Comparative autoradiographic distribution of central omega (benzodiazepine) modulatory site subtypes with high, intermediate and low affinity for zolpidem and alpidem.

Pharmacological characterization of [3H]benzodiazepine binding to membrane preparations of adult rat hippocampus and neonatal rat brain have demonstrated, in addition to the omega 1 and omega 2 populations of central omega benzodiazepine binding sites associated with GABAA receptors, the existence of binding sites with microM affinity for the imidazopyridines zolpidem and alpidem. In the present study we have investigated their comparative autoradiographic distribution using [3H]flumazenil as a ligand. In the neonatal rat CNS, the imidazopyridine derivatives zolpidem and alpidem were found to discriminate two [3H]flumazenil binding site populations with an IC50 value ratio of more than 200-fold. In the different regions investigated (spinal cord, striatum, neocortex and inferior colliculus) the low affinity component had IC50 values of 20-40 microM (zolpidem) and 5-15 microM (alpidem) and accounted for ca. 50% of the total binding site population. In the adult rat, these imidazopyridine derivatives displayed a greater displacing potency in the cerebellum (IC50 = 6 and 36 nM, respectively) than in the hippocampus (IC50 = 37 and 403 nM, respectively). In the cerebellum, [3H]flumazenil binding was fully displaced by 1 microM of either compound and Hill coefficients of displacement curves were close to unity. In the hippocampus, 25% of [3H]flumazenil binding were resistant to 3 microM zolpidem or 1 microM alpidem, but were displaced by 100 microM of either compound. CL 218,872 also displayed a greater displacing potency in the cerebellum (IC50 = 83 nM) than in the hippocampus (IC50 = 711 nM) but [3H]flumazenil binding in the hippocampus was fully displaced by 10 microM of this compound. In adult rat hippocampus, zolpidem and alpidem were found to discriminate between three central omega site subtypes which display high (IC50 = 31 and 6.1 nM, for these imidazopyridine derivatives. In contrast, CL 218,872 discriminated between omega 1 and omega 2 sites but not between two omega 2 receptor subpopulations. omega 1 sites were mainly localized in layer IV of the sensorimotor cortex, cerebellum, substantia nigra, olfactory bulb and inferior colliculus. omega 2I sites were present in the cortical mantle (with higher levels in the cingulate and olfactory than in the sensorimotor cortex) and in subcortical (hippocampus, hypothalamus and nucleus accumbens) limbic structures. In the hippocampus, hypothalamus, spinal cord and nucleus accumbens, omega 2L sites accounted for more than 25% of the specific [3H]flumazenil binding; the density of these sites was minor in the cortex and in most pyramidal and extrapyramidal system structures.(ABSTRACT TRUNCATED AT 400 WORDS)

Imaging of primary and remote ischaemic and excitotoxic brain lesions. An autoradiographic study of peripheral type benzodiazepine binding sites in the rat and cat.

Seven days after unilateral middle cerebral artery occlusion in rats, peripheral type benzodiazepine binding sites (PTBBS), using [3H]PK 11195 as a specific radioligand, were greatly increased in the cortical and striatal regions surrounding the focus of infarction with smaller increases in the ventrolateral and posterior thalamic complexes and in the substantia nigra, all ipsilateral to the occlusion. Similarly, PTBBS increases were observed in the caudate nucleus and entorhinal cortex of cats likewise subjected to prior unilateral occlusion of the middle cerebral artery. Intrastriatal administration of N-methyl-D-aspartate (250 nmol) in the rat resulted in a dramatic ipsilateral increase in PTBBS levels in the striatum and in the deeper laminae of the ipsilateral frontoparietal cortex. Intrastriatal kainic acid administration (12 nmol) also elicited PTBBS increases ipsilaterally in rat striatum and cortex; a bilateral elevation of PTBBS levels was observed in the hippocampus. With all these interventions there existed a good spatial correlation between the PTBBS increase and neuronal loss as assessed either histologically or by the autoradiographic detection of the putative neuronal marker [3H]SCH 23390 (a D1 dopamine receptor ligand). Moreover, a glial proliferation of non-neuronal cells (macrophage and glial cells) was observed in brain regions noted to have increased PTBBS levels. PTBBS autoradiography thus constitutes a suitable technique for the localization of damaged areas in several experimental models of brain injury. PTBBS label not only the primary lesions but also functionally related areas and could further our understanding of phenomena such as partial neuronal loss and diaschisis. The study of PTBBS could be envisaged for the detection, localization and quantification of all neuropathological situations which engender a glial reaction or macrophage invasion and is potentially applicable to both experimental and human subjects, in which both autoradiographic and tomographic approaches could be undertaken.

Pharmacological characterization of in vivo [3H]lfenprodil binding sites in the mouse brain.

Intravenous injection of 5 muCi of [3H]ifenprodil to mice resulted in an accumulation of radioactivity in the whole brain which was maximal at 5 min postinjection and then declined in a biphasic manner. When whole brain radioactivity was measured 2 h after [3H]ifenprodil injection, more than 65% of the incorporated label was displaced by i.p. administration (30 min before the radiotracer) of the ifenprodil chemical congener +/-alpha-(4-chlorophenyl)-4-(4- fluorophenylmethyl)-1-piperidine ethanol (SL 82.0715) (10 mg/kg). At this time, most of the radioactivity (80%) present in the brain comigrated with authentic [3H]ifenprodil. When administered 30 min before the radiotracer, several sigma ligands inhibited in vivo [3H]ifenprodil binding to the mouse brain with the following rank order of potency (ID50, mg/kg, i.p.): haloperidol (0.27) greater than ifenprodil (0.83) greater than SL 82.0715 (1.37) greater than BMY 14,802 (5.5) greater than 1,3-di-O-tolylguanidine (18). GBR 12909 (20 mg/kg, i.p.) and phencyclidine (30 mg/kg, i.p.) also inhibited this binding by 71 and 59%, respectively. In contrast, the N-methyl-D-aspartate receptor channel blockers 1-[1-(2-thienyl)cyclohexyl] piperidine and MK-801 (10 mg/kg, i.p.) failed to affect [3H]ifenprodil binding.(ABSTRACT TRUNCATED AT 250 WORDS)

Comparative in vivo and in vitro regional selectivity of central omega (benzodiazepine) site ligands in inhibiting [3H]flumazenil binding in the rat central nervous system.

The in vivo selectivity for central omega (benzodiazepine) modulatory site subtypes of ligands from several chemical classes has been evaluated by measuring the displacement of the in vivo binding of [3H]flumazenil to several rat central nervous system structures differentially enriched in omega 1 and omega 2 sites. This labeling was prevented in a dose-related manner by the i.p. administration, 30 min before the radioligand, of several benzodiazepine derivatives, the cyclopyrrolone derivatives suriclone and zopiclone, the triazolopyridazine derivative CL 218,872 and the imidazopyridine derivative zolpidem. Most of the benzodiazepine derivatives studied displayed in vivo some selectivity for omega 2-enriched structures. In contrast, oxoquazepam and CL 218,872 were 2- to 3-fold more potent at preventing [3H]flumazenil binding in omega 1-enriched (cerebellum) than in omega 2-enriched structures. Maximal inhibitions by zolpidem of in vivo [3H]flumazenil binding [cerebellum (100%) > cerebral cortex (79%) > or = striatum (74%) > hippocampus (52%) > spinal cord (37%)] were related to the relative omega 1/omega 2 distribution ratio in each structure. These differences did not result from an uneven distribution of this compound in the central nervous system. Quantitative autoradiographic studies performed on 30 central nervous system regions showed a strong correlation between the in vitro and in vivo regional selectivity of zolpidem. For all the drugs studied there was a significant global correlation between their potency at inhibiting [3H]flumazenil binding in vitro and in vivo either in the cerebellum (P < .001) or in the spinal cord (P < .01) and between the in vitro and in vivo cerebellum/spinal cord selectivity. The differential in vivo selectivity of zolpidem may account for the reported hypnoselective profile of this imidazopyridine in the rodent.

In vivo interaction of zolpidem with central benzodiazepine (BZD) binding sites (as labeled by [3H]Ro 15-1788) in the mouse brain. Preferential affinity of zolpidem for the omega 1 (BZD1) subtype.

Zolpidem is a novel hypnotic drug which possesses preferential affinity, under in vitro conditions, for the omega 1 (BZD1) subtype of BZD binding sites. In the present study the in vivo interaction of zolpidem with mouse brain BZD binding sites, as labeled by i.v. injection of [3H]Ro 15-1788, has been investigated. Intraperitoneal administration of zolpidem (30 min before sacrifice) decreased in a dose-dependent manner, the retention of [3H]Ro 15-1788 in the cerebral cortex (ED50 = 8.9 mg/kg i.p.); the inhibition by zolpidem was maximal (70%) at 5 to 10 min postinjection and of only 10% 1 hr later. These kinetics are in agreement with its short lasting hypnotic properties. CGS 9896, CL 218,872 and flunitrazepam also prevented the cortical accumulation of [3H]Ro 15-1788 with ED50 values of 12.5, 24 and 0.17 mg/kg i.p., respectively. Zolpidem, like flunitrazepam, diminishes exploratory activity and possesses anticonvulsant and myorelaxant effects in the mouse. However, in contrast to flunitrazepam, the sedative action of zolpidem can be evidenced at a much lower recognition site occupancy (35%) than that needed for myorelaxant or anticonvulsant effects (50-56%). The regional selectivity of zolpidem as an inhibitor of [3H]Ro 15-1788 in vitro and in vivo binding in the mouse brain has been assessed by quantitative autoradiography.(ABSTRACT TRUNCATED AT 250 WORDS)