Antagonists at the ionotropic non-NMDA [AMPA (amino-methyl proprionic acid)/kainate] type of glutamate receptors have been suggested to possess several advantages compared to NMDA (N-methyl-D-aspartate) receptor antagonists, particularly in terms of risk/benefit ratio, but the non-NMDA receptor antagonists available so far have not fulfilled this promise. From a large series of pyrrolyl-quinoxalinedione derivatives, we selected six new competitive non-NMDA receptor antagonists. The basis of selection was high potency and selectivity for AMPA and/or kainate receptors, high in vivo potency after systemic administration, and an acceptable ratio between neuroprotective or anticonvulsant effects and adverse effects. Pharmacological characteristics of these novel compounds are described in this study with special emphasis on their effects in the kindling model of temporal lobe epilepsy, the most common type of epilepsy in humans. In most experiments, NBQX and the major antiepileptic drug valproate were used for comparison with the novel compounds. The novel non-NMDA receptor antagonists markedly differed in their AMPA and kainate receptor affinities from NBQX. Thus, while NBQX essentially did not bind to kainate receptors at relevant concentrations, several of the novel compounds exhibited affinity to rat brain kainate receptors or recombinant kainate receptor subtypes in addition to AMPA receptors. One compound, LU 97175, bound to native high affinity kainate receptors and rat GluR5-GluR7 subunits, i.e. low affinity kainate binding sites, with much higher affinities than to AMPA receptors. All compounds potently blocked AMPA-induced cell death in vitro and, except LU 97175, AMPA-induced convulsions in vivo. In the kindling model, compounds with a high affinity for GluR7 (LU 97175) or compounds (LU 115455, LU 136541) which potently bind to AMPA receptors and low affinity kainate receptor subunits were potent anticonvulsants in the kindling model, whereas the AMPA receptor-selective LU 112313 was the least selective compound in this model, indicating that non-NMDA antagonists acting at both AMPA and kainate receptors are more effective in this model than AMPA receptor-selective drugs. Three of the novel compounds, i.e. LU 97175, LU 115455 and LU 136541, exerted potent anticonvulsant effects without inducing motor impairment in the rotarod test. This combination of actions is thought to be a prerequisite for selective anticonvulsant drug action.
SummaryIt has been shown that 5 or 10 mg (--)deprenyl aider i.v. application inhibited platelet MAO within 30 min. This effect correlated with the improvement of parkinsonian patients disability. Platelet MAO is purely of type B, thus resembling the human brain enzyme, which is 80 % of type B. In other organs of the human MAO-A is of higher activity, thus it can oxidatively deaminate 5-HT, noradrenaline and tyramine in the periphery. The rather low peripheral side effects of (--)deprenyl can be explained by this fact. In vitro studies demonstrated that (--)deprenyl in comparison to d, 1-tranylcypromine, clorgyline and harmaline is by far the most potent inhibitor of human brain MAO. Post-mortem studies in different human brain areas showed that there are differences in the behaviour of (--)deprenyl (~10 mg) between short-and long-term treatment. Both show sufficient inhibition of DA-sensitive MAO (85--90 ~ However, when 5-HT is used as a substrate short-term treatment inhibits by about 40--50 % whereas long-term treatment inhibits by about 65 % which is higher than that mentioned before but not sufficient to increase brain 5-HT or decrease 5-HIAA. Therefore, long-term treatment with more than 1 mg/10 kg body weight could result in an accumulation of (--)deprenyl in the brain. Evidence for this derives from one parkinsonian patient, who was treated with 100 mg (--)deprenyl in which case both forms of the enzyme were inhibited sufficiently to increase DA and 5-HT in several brain regions.
Deprenyl is an inhibitor of monoamine oxidase type B, the enzyme responsible for 2-phenylethylamine oxidation, and is used in conjunction with L-Dopa therapy in Parkinson's disease. Post-mortem studies in human brain tissue have shown that after (-)deprenyl administration to parkinsonian patients amphetamine is present in concentrations up to 56 ng/g. It also could be shown that phenylethylamine concentrations are substantially increased in such patients. Phenylethylamine and amphetamine have been investigated using a gas chromatographic technique.
1. Significantly reduced values of noradrenaline in Parkinson's disease were observable in all brain areas which were studied. 2. A topographic distribution of free 3-methoxy-4-hydroxyphenylglycol (MHPG) can be demonstrated in the human brain. As MHPG in the various brain areas shows a different pattern of concentration it seems that this metabolite of noradrenaline is of physiological significance and is able to reflect noradrenaline turnover. The highest values of free MHPG were found in the hypothalamus, n. accumbens, thalamus and n. ruber. 3. In a limited series of patients with Parkinson's disease post mortem analysis indicated lower values of MHPG in caudate n., putamen, s. nigra, red nucleus and n. accumbens. All other brain areas did not show significant alterations. 4. Parkinsonian patients who died during Madopar therapy demonstrated a significant increase of MHPG in caudate n., putamen, s. nigra, n. ruber, n. amygdalae and n. accumbens when compared to the untreated group, indicating an enhanced turnover of noradrenaline in these areas. 5. Bound MHPG has been estimated in various brain areas as to be in the range of 13--38 percent of free MHPG.
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