Synthesis, radiosynthesis and first in vitro evaluation of novel PET-tracers for the dopamine transporter: [(11)C]IPCIT and [(18)F]FE@IPCIT.

INTRODUCTION: Present data indicate that merging beneficial structural elements from previously published DAT-ligands highest DAT affinity, selectivity and a suitable metabolic profile should be achieved. This combination led to the development of IPCIT and FE@IPCIT. METHODS: Precursor synthesis was done starting from cocaine in a six step reaction. O-[(11)C]-methylation was established using [(11)C]methyl iodide, optimized and subsequently automated. Small scale (18)F-fluroroethylation as well as optimization of reaction parameters and automation were performed. Affinity and selectivity of the candidate substances were tested in standard binding experiments on human membranes. Metabolic stability and blood-brain-barrier (BBB) penetration were determined. RESULTS: Precursor compound, IPCITacid, and reference compounds, IPCIT and FE@IPCIT, were obtained in 4.9%, 12.7% and 4.1% yield, respectively. Automated radiosynthesis of [(11)C]IPCIT yielded 1.9 ± 0.7 GBq (12.5 ± 4%, corrected for decay). Optimum parameters for (18)F-fluoroethylation were 110 °C for 15 min under TBAH catalysis, yielding 67 ± 16 % radiochemical incorporation. Affinity was determined as 1.7 ± 0.6 nM for IPCIT, 1.3 ± 0.2 nM for FE@IPCIT and 37 ± 13 nM for the precursor molecule, IPCIT-acid. Results from in vitro and in silico evaluations revealed high stability but also high lipophilicity. CONCLUSION: Present data indicate high affinity and stability of both IPCIT and FE@IPCIT. Radiolabelling, optimization of reaction parameters and automation succeeded. On the other hand, data concerning BBB-penetration are not promising.

Development and automation of a novel NET-PET tracer: [11C]Me@APPI.

INTRODUCTION: The norepinephrine transporter (NET) is an important target for research in neurology and psychology and is involved in the pathophysiology of many neurodegenerative diseases such as Alzheimer's disease and attention deficient hyperactivity disorder. For visualization of NET abundance and deregulation, a novel PET tracer--[(11)C]Me@APPI--has been developed. METHODS: For precursor synthesis, a 4-step synthesis starting from N-phenyl-o-phenylenediamine was set up. Radiosynthesis was established and optimized using standard methods and subsequently automated in a GE TRACERlabFx C Pro synthesizer. Preclinical testing was performed comprising affinity and selectivity testing on human membranes as well as stability and blood-brain-barrier-penetration using in-vitro models. RESULTS: Precursor molecule (APPI:0) and reference compound (Me@APPI) were synthesized with 26.5% and 21.4% overall yield, respectively. So far, 1.25±0.72 GBq [(11)C]Me@APPI with 54.35±7.80 GBq/µmol specific activity were produced (n=11). Affinity of reference compounds was determined as 8.08±1.75 nM for Me@APPI and 19.31±2.91 nM for APPI:0, respectively (n≥9). IAM-chromatography experiments (n=3) revealed a P(m) value of 1.51±0.34 for Me@APPI. Stability testing using human liver microsomes revealed that 99.5% of the tracer was found to be still intact after 60 minutes (n=4). CONCLUSION: Present data indicate that [(11)C]Me@APPI has promising properties to become a clinically useful NET-PET-tracer. Further in-vitro and in-vivo evaluations are currently under way.