Aminooxy Pluronics: Synthesis and Preparation of Glycosaminoglycan Adducts

Novel biomaterials have been prepared in which glycosaminoglycans (GAGs) are chemically modified to create amphiphilic multiblock copolymers that are able to adhere to hydrophobic surfaces and can self-assemble into cross-linker-free hydrogels. First, the triblock poly(ethylene oxide)−polypropylene oxide copolymers (Pluronics) were converted into the previously unknown aminooxy (AO) derivatives. Both mono-AO and bis-AO Pluronics (AOPs) were synthesized and fully characterized in order to prepare tetrablock and pentablock copolymers, respectively. Second, the AOPs were coupled to the uronic acid carboxylates of heparin (HP) and hyaluronic acid (HA) using carbodiimide chemistry in order to give the previously undescribed amidooxy GAG derivatives. The coupling chemistry was confirmed using a newly prepared fluorescent AO reagent. Third, AOP-heparin and AOP-fluorescently labeled heparin were shown to adsorb efficiently to polystyrene surfaces, as determined by IL-8 based ELISA and fluorescence measurements, respectively. Fourth, AOP-linked fluorescently labeled HA was shown to adsorb efficiently to plastic surfaces. Finally, three different AOPs were evaluated for self-assembling hydrogel formation by AOP−HA pentablock polymers. In short, AOP−GAG adducts are semisynthetic amphiphilic biomacromolecules that offer a range of valuable practical opportunities for surface modification, preparation of cross-linker-free hydrogels, and formation of self-assembling mimics of the extracellular matrix

Flexible Filaments for <i>in Vivo</i> Imaging and Delivery: Persistent Circulation of Filomicelles Opens the Dosage Window for Sustained Tumor Shrinkage

Shape effects of synthetic carriers are largely unexplored in vivo, although recent findings suggest that flexible filaments can persist in the circulation even if microns in length. Here, to better assess biodistribution, a near-infrared fluorophore (NIRF) was incorporated into such block copolymer “filomicelles”, and both in vivo and ex vivo imaging show that the majority of these wormlike micelles remain in the circulation for at least a day after intravenous injection. NIRF imaging further suggests that filomicelles convect into a tumor and some fragments can penetrate into the tumor stroma. To assess a functional effect, the hydrophobic drug paclitaxel (tax) was loaded into both filomicelles and sonication-generated spherical micelles of the same copolymer. Intravenous injection of tax-loaded filomicelles nearly doubles the maximum tolerated dose of tax in normal mice compared to tax-loaded spherical micelles. In tumor-bearing mice, the higher dose of tax produces greater and more sustained tumor shrinkage and tumor cell apoptosis. These results thus begin to address mechanisms for how nonspherical carriers deliver both imaging agents and anticancer therapeutics to solid tumors

Endothelial Targeting of Antibody-Decorated Polymeric Filomicelles

The endothelial lining of the lumen of blood vessels is a key therapeutic target for many human diseases. Polymeric filomicelles that self-assemble from polyethylene oxide (PEO)-based diblock copolymers are long and flexible rather than small or rigid, can be loaded with drugs, andmost importantlythey circulate for a prolonged period of time in the bloodstream due in part to flow alignment. Filomicelles seem promising for targeted drug delivery to endothelial cells because they can in principle adhere strongly, length-wise to specific cell surface determinants. In order to achieve such a goal of vascular drug delivery, two fundamental questions needed to be addressed: (i) whether these supramolecular filomicelles retain structural integrity and dynamic flexibility after attachment of targeting molecules such as antibodies, and (ii) whether the avidity of antibody-carrying filomicelles is sufficient to anchor the carrier to the endothelial surface despite the effects of flow that oppose adhesive interactions. Here we make targeted filomicelles that bear antibodies which recognize distinct endothelial surface molecules. We characterize these antibody targeted filomicelles and prove that (i) they retain structural integrity and dynamic flexibility and (ii) they adhere to endothelium with high specificity both in vitro and in vivo. These results provide the basis for a new drug delivery approach employing antibody-targeted filomicelles that circulate for a prolonged time yet bind to endothelial cells in vascular beds expressing select markers

Endothelial Targeting of Antibody-Decorated Polymeric Filomicelles

The endothelial lining of the lumen of blood vessels is a key therapeutic target for many human diseases. Polymeric filomicelles that self-assemble from polyethylene oxide (PEO)-based diblock copolymers are long and flexible rather than small or rigid, can be loaded with drugs, andmost importantlythey circulate for a prolonged period of time in the bloodstream due in part to flow alignment. Filomicelles seem promising for targeted drug delivery to endothelial cells because they can in principle adhere strongly, length-wise to specific cell surface determinants. In order to achieve such a goal of vascular drug delivery, two fundamental questions needed to be addressed: (i) whether these supramolecular filomicelles retain structural integrity and dynamic flexibility after attachment of targeting molecules such as antibodies, and (ii) whether the avidity of antibody-carrying filomicelles is sufficient to anchor the carrier to the endothelial surface despite the effects of flow that oppose adhesive interactions. Here we make targeted filomicelles that bear antibodies which recognize distinct endothelial surface molecules. We characterize these antibody targeted filomicelles and prove that (i) they retain structural integrity and dynamic flexibility and (ii) they adhere to endothelium with high specificity both in vitro and in vivo. These results provide the basis for a new drug delivery approach employing antibody-targeted filomicelles that circulate for a prolonged time yet bind to endothelial cells in vascular beds expressing select markers