Synthesis of Analogs of a Potential Drug for Treatment of Epilepsy

Fluet-Chouinard, Adrien

29 May 2019

Prior work in the Durst group had generated more than forty analogs of the potent anticonvulsant isoxylitone isolated isolated from a medicinal plant Delphinium denudatum Wall. The nitrile designated as TD532 was the most potent compound generated by A. Saikaley. The starting material for the synthesis of TD532 is isophorone. The observation that TD532 showed considerable potential as an anticonvulsant suggested that other cyclohexenones might have have similar activity. During this project close to fifty derivatives of cyclohex-2-enone, focusing mainly on 3-arylcylohex-2-enones, were prepared. The synthesis of these compounds is described and structure activity relationships are discussed. Based on all the available structure activity data, we have designated the indicated portion of structure A as the pharmacophore for anticonvulsant and anti-epileptic activity. The ester designated as TD561 (compound 40) showed excellent potential in both in vitro and in vivo assays. It has been shown to be a pro-drug of the corresponding acid TD562 (compound 48). These two compounds and the sodium salt of TD562 are currently undergoing final pre-clinical studies at the Center for Drug Research and Development in Vancouver. Five analogs, including TD561 are also under investigation by the Epilepsy and Seizure Division of the US National Institutes of Health.

Synthesis of Analogs

Potential Drug

Treatment of Epilepsy

Anti-epileptic drug

Structure-activity relationship

Investigation Of Drug-related Changes On Bone Tissues Of Rat Animal Models In Healthy And Disease States

Garip, Sebnem

01 October 2012

Disease- and drug-related bone disorders are rapidly increasing in the population. The drugs which are used for the treatment of neurodegenerative diseases and metabolic derangements, may have negative or positive effects on bone tissues. In the first study, the possible side-effects of Carbamazepine and epileptic seizures on bone structure and composition were investigated by FTIR and synchrotron-FTIR microspectroscopy, AFM and micro- and nano-hardness analysis. The effects on the blood parameters, bone turnover and vitamin D metabolism were also investigated by ELISA and western blot analysis. The current study provides the first report on differentiation of the effects of both epileptic seizures and AED therapy on bones. Besides Carbamazepine treatment, seizures also caused a decrease in the strength of bone. The biochemical data showed that both the epileptic and drug-treated groups decreased vitamin D levels by increasing the vitamin D catabolism enzyme / 25-hydroxyvitamin D-24-hydroxylase. In the second study, the possible pleiotropic (positive) effects of cholesterol lowering drug / Simvastatin on bones were investigated by ATR-FTIR spectroscopy. The current study provides the first report on dose-dependent effects of simvastatin on protein structure and lipid conformation of bones. ATR-FTIR studies showed that although both high and low dose simvastatin strengthen bones, low dose simvastatin treatment is much more effective in increasing bone strength. Neural network analysis revealed an increased antiparallel and aggregated beta sheet and random coil in the protein secondary structure of high dose group implying a protein denaturation. Moreover, high dose may induce lipid peroxidation which limit the pleiotropic effects of high dose treatment on bones. This study clearly demonstrated that using low dose simvastatin is safer and more effective for bone health than high dose simvastatin treatment.

QD Biochemistry 415-436