Discovery and development of neuronal nitric oxide synthase inhibitors.

The role of neuronally derived nitric oxide (NO) in neurotransmission and neural injury remains an area of active investigation. NO generation has been postulated to be involved in the deleterious events surrounding ischemia/reperfusion injury either directly or via the production of more reactive oxidants such as peroxynitrite. In our search for novel therapeutics for the treatment of a variety of neurological diseases including stroke, we have discovered novel, potent, and selective inhibitors of the neuronal nitric oxide synthase (nNOS) isoform. These compounds have proven to be effective in models of ischemia/reperfusion supporting the role of nNOS in these processes. The effects of these compounds as well as additional aspects critical to their development will be presented.

Efficacy of AR-R15896AR in the rat monofilament model of transient middle cerebral artery occlusion.

The monofilament technique of transient middle cerebral artery occlusion (MCAO) was used in 3 separate studies to evaluate the efficacy of the low-affinity, use-dependent N-methyl-d-aspartate receptor antagonist, AR-R15896AR. First, a dose-response curve was attempted. Wister Kyoto rats received 2 hours of MCAO. Five minutes later, a 30-minute intravenous infusion of AR-R15896AR was given, followed by subcutaneous implantation of Alzet minipumps that were calibrated to maintain specified plasma levels (approximately 682, 1885, or 2682 ng/mL) of AR-R15896 (free base) for 1 week. The highest plasma level attained significantly decreased the percentage of damage to the subcortex, cortex, and total brain. Second, the high-dose, 1-week treatment regimen was repeated to determine if neuroprotection would extend to 8 weeks after MCAO. Indeed, in separate groups of animals, significant reduction in the percentage of damage, which was generally confined to the cortex and subcortex, was observed at 1, 2, 4, and 8 weeks. Third, verification was achieved in another laboratory. Lister Hooded rats received 60 minutes of transient MCAO. At 70 minutes, an acute dose of AR-R15896AR (20.3 mg/kg) was injected intraperitoneally and the rats were killed 23 hours later. This treatment group also exhibited significant reduction in the volume of infarction in the subcortex, cortex, and total brain. The outcome of these investigations supports the ongoing Phase II clinical trials in patients with acute stroke.

The low-affinity, use-dependent NMDA receptor antagonist AR-R 15896AR. An update of progress in stroke.

Use-dependent N-methyl-D-aspartate (NMDA) receptor antagonists protect neurons from the lethal consequences of excessive stimulation by excitatory amino acids. Clinical development of high-affinity compounds such as MK801 have been limited due to untoward side effects. Toward this end, the lower-affinity use-dependent NMDA antagonists have greater margins of safety and have advanced to clinical trials for stroke, epilepsy, head trauma and chronic neurodegenerative disorders. AR-R 15896AR is currently in Phase II trials for stroke and has been repeatedly demonstrated to afford neuroprotection in a variety of in vivo and in vitro models associated with ischemia/excitotoxic conditions.

-(S)-Alpha-phenyl-2-pyridine-ethanamine Dihydrochloride-, a low affinity uncompetitive N-methyl-D-aspartic acid antagonist, is effective in rodent models of global and focal ischemia.

[(S)-Alpha-phenyl-2-pyridine-ethanamine dihydrochloride] (ARL 15896AR) is a low affinity uncompetitive N-methyl-D-aspartic acid receptor antagonist that was tested in animal models of anoxia and ischemia. Pretreatment of rodents with ARL 15896AR extended survival time during exposure to hypoxia. With the rat four-vessel occlusion model of global ischemia (20 min), oral dosing commencing at reflow, resulted in significant protection of the CA1 hippocampal neurons. ARL 15896AR was, however, ineffective in the rat two-vessel occlusion model and in the gerbil models of forebrain ischemia, the latter due to an inability to attain suitable plasma levels. In the spontaneously hypertensive rat model of middle cerebral artery occlusion (MCAO) (2 hr plus 22 hr reflow), acute dosing with ARL 15896AR (i.p.) beginning from 30 min before or up to 1 hr post-MCAO significantly reduced cortical infarct volume. The ability of ARL 15896AR to influence infarct size, as well as functional correlates was examined in SHR after 90 min of MCAO. T2 weighted magnetic resonance images taken at 2 and 6 days post-MCAO revealed significantly smaller lesion sizes in the group receiving injections with ARL 15896AR beginning 30 min after occlusion. Spontaneously hypertensive rats were subsequently tested (30-42 days post-MCAO) and found to be deficient in skilled use of the forepaws (staircase test). The contralateral forepaw was most severely impaired, however, ARL 15896AR treatment prevented motor impairment in only the ipsilateral forepaw. Histopathological examination of cortical infarct size was unremarkable between treated and control rats. The findings indicate that ARL 15896AR exhibits neuroprotection in global and focal models of ischemia

Neuroprotective actions of 2-amino-N-(1,2-diphenylethyl)-acetamide hydrochloride (FPL 13950) in animal models of hypoxia and global ischemia.

2-Amino-N-(1,2-diphenylethyl)-acetamide hydrochloride (FPL 13950) has been demonstrated to have good anticonvulsant efficacy and a relative lack of acute side effects in rodents. Similar in structure to remacemide hydrochloride, it was also shown to possess weak potency as an uncompetitive antagonist of N-methyl-D-aspartic acid (NMDA) receptors. In our study FPL 13950 was profiled preclinically as a potential neuroprotective agent with respect to lengthening the survival time of rodents exposed to hypoxia, as well as for ability to protect the vulnerable CA1 pyramidal neurons of the rat and dog from the consequences of global ischemia. Under conditions of hypoxia, pretreatment of rodents with FPL 13950 resulted in an extension in the time to loss of the righting reflex (rats) and mortality (rats and mice). This occurred whether the rats were maintained at ambient body temperature or made hyperthermic. When administered after 30 min of four-vessel occlusion global ischemia for periods of either 7 (b.i.d.) or 14 days (s.i.d.), FPL 13950 exhibited protection of the vulnerable CA1 hippocampal neurons in rat. In the 14-day treatment study the CA3 neurons were evaluated and FPL 13950 was found to prevent the lesser degree of ischemic-induced damage to this hippocampal region. In ischemic rats treated with FPL 13950 for 7 days, electrophysiological responses of CA1 neurons (orthodromic and antidromic population spikes, in vitro) were also preserved after FPL 13950 treatment. FPL 13950 was administered i.v. at 30 min after 8 min of clamping the ascending aorta in dogs, followed by a b.i.d./s.i.d. dosing regimen for 1 wk. Neuronal damage to CA1 was considerable in the saline-treated ischemic animals but significantly protected in dogs receiving FPL 13950. FPL 13950 continues to serve as a potential backup candidate for remacemide HCl which is currently in clinical trials for patients with stroke and epilepsy.