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Project

Development of theranostic ligands for fibroblast activation protein with improved pharmacokinetic profile.

Fibroblast activation protein (FAP) is a serine protease expressed on stromal cells of > 90% of all epithelial cancers, whereas its expression is almost undetectable in normal tissues. In addition, FAP expression is highly restricted and transiently increased in adult tissues during wound healing, inflammation, or fibrosis in activated fibroblasts. The highly focal expression makes FAP a promising diagnostic marker and an attractive therapeutic target, not only in cancer, but also in fibrotic and cardiovascular diseases. UAntwerp has an approved patent for the only highly potent, selective and orally bioavailable small molecule inhibitors of FAP known to date (US9346814 and EP2804859). One of the compounds in this patent (UAMC1110) has received widespread attention as the structural basis for FAP-targeted positron emission tomography (PET) radiotracers and FAP-targeted radiopharmaceutical therapies, which are currently heavily investigated and in high demand by the pharmaceutical industry. Also, at UAntwerp, research is ongoing that aims at producing UAMC1110 derivatives, with main applications in the in vitro diagnostics field. In addition, in the scope of a former IOF-POC project the applicants of this proposal have collaborated on the discovery of 18F-labeled UAMC1110 derivatives that can be used as PET diagnostics in oncology, fibrosis and related domains, and in cardiovascular disease. Recently, we have developed a small library of 18F-labeled probes that show promising stability, pharmacokinetics and tumour-targeting properties in human glioblastoma cancer xenografts. Based on this preliminary data a patent application has been filed. However, there is still room for improvement by reducing the accumulation of these probes in non-targeted organs, which is especially relevant in the context of radionuclide therapy. Through structural optimization (increasing the polarity of the probes), this POC project aims to expand this library and deliver compounds having high metabolic stability and less or no accumulation in liver and gastrointestinal tract. Following the proof-of-concept, these optimized probes will be included in the patent that will be filed in early June 2022, which should strengthen the industrial development of these probes as PET-diagnostics and theranostics.
Date:1 Sep 2022 →  31 Aug 2023
Keywords:FIBROBLASTS
Disciplines:Nuclear imaging, Medicinal chemistry