Potent benzoazepinone γ-secretase modulators with improved bioavailability.

The triazolyl amide γ-secretase modulators are potent alternatives to the cinnamyl amides that have entered the clinic for the treatment of Alzheimer's disease. Herein we build on the lead benzoazepinones described in our prior communication with imidazomethoxyarene moiety alternatives that offer opportunities to fine tune physical properties as well as address hERG binding and PK. Both half-life and bioavailability were significantly improved, especially in dog, with robust brain Aß42 lowering maintained in both transgenic mouse and rat.

Discovery of novel triazolobenzazepinones as γ-secretase modulators with central Aß42 lowering in rodents and rhesus monkeys.

Synthesis and SAR studies of novel triazolobenzazepinones as gamma secretase modulators (GSMs) are presented in this communication. Starting from our azepinone leads, optimization studies toward improving central lowering of Aß42 led to the discovery of novel benzo-fused azepinones. Several benzazepinones were profiled in vivo and found to lower brain Aß42 levels in Sprague Dawley rats and transgenic APP-YAC mice in a dose-dependent manner after a single oral dose. Compound 34 was further progressed into a pilot study in our cisterna-magna-ported rhesus monkey model, where we observed robust lowering of CSF Aß42 levels.

Triazoles as γ-secretase modulators.

Synthesis, SAR, and evaluation of aryl triazoles as novel gamma secretase modulators (GSMs) are presented in this communication. Starting from the literature and in-house leads, we evaluated a range of five-membered heterocycles as replacements for olefins commonly found in non-acid GSMs. 1,2,3-C-aryl-triazoles were identified as suitable replacements which exhibited good modulation of γ-secretase activity, excellent pharmacokinetics and good central lowering of Aß42 in Sprague-Dawley rats.

Identification of novel metabolites of colchicine in rat bile facilitated by enhanced online radiometric detection.

Three novel conjugation metabolites of colchicine were identified in rat bile facilitated by enhanced on-line liquid chromatography-accurate radioisotope counting. The known 2- and 3-demethylcolchicines (DMCs) underwent O-sulfate conjugation in addition to the previously described O-glucuronidation. 2-DMC was preferably O-glucuronidated, whereas 3-DMC predominantly yielded O-sulfation conjugates, indicating phase II conjugation regiopreferences. Moreover, M1 was identified as a novel glutathione conjugate and a possible biotransformation pathway for its formation was proposed. The known 2-DMC (M6), 3-DMC (M7), 2-DMC glucuronide (M4), and novel 3-DMC sulfate (M3) were confirmed as the major metabolites. Radiometric data were acquired by the XFlow liquid chromatography-accurate radioisotope counting (XFlow LC-ARC) system, a novel technology for dynamic control of both on-column and postcolumn high-performance liquid chromatography flow rates to maximize sensitivity and resolution of radiochromatograms. A comparative evaluation was also performed between the XFlow LC-ARC system and a conventional flow radiometric detection system using bile samples from an in vivo disposition study of colchicine in male Sprague-Dawley rats. Results demonstrated a 20-fold sensitivity improvement of the XFlow LC-ARC system in comparison with radioactivity detection by conventional flow scintillation analyzers. The dynamic flow mode also provided the best chromatographic resolution. Unambiguous metabolite identification was performed by high-resolution mass spectrometry and nuclear magnetic resonance analysis.

A porcine astrocyte/endothelial cell co-culture model of the blood-brain barrier.

A method for the isolation of porcine atrocytes as a simple extension of a previously described procedure for isolation of brain capillary endothelial cells from adolescent pigs [Methods Cell Sci. 17 (1995) 2] is described. The obtained astroglial culture purified through two passages and by the method of the selective detachment was validated by a phase contrast microscopy and through an immunofluorescent assay for the glial fibrillary acidic protein (GFAP). Porcine astrocytes were co-cultivated with porcine brain capillary endothelial cells (PBCEC) for the development of an in vitro blood-brain barrier (BBB) model. The model was visualized by an electron microscopy and showed elevated transendothellial electrical resistance and reduced inulin permeability. To our knowledge, this is the first report for the establishment of a porcine astrocyte/endothelial cell co-culture BBB model, which avoids interspecies and age differences between the two cell types, usually encountered in the other reported co-culture BBB models. Considering the availability of the porcine brain tissue and the close physiological and anatomical relation between the human and pig brain, the porcine astrocyte/endothelial cell co-culture system can serve as a reliable and easily reproducible model for different in vitro BBB studies.

Brief heat shock affects the permeability and thermotolerance of an in vitro blood-brain barrier model of porcine brain microvascular endothelial cells.

Heat shock was imposed on an in vitro model of the blood-brain barrier (BBB) by submersion into prewarmed growth medium. Transendothelial electrical resistance (TEER) was used to assess the functional integrity of the endothelial barrier. Consequences of the heat shock were highly dependent upon the temperature and duration of exposure. Temperatures below 47 degrees C required more than 30 s of exposure to significantly impair barrier function, but full recovery occurred within 1 h. When the temperature was 50-54 degrees C, an exposure of only 10 s significantly diminished barrier function. Ten seconds of 51 degrees C or 54 degrees C caused a significant loss of barrier function (45% and 80%, respectively). Full recovery from the 51 degrees C shock occurred within 5 min, while recovery from the 54 degrees C shock required more than 10 h. When the temperature was 57 degrees C or greater, a 3-s duration diminished barrier function by 80%. In response to heat shock, the brain microvascular endothelial cells developed thermotolerance and over-compensated in their ability to form a physiological barrier. The BBB models lost more than 60% of barrier function when initially exposed to 53 degrees C for 5 s but lost only 30% of function when exposed to the same treatment 24 h later. The BBB models over-compensated to produce a reinforced barrier with double the original TEER following repeated application of heat treatment (57 degrees C for 3 s). In vivo experiments will require exquisite manipulation of the temperature and duration in order to achieve the desired opening of the BBB in therapeutic applications.