Many targeting strategies can be employed to direct nanoparticles to tumors for imaging and therapy. However, tumors display a dynamic, heterogeneous microenvironment that undergoes spatiotemporal changes, including the expression of targetable cell-surface biomarkers. Here, we develop a nanoparticle system to effectively target two receptors overexpressed in the microenvironment of aggressive tumors. Hyaluronic acid (HA) was regioselectivity modified using a multi-step synthetic approach to alter binding specificities for CD44 and P-selectin to tumor cell interaction. The dual-targeting strategy utilizes sulfate modifications on HA that targets P-selectin, in addition to native targeting of CD44, which exploits spatiotemporal alterations in the expression patterns of these two receptors in cancer sites. Using biophysical characterization and in vitro studies, we demonstrate that modified HA nanoparticles effectively targets both P-selectin+ and CD44+ cells, which lays the groundwork for future in vivo biomedical applications.
The prognosis of pancreatic cancer remains poor. Intraoperative fluorescence imaging of tumors could improve staging and surgical resection, thereby improving prognosis. However, imaging pancreatic cancer with macromolecular delivery systems, is often hampered by nonspecific organ accumulation. Methods: We describe the rational development of hyaluronic acid (HA) conjugates that vary in molecular weight and are conjugated to near infrared fluorescent (NIRF) dyes that have differences in hydrophilicity, serum protein binding affinity, and clearance mechanism. We systematically investigated the roles of each of these properties on tumor accumulation, relative biodistribution, and the impact of intraoperative imaging of orthotopic, syngeneic pancreatic cancer. Results: Each HA-NIRF conjugate displayed intrapancreatic tumor enhancement. Regardless of HA molecular weight, Cy7.5 conjugation directed biodistribution to the liver, spleen, and bowels. Conjugation of IRDye800 to 5 and 20 kDa HA resulted in low liver and spleen signal while enhancing the tumor up to 14-fold compared to healthy pancreas, while 100 kDa HA conjugated to IRDye800 resulting in liver and spleen accumulation. Conclusion: These studies demonstrate that by tuning HA molecular weight and the physicochemical properties of the conjugated moiety, in this case a NIRF probe, peritoneal biodistribution can be substantially altered to achieve optimized delivery to tumors intraoperative abdominal imaging.
