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2DG - a glucose analogue and glycolytic inhibitor with anticonvulsant and antiepileptic actions. Tom Sutula, MD, PhD Department of Neurology, University of Wisconsin Chief Scientific Officer, NeuroGenomex, Inc. The novel mechanism of 2DG: why 2DG is a glycolytic inhibitor.
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2DG - a glucose analogue and glycolytic inhibitor with anticonvulsant and antiepileptic actions Tom Sutula, MD, PhD Department of Neurology, University of Wisconsin Chief Scientific Officer, NeuroGenomex, Inc.
The novel mechanism of 2DG: why 2DG is a glycolytic inhibitor cannot undergo isomerization
Completed preclinical efficacy studies Animal Models of Acute & Chronic Epilepsy in vitro Models of Seizure Induction • 2DG reduces epileptic discharges evoked by: • K+ (7.5mM, ictal & interictal) • bicuculline (GABA • antagonist) • 4AP (K+ channel antagonist) • DHPG (metabotropic • glutamate agonist) • protection against seizures evoked by 6Hz stimulation • protection against audiogenic seizures in Fring’s mice • 2-fold slowing of latency to status epilepticus onset by kainic acid, pilo • 2-fold slowing of kindling progression evoked from different brain sites • time course of action & dose range • effective against seizure progression when administered up to 10 minutes after a seizure
Completed preclinical efficacy studies Animal Models of Acute & Chronic Epilepsy in vitro Models of Seizure Induction • 2DG reduces epileptic discharges evoked by: • K+ (7.5mM, ictal & interictal) • bicuculline (GABA • antagonist) • 4AP (K+ channel antagonist) • DHPG (metabotropic • glutamate agonist) • protection against seizures evoked by 6Hz stimulation • protection against audiogenic seizures in Fring’s mice • 2-fold slowing of latency to status epilepticus onset by kainic acid, pilo • 2-fold slowing of kindling progression evoked from different brain sites • time course of action & dose range • effective against seizure progression when administered up to 10 minutes after a seizure • implies that actions of 2DG at • the cellular level are “broad- • spectrum” against different • mechanisms of network • synchronization • these properties are • unlike ANY other • marketed drugs • 2DG is disease- • modifying against • progressive adverse • effects of seizures • efficacy studies support • clinical utility for both • ACUTE and CHRONIC • uses
Completed preclinical efficacy studies Animal Models of Acute & Chronic Epilepsy in vitro Models of Seizure Induction • 2DG reduces epileptic discharges evoked by: • K+ (7.5mM, ictal & interictal) • bicuculline (GABA • antagonist) • 4AP (K+ channel antagonist) • DHPG (metabotropic • glutamate agonist) • protection against seizures evoked by 6Hz stimulation • protection against audiogenic seizures in Fring’s mice • 2-fold slowing of latency to status epilepticus onset by kainic acid, pilo • 2-fold slowing of kindling progression evoked from different brain sites • time course of action & dose range • effective against seizure progression when administered up to 10 minutes after a seizure • implies that actions of 2DG at • the cellular level are “broad- • spectrum” against different • mechanisms of network • synchronization • these properties are • unlike ANY other • marketed drugs • 2DG is disease- • modifying against • progressive adverse • effects of seizures • efficacy studies support • clinical utility for both • ACUTE and CHRONIC • uses
Completed preclinical efficacy studies Animal Models of Acute & Chronic Epilepsy in vitro Models of Seizure Induction • 2DG reduces epileptic discharges evoked by: • K+ (7.5mM, ictal & interictal) • bicuculline (GABA • antagonist) • 4AP (K+ channel antagonist) • DHPG (metabotropic • glutamate agonist) • protection against seizures evoked by 6Hz stimulation • protection against audiogenic seizures in Fring’s mice • 2-fold slowing of latency to status epilepticus onset by kainic acid, pilo • 2-fold slowing of kindling progression evoked from different brain sites • time course of action & dose range • effective against seizure progression when administered up to 10 minutes after a seizure • implies that actions of 2DG at • the cellular level are “broad- • spectrum” against different • mechanisms of network • synchronization • these properties are • unlike ANY other • marketed drugs • 2DG is disease- • modifying against • progressive adverse • effects of seizures • efficacy studies support • clinical utility for both • ACUTE and CHRONIC • uses
Completed preclinical efficacy studies Animal Models of Acute & Chronic Epilepsy in vitro Models of Seizure Induction • 2DG reduces epileptic discharges evoked by: • K+ (7.5mM, ictal & interictal) • bicuculline (GABA • antagonist) • 4AP (K+ channel antagonist) • DHPG (metabotropic • glutamate agonist) • protection against seizures evoked by 6Hz stimulation • protection against audiogenic seizures in Fring’s mice • 2-fold slowing of latency to status epilepticus onset by kainic acid, pilo • 2-fold slowing of kindling progression evoked from different brain sites • time course of action & dose range • effective against seizure progression when administered up to 10 minutes after a seizure • implies that actions of 2DG at • the cellular level are “broad- • spectrum” against different • mechanisms of network • synchronization • these properties are • unlike ANY other • marketed drugs • 2DG is disease- • modifying against • progressive adverse • effects of seizures • efficacy studies support • clinical utility for both • ACUTE and CHRONIC • uses
2DG delivery to neurons and circuits is activity-dependent: a novel advantageous property for an anticonvulsant 2DG is preferentially delivered to regions with high energy needs by activity-dependent neurovascular coupling involving neurons, glia, and endothelial cells in the “neurovascular unit” Implications for clinical applications • likely useful for acute epileptic conditons with ongoing seizures (eg., status epilepticus, clusters) • potentially useful for peri-seizure administration to optimize delivery and minimize side-effects • potentially novel methods of delivery in combination with stimulation /device therapies H3-2DG autoradiogram during 1 hz stimulation 18F-2DG PET scan during status epilepticus
