severity and duration at threshold were reduced only after the highest does of fosphenytoin tested (84 mg/kg). Thus, fosphenytoin showed anticonvulsant properties similar to phenytoin in amygdala kindled rats. We conclude that fosphenytoin is an adequate and reliable substitute for the parenteral injection of phenytoin in experimental seizure models of rats.