71727-37-2Relevant academic research and scientific papers
Optimization of the in vitro cardiac safety of hydroxamate-based histone deacetylase inhibitors
Shultz, Michael D.,Cao, Xueying,Chen, Christine H.,Cho, Young Shin,Davis, Nicole R.,Eckman, Joe,Fan, Jianmei,Fekete, Alex,Firestone, Brant,Flynn, Julie,Green, Jack,Growney, Joseph D.,Holmqvist, Mats,Hsu, Meier,Jansson, Daniel,Jiang, Lei,Kwon, Paul,Liu, Gang,Lombardo, Franco,Lu, Qiang,Majumdar, Dyuti,Meta, Christopher,Perez, Lawrence,Pu, Minying,Ramsey, Tim,Remiszewski, Stacy,Skolnik, Suzanne,Traebert, Martin,Urban, Laszlo,Uttamsingh, Vinita,Wang, Ping,Whitebread, Steven,Whitehead, Lewis,Yan-Neale, Yan,Yao, Yung-Mae,Zhou, Liping,Atadja, Peter
, p. 4752 - 4772 (2011/09/20)
Histone deacetylase (HDAC) inhibitors have shown promise in treating various forms of cancer. However, many HDAC inhibitors from diverse structural classes have been associated with QT prolongation in humans. Inhibition of the human ether a-go-go related gene (hERG) channel has been associated with QT prolongation and fatal arrhythmias. To determine if the observed cardiac effects of HDAC inhibitors in humans is due to hERG blockade, a highly potent HDAC inhibitor devoid of hERG activity was required. Starting with dacinostat (LAQ824), a highly potent HDAC inhibitor, we explored the SAR to determine the pharmacophores required for HDAC and hERG inhibition. We disclose here the results of these efforts where a high degree of pharmacophore homology between these two targets was discovered. This similarity prevented traditional strategies for mitigating hERG binding/modulation from being successful and novel approaches for reducing hERG inhibition were required. Using a hERG homology model, two compounds, 11r and 25i, were discovered to be highly efficacious with weak affinity for the hERG and other ion channels.
Process development of a novel non-xanthine adenosine A1 receptor antagonist
Zanka, Atsuhiko,Uematsu, Ryoichi,Morinaga, Yasuhiro,Yasuda, Hironobu,Yamazaki, Hiroshi
, p. 389 - 393 (2013/09/08)
(+)-(R)-1-[(E)-3-(2-phenylpyrazolo[l,5-a]pyridin-3-yl)acryloyl]-2- piperidine ethanol (FK453) is a novel, potent adenosine AI receptor antagonist for the regulation of renal function. The development of a reliable process suitable for large scale manufacture is described. A Horner-Emmons reaction and a 1,3-dipolar cycloaddition were successfully scaled up to afford ethyl (E)-3-(2-phenylpyrazolo[l,5-a]pyridin-3-yl)acryloylate, with excellent regioselectivity and stereoselectivity. Process improvements and optimization of each step permitted elimination of column chromatography, resulting in a straightforward, practical synthesis of FK453.
Discovery of FK453, a novel non-xanthine adenosine A1 receptor antagonist
Akahane, Atsushi,Katayama, Hirohito,Mitsunaga, Takafumi,Kita, Yasuhiro,Kusunoki, Takahiro,Terai, Takao,Yoshida, Keizo,Shiokawa, Youichi
, p. 2059 - 2062 (2007/10/03)
Novel 2-phenylpyrazolo[1,5-a]pyridine-3-acryloylamides were synthesized and evaluated for diuretic activities. FK453 (1d), the most potent compound in this series, was found to be a potent and selective adenosine A1 receptor antagonist, whereas 1e, the (S)-enantiomer of FK453, was a weak and non-selective adenosine antagonist.