2DG delivery to neurons and circuits is activity-dependent: a novel advantageous property for an anticonvulsant 2DG is preferentially delivered to regions with high energy needs by activity-dependent neurovascular coupling involving neurons, glia, and endothelial cells in the “neurovascular unit” Implications for clinical applications • likely useful for acute epileptic conditons with ongoing seizures (eg., status epilepticus, clusters) • potentially useful for peri-seizure administration to optimize delivery and minimize side-effects • potentially novel methods of delivery in combination with stimulation /device therapies H3-2DG autoradiogram during 1 hz stimulation 18F-2DG PET scan during status epilepticus
2DG delivery to neurons and circuits is activity-dependent: a novel advantageous property for an anticonvulsant 2DG is preferentially delivered to regions with high energy needs by activity-dependent neurovascular coupling involving neurons, glia, and endothelial cells in the “neurovascular unit” Implications for clinical applications • likely useful for acute epileptic conditons with ongoing seizures (eg., status epilepticus, clusters) • potentially useful for peri-seizure administration to optimize delivery and minimize side-effects • potentially novel methods of delivery in combination with stimulation /device therapies H3-2DG autoradiogram during 1 hz stimulation 18F-2DG PET scan during status epilepticus
2DG delivery to neurons and circuits is activity-dependent: a novel advantageous property for an anticonvulsant 2DG is preferentially delivered to regions with high energy needs by activity-dependent neurovascular coupling involving neurons, glia, and endothelial cells in the “neurovascular unit” Implications for clinical applications • likely useful for acute epileptic conditons with ongoing seizures (eg., status epilepticus, clusters) • potentially useful for peri-seizure administration to optimize delivery and minimize side-effects • potentially novel methods of delivery in combination with stimulation /device therapies H3-2DG autoradiogram during 1 hz stimulation 18F-2DG PET scan during status epilepticus
Activity-dependent effects of 2DG on synaptic transmission
Activity-dependent effects of 2DG on synaptic transmission no effects on synaptic properties in normal conditions
Activity-dependent effects of 2DG on synaptic transmission 2DG reduces amplitude and frequency of sEPSCs after exposure to conditions that increase activity
Activity-dependent effects of 2DG on synaptic transmission • modification in mEPSCs is activity-dependent • implicates presynaptic vesicle release as • a mechanism of action of 2DG NOT SHOWN: “homeostatic” effects on synaptic plasticity
2DG in the pipeline Efficacy Toxicology • distinctive pattern of effectiveness in pre-clinical models • disease-modifying against progressive adverse effects of seizures • novel acute and chronic anti-epilepsy mechanisms of action • 2DG concentrates in areas of ictal epileptic activity • PET imaging agent for 30+ years • Favorable toxicity history • Completed Phase 1 in cancer • More than 20 other investigator clinical studies with > 300 subjects • Need to confirm safety in effective dose (ED) range – cardiac toxicity observed with chronic dosing at 10X > ED range, and mild potentially reversible cardiac autophagy in ED range Intellectual Property Remaining preclincal studies • IP licensed from WARF: 1 patent issued and 1 pending in US (has been issued in Australia) • NGX has exclusive license from WARF for all human therapeutic use • bioanalytical assay • development , toxicity, PK, • TK, ADME studies underway • in 2010 Q2
2DG in the pipeline Efficacy Toxicology • distinctive pattern of effectiveness in pre-clinical models • disease-modifying against progressive adverse effects of seizures • novel acute and chronic anti-epilepsy mechanisms of action • 2DG concentrates in areas of ictal epileptic activity • PET imaging agent for 30+ years • Favorable toxicity history • Completed Phase 1 in cancer • More than 20 other investigator clinical studies with > 300 subjects • Need to confirm safety in effective dose (ED) range – cardiac toxicity observed with chronic dosing at 10X > ED range, and mild potentially reversible cardiac autophagy in ED range Intellectual Property Remaining preclincal studies • IP licensed from WARF: 1 patent issued and 1 pending in US (has been issued in Australia) • NGX has exclusive license from WARF for all human therapeutic use • bioanalytical assay • development , toxicity, PK, • TK, ADME studies underway • in 2010 Q2 IND filing anticipated 2011 Q1
Current Development Plan • Complete preclinical toxicity, formulation, CMC, and filing of IND • “IND-enabling preclinical studies of 2DG for treatment of epilepsy” (awaiting NIH RAID, anticipated start Q2 2010) • Will complete preclinical studies including bioanalytical assay development, pharmacokinetic, toxicological, toxicokinetic, manufacturing, formulation, and clinical trial designs, and regulatory documentation for submission of an IND. • Investigator-initiated first in humans Phase I/II clinical trial in patients • with intractable epilepsy • “A Preliminary Tolerability and Efficacy Study of 2DG in Intractable Epilepsy” • Nathan Fountain, MD, University of Virginia • (EpilepsyTherapy Project-ERF, WARF, NGX, anticipated start in Q4 2010) • This will be a preliminary study of 2DG that will seek to detect an efficacy signal and assess tolerability in 10-15 intractable patients with frequent seizures. • Development of delayed release formulations • Zeeh Experimental Pharmacy Station (University of Wisconsin) • (E. Elder, PhD, supported by WARF) • This program is developing delayed release formulations to exploit the activity-dependent uptake and short t1/2 (~ 40 min) enabling chronic administration at lower total doses.
