Inhibition of IL-1ß release from macrophages targeted with necrosulfonamide-loaded porous nanoparticles.

Inflammation is required for protective responses against pathogens and is thus essential for survival, but sustained inflammation can lead to diseases, such as atherosclerosis and cancer. Two important mediators of inflammation are the cytokines IL-1ß and IL-18, which are produced by myeloid cells of the immune system, including macrophages. These cytokines are released into the extracellular space through pores formed in the plasma membrane by the oligomerized protein gasdermin D (GSDMD). Necrosulfonamide (NSA) was recently identified as an effective GSDMD inhibitor and represents a promising therapeutic agent in GSDMD-dependent inflammatory diseases. Here, we targeted NSA to both mouse and human macrophages by using three different types of porous nanoparticles (NP), i.e. mesoporous silica (MSN), porous crosslinked cyclodextrin carriers (CD-NP), and a mesoporous magnesium-phosphate carrier (MPC-NP), all displaying high loading capacities for this hydrophobic drug. Cellular uptake and intracellular NSA delivery were tracked in time-lapse experiments by live-cell, high-throughput fluorescence microscopy, demonstrating rapid nanoparticle uptake and effective targeted delivery of NSA to phagocytic cells. Notably, a strong cytostatic effect was observed when a macrophage cell line was exposed to free NSA. In contrast, cell growth was much less affected when NSA was delivered via the nanoparticle carriers. Utilizing NSA-loaded nanoparticles, a successful concentration-dependent suppression of IL-1ß secretion from freshly differentiated primary murine and human macrophages was observed. Functional assays showed the strongest suppressive effect on human macrophages when using CD-NP for NSA delivery, followed by MSN-NP. In contrast, MPC-NP completely blocked the metabolic activity in macrophages when loaded with NSA. This study demonstrates the potential of porous nanoparticles for the effective delivery of hydrophobic drugs to macrophages in order to suppress inflammatory responses.

Mesoporous Biodegradable Magnesium Phosphate-Citrate Nanocarriers Amplify Methotrexate Anticancer Activity in HeLa Cells.

We present the synthesis of amorphous, mesoporous, colloidal magnesium phosphate-citrate nanoparticles (MPCs) from biogenic precursors, resulting in a biocompatible and biodegradable nanocarrier that amplifies the action of the anticancer drug methotrexate (MTX). Synthesis conditions were gradually tuned to