Your search keyword '"Henrik Klitgaard"' showing total 3 results

1. Drug characteristics derived from kinetic modeling: combined 11C-UCB-J human PET imaging with levetiracetam and brivaracetam occupancy of SV2A

Author

Mika Naganawa, Jean-Dominique Gallezot, Sjoerd J. Finnema, Ralph Paul Maguire, Joël Mercier, Nabeel B. Nabulsi, Sophie Kervyn, Shannan Henry, Jean-Marie Nicolas, Yiyun Huang, Ming-Kai Chen, Jonas Hannestad, Henrik Klitgaard, Armel Stockis, and Richard E. Carson

Subjects

Radiology, Nuclear Medicine and imaging

Abstract

Background Antiepileptic drugs, levetiracetam (LEV) and brivaracetam (BRV), bind to synaptic vesicle glycoprotein 2A (SV2A). In their anti-seizure activity, speed of brain entry may be an important factor. BRV showed faster entry into the human and non-human primate brain, based on more rapid displacement of SV2A tracer 11C-UCB-J. To extract additional information from previous human studies, we developed a nonlinear model that accounted for drug entry into the brain and binding to SV2A using brain 11C-UCB-J positron emission tomography (PET) data and the time-varying plasma drug concentration, to assess the kinetic parameter K1 (brain entry rate) of the drugs. Method Displacement (LEV or BRV p.i. 60 min post-tracer injection) and post-dose scans were conducted in five healthy subjects. Blood samples were collected for measurement of drug concentration and the tracer arterial input function. Fitting of nonlinear differential equations was applied simultaneously to time-activity curves (TACs) from displacement and post-dose scans to estimate 5 parameters: K1 (drug), K1(11C-UCB-J, displacement), K1(11C-UCB-J, post-dose), free fraction of 11C-UCB-J in brain (fND(11C-UCB-J)), and distribution volume of 11C-UCB-J (VT(UCB-J)). Other parameters (KD(drug), KD(11C-UCB-J), fP(drug), fP(11C-UCB-J, displacement), fP(11C-UCB-J, post-dose), fND(drug), koff(drug), koff(11C-UCB-J)) were fixed to literature or measured values. Results The proposed model described well the TACs in all subjects; however, estimates of drug K1 were unstable in comparison with 11C-UCB-J K1 estimation. To provide a conservative estimate of the relative speed of brain entry for BRV vs. LEV, we determined a lower bound on the ratio BRV K1/LEV K1, by finding the lowest BRV K1 or highest LEV K1 that were statistically consistent with the data. Specifically, we used the F test to compare the residual sum of squares with fixed BRV K1 to that with floating BRV K1 to obtain the lowest possible BRV K1; the same analysis was performed to find the highest LEV K1. The lower bound of the ratio BRV K1/LEV K1 was ~ 7. Conclusions Under appropriate conditions, this advanced nonlinear model can directly estimate entry rates of drugs into tissue by analysis of PET TACs. Using a conservative statistical cutoff, BRV enters the brain at least sevenfold faster than LEV.

Published

2022

2. New avenues for anti-epileptic drug discovery and development

Author

Twyman Roy E, Wolfgang Löscher, Dieter Schmidt, and Henrik Klitgaard

Subjects

medicine.medical_specialty, Drug Industry, Drug Evaluation, Preclinical, Drug Resistance, Drug resistance, Pharmacology, Epilepsy, Drug Discovery, Animals, Humans, Medicine, Molecular Targeted Therapy, Cooperative Behavior, Intensive care medicine, Drug industry, Clinical Trials as Topic, business.industry, Drug discovery, General Medicine, medicine.disease, Clinical trial, Drug development, Research Design, Drug Design, Anticonvulsants, Cooperative behavior, business

Abstract

Despite the introduction of over 15 third-generation anti-epileptic drugs, current medications fail to control seizures in 20-30% of patients. However, our understanding of the mechanisms mediating the development of epilepsy and the causes of drug resistance has grown substantially over the past decade, providing opportunities for the discovery and development of more efficacious anti-epileptic and anti-epileptogenic drugs. In this Review we discuss how previous preclinical models and clinical trial designs may have hampered the discovery of better treatments. We propose that future anti-epileptic drug development may be improved through a new joint endeavour between academia and the industry, through the identification and application of tools for new target-driven approaches, and through comparative preclinical proof-of-concept studies and innovative clinical trials designs.

Published

2013

3. Preface for the Steve White Honorary Issue of Neurochemical Research

Author

Henrik Klitgaard

Subjects

0301 basic medicine, 03 medical and health sciences, Cellular and Molecular Neuroscience, 030104 developmental biology, 0302 clinical medicine, Neurochemical, White (horse), Neurochemistry, General Medicine, Psychology, Biochemistry, Neuroscience, 030217 neurology & neurosurgery

Published

2017