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  • Application of structure-based drug design and parallel chemistry to identify selective, brain penetrant, in vivo active phosphodiesterase 9A inhibitors.

Application of structure-based drug design and parallel chemistry to identify selective, brain penetrant, in vivo active phosphodiesterase 9A inhibitors.

Journal of medicinal chemistry (2012-10-03)
Michelle M Claffey, Christopher J Helal, Patrick R Verhoest, Zhijun Kang, Kristina S Fors, Stanley Jung, Jiaying Zhong, Mark W Bundesmann, Xinjun Hou, Shenping Lui, Robin J Kleiman, Michelle Vanase-Frawley, Anne W Schmidt, Frank Menniti, Christopher J Schmidt, William E Hoffman, Mihaly Hajos, Laura McDowell, Rebecca E O'Connor, Mary Macdougall-Murphy, Kari R Fonseca, Stacey L Becker, Frederick R Nelson, Spiros Liras
RÉSUMÉ

Phosphodiesterase 9A inhibitors have shown activity in preclinical models of cognition with potential application as novel therapies for treating Alzheimer's disease. Our clinical candidate, PF-04447943 (2), demonstrated acceptable CNS permeability in rats with modest asymmetry between central and peripheral compartments (free brain/free plasma = 0.32; CSF/free plasma = 0.19) yet had physicochemical properties outside the range associated with traditional CNS drugs. To address the potential risk of restricted CNS penetration with 2 in human clinical trials, we sought to identify a preclinical candidate with no asymmetry in rat brain penetration and that could advance into development. Merging the medicinal chemistry strategies of structure-based design with parallel chemistry, a novel series of PDE9A inhibitors was identified that showed improved selectivity over PDE1C. Optimization afforded preclinical candidate 19 that demonstrated free brain/free plasma ≥ 1 in rat and reduced microsomal clearance along with the ability to increase cyclic guanosine monophosphosphate levels in rat CSF.

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Sigma-Aldrich
PF-04449613, ≥98% (HPLC)