The selective activation of the immune system using nanoparticles as a drug delivery system is a promising field in cancer therapy. Block copolymers from HPMA and laurylmethacrylate-co-hymecromone-methacrylate allow the preparation of multifunctionalized core-crosslinked micelles of variable size. To activate dendritic cells (DCs) as antigen presenting cells, the carbohydrates mannose and trimannose are introduced into the hydrophilic corona as DC targeting units. To activate DCs, a lipophilic adjuvant (L18-MDP) is incorporated into the core of the micelles. To elicit an immune response, a model antigen peptide (SIINFEKL) is attached to the polymeric nanoparticle-in addition-via a click reaction with the terminal azide. Thereafter, the differently functionalized micelles are chemically and biologically characterized. While the core-crosslinked micelles without carbohydrate units are hardly bound by DCs, mannose and trimannose functionalization lead to a strong binding. Flow cytometric analysis and blocking studies employing mannan suggest the requirement of the mannose receptor and DC-SIGN for effective micelle binding. It could be suppressed by blocking with mannan. Adjuvant-loaded micelles functionalized with mannose and trimannose activate DCs, and DCs preincubated with antigen-conjugated micelles induce proliferation of antigen-specific CD8+ T cells.
Keywords: HPMA block copolymers; micelles; targeting; trimannose; vaccines.
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