The PTSgel released IgG for 28 days and was well tolerated. The polymer degraded in parallel with drug release. These results demonstrate the potential of intracameral PTSgel formulations for sustained delivery of biologic therapies to the ocular anterior segment.
Objective. To evaluate thermosensitive, biodegradable pentablock copolymers (PTSgel) for sustained release and integrity of a therapeutic protein when injected subcutaneously. Materials and Methods. Five PTSgels with PEG-PCL-PLA-PCL-PEG block arrangements were synthesized. In vitro release of IgG from PTSgels and concentrations was evaluated at 37°C. Released IgG integrity was characterized by SDS-PAGE. In vitro disintegration for 10GH PTSgel in PBS was monitored at 37°C over 72 days using gravimetric loss and GPC analysis. Near-infrared IgG in PTSgel was injected subcutaneously and examined by in vivo imaging and histopathology for up to 42 days. Results. IgG release was modulated from approximately 7 days to more than 63 days in both in vitro and in vivo testing by varying polymer composition, concentration of PTSgel aqueous solution, and concentration of IgG. Released IgG in vitro maintained structural integrity by SDS-PAGE. Subcutaneous PTSgels were highly biocompatible and in vitro IgG release occurred in parallel with the disappearance of subcutaneous gel in vivo. Conclusions. Modulation of release of biologics to fit the therapeutic need can be achieved by varying the biocompatible and biodegradable PTSgel composition. Release of IgG parallels disappearance of the polymeric gel; hence, little or no PTSgel remains after drug release is complete.
A practical synthesis targeting the C16−C20 segment of the endogenous metabolite Resolvin E1 (RvE1) is described. The original route was revised to avoid the use of source-constrained raw materials and chemistries that were problematic on larger scale. The revised route utilizes commercially available (E)-1-chloropent-1-en-3-one as the key raw material to replace (S)-glycidol. The (E)-vinyl iodide functionality was installed by an addition/elimination sequence to prepare the segment required for a subsequent Sonogashira coupling. The chiral secondary hydroxyl group at C18 was established by Corey− Bakshi−Shibata (CBS) reduction followed by lipase-catalyzed acetylation to achieve chiral purity in excess of 98% ee. The revised route offered a viable multikilogram process to support early clinical production of this pro-resolution therapeutic agent.
Herein, we describe the enabling synthesis of (+)-BMS-820836, a 4,7-disubstituted tetrahydroisoquinoline which was developed as a treatment for a range of neurological diseases, including depression and neurophatic pain. In order to advance the drug candidate into the Phase 1 clinical trials, an efficient and scalable synthesis was required. Three areas of improvement included the development of a regioselective Friedel−Crafts cyclization, a classical resolution for the purification of the desired enantiomer, and a robust Suzuki−Miyaura coupling. These improvements ultimately resulted in the isolation of (+)-BMS-820836 as a free-flowing white solid in 99 area% purity and 3% overall yield after 14 steps.
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