Gaboxadol -- a different hypnotic profile with no tolerance to sleep EEG and sedative effects after repeated daily dosing.

Gaboxadol, a selective extra synaptic GABA(A) receptor agonist, has been in clinical development for the treatment of insomnia. Development of tolerance to therapeutic effects (e.g. hypnotic and anticonvulsant and sedative) and withdrawal symptoms (e.g. REM sleep rebound and reduced seizure threshold) upon treatment discontinuation is reported for GABA(A) receptor allosteric modulators acting via the benzodiazepine binding site, e.g. zolpidem and indiplon. We conducted a head to head comparison in rats of the hypnotic (sleep EEG after 21 daily doses and 24 and 48 h after the last dose) and seizure threshold modifying (bicuculline assay 24 h after 28 daily doses) effects of gaboxadol and benzodiazepine ligands. Furthermore, we investigated in further details a previously reported apparent rapid development of tolerance to gaboxadol's effects in a rat rotarod motor coordination assay and related this effect to CNS exposure levels and in vitro potency at extra synaptic GABA(A) receptors. Sleep EEG studies demonstrated lack of tolerance and withdrawal effects after 28 daily doses with gaboxadol, whereas zolpidem produced both tolerance and withdrawal effects under a similar dosing regimen. Daily dosing with gaboxadol, zolpidem or indiplon for 28 days and acute discontinuation of treatment left the threshold to bicuculline-induced seizures unchanged. The rapidly attenuated effect of repeated gaboxadol dosing was confirmed in the rotarod model. However, re-challenge of gaboxadol insensitive animals with gaboxadol produced a maximum response, ruling out that receptor desensitisation accounts for these effects. By comparing CNS exposure at rotarod responses and concentration response relation at cloned GABA(A) receptors expressed in Xenopus oocytes it appears that the decline in response in the rotarod model coincides with the steep part of the concentration response curve for gaboxadol at extra synaptic GABA(A) receptors. In conclusion, rat sleep EEG repeated dose studies of gaboxadol confirm a hypnotic-like profile and no withdrawal effects, whereas tolerance and withdrawal effects were shown with zolpidem. Withdrawal from gaboxadol, zolpidem and indiplon did not affect the seizure threshold to bicuculline. Gaboxadol's apparent rapid development of tolerance in the rotarod assay appears to be kinetically determined.

Induction of P-glycoprotein expression and activity by ritonavir in bovine brain microvessel endothelial cells.

Extended treatment with human immunodeficiency virus (HIV) protease inhibitors (HPIs) is standard in HIV/AIDS therapy. While these drugs have helped decrease the overall incidence of AIDS defining illnesses, the relative prevalence of HIV/AIDS dementia has increased. HPIs may cause induction of blood-brain barrier (BBB) drug transporters (P-glycoprotein; P-gp) and thereby limit entry of HPIs into brain tissue, increasing the probability that the brain could become an HIV sanctuary site. Using bovine brain microvessel endothelial cells (BMEC) as an in-vitro model of the BBB, the potential for the HIV protease inhibitor ritonavir to cause induction of P-gp activity and expression was examined. BMEC were isolated from fresh cow brain by enzymatic digest and density centrifugation. Primary culture BMEC were co-incubated with ritonavir or vehicle control for 120 h. Quantitative drug accumulation of rhodamine 123 (Rh123) and fluorescence microscopy were used as measures of P-gp activity. P-gp expression was assessed using quantitative Western blotting. Ritonavir decreased Rh123 cell accumulation and increased P-gp immunoreactive protein in a concentration-dependent manner. Fluorescent microscopy mirrored Rh123 quantitative studies. In BMEC pretreated with 30 microM ritonavir, Rh123 accumulation was decreased 40% and immunoreactive P-gp protein increased 2-fold. Collectively, a strong correlation between decreased Rh123 BMEC accumulation and increased P-gp immunoreactive protein was observed (Spearman r2 = 0.77, P < 0.0001). Thus extended exposure of BMEC to ritonavir caused a concentration-dependent increase in P-gp activity and expression. Similar findings may occur at the clinical level with prolonged HIV protease inhibitor use, giving insight into the central nervous system as an HIV sanctuary site and eventual development of HIV dementia.

The effect of chronic lorazepam administration in aging mice.

To assess benzodiazepine tolerance in aged animals, lorazepam or vehicle was administered chronically to male Crl: CD-1(ICR)BR mice. Pharmacodynamic and neurochemical endpoints were examined on days 1 and 14 of drug administration. There was no age-related significant difference in plasma lorazepam levels. Young and middle-aged animals demonstrated behavioral tolerance to lorazepam, while the aged animals showed a similar trend which failed to reach significance. In addition, aged animals also showed a trend toward tolerance to the anticonvulsant effects of lorazepam. There were no changes in alpha1 mRNA levels in cortex or hippocampus following administration of lorazepam when compared to vehicle-treated animals in any age group. Aged animals, however, had an initial increase in alpha1 mRNA expression in cortex and hippocampus on day 1 of vehicle treatment followed by decreased expression on day 14. These age-related changes were abolished by lorazepam administration. In summary, age-related sensitivity to the effects of lorazepam was not demonstrated in the present study. However, comparison of these data to other studies indicates that the effect of chronic benzodiazepine treatment may be specific to the benzodiazepine administered, the technique used to quantify mRNA expression changes, the subunits of the GABA(A) receptor investigated and the brain region analyzed. The phenomenon of benzodiazepine sensitivity in the elderly is an area of research which remains controversial and may well be compound specific. Determining benzodiazepines that do not produce pharmacodynamic sensitivity, such as lorazepam, may allow more careful prescribing and dosing of these drugs, and perhaps even the development of specific agents which could avoid this sensitivity.

Acute zolpidem administration produces pharmacodynamic and receptor occupancy changes at similar doses.

Zolpidem is chemically unrelated to classical benzodiazepines but has demonstrated relatively high affinity binding to the alpha(1) GABA(A) receptor. To assess pharmacodynamic and neurochemical effects of zolpidem, open-field behavior, pentylenetetrazole-induced seizure threshold and benzodiazepine receptor binding in vitro were evaluated in the same animal following a single dose of zolpidem. Zolpidem (2, 5 and 10 mg/kg), lorazepam (2 mg/kg) or vehicle was administered intraperitoneally in male CD-1 mice. Behavioral activity, assessed by three open-field parameters, was decreased following the two highest doses of zolpidem (5 and 10 mg/kg), and reached significance at the 10 mg/kg dose. Locomotor activity was also decreased significantly by lorazepam as expected. Pentylenetetrazole-induced seizure threshold was increased with the administration of 2 and 10 mg/kg zolpidem as well as with lorazepam. Apparent affinity (K(D)) of [3H]flunitrazepam, a non-selective ligand, for the benzodiazepine receptor in cortical membrane preparations was not significantly changed, while receptor number (Bmax) was decreased at all doses of zolpidem, reaching significance at the 10 mg/kg dose. These results confirm that the behavioral effects of zolpidem are similar to those of classical benzodiazepines. In addition, zolpidem had no significant effect on the affinity of the benzodiazepine receptor for [3H]flunitrazepam, but did decrease the density of receptor binding sites.

Environmental conditions unexpectedly affect the long-term extent of cell death following an hypoxic episode.

Previously we reported delayed cell death, defined by clear-cut cell loss 60 days after a nitrite-induced hypoxic episode. The loss of cells was not apparent two weeks after the treatment, although some changes in cellular appearance were observed at that time. A similar delayed loss of neurons in the hippocampus after hypoxia induced by blood vessel occlusion has also been found. In addition, we reported that the amount of methemoglobinemia induced by the sodium nitrite can be reduced by the stress produced by handling and the injection of saline 2 or 24 h before the nitrite administration. The degree of methemoglobin formed is directly related to cell death in certain areas of the brain, including regions within the hippocampus. Considering the many effects that can be produced by chronic and acute stress of several kinds and the length of time during which these effects manifest themselves, we undertook to determine the histologic effects of the stresses of transport on the neuroanatomic effects of sodium nitrite administration 60 days post administration. Comparisons were made of the effects of two methods of transport from the laboratory in which the animals (male CD-1 mice) were injected with the sodium nitrite or saline (Tufts Medical School) to the laboratory in which the histologic evaluations were made (Binghamton University). The animals began their travel several hours after the injections. One transport method was by commuter airline and the other was by automobile. All animals had the same transport from the supplier to the Boston location (truck). Thus, the stress of experimental interest occurred after the nitrite administration. Upon arrival at Binghamton University, the animals were housed at the University in their own colony room for 60 days before sacrifice. After sacrifice, sections from their brains were subjected to a number of histologic staining procedures, including PTAH, the Bielschowsky silver method, GFAP, and the standard Nissl procedure. Although special attention was paid to hippocampal areas, changes in cells in the habenulae and the linings of ventricular areas were also prominent. Surprisingly, the nitrite treatment before transport to Binghamton offered partial protection against the very substantial and lasting effects of the injections, transport, and handling found in the control animals. Differential effects caused by the two methods of transport were also noted.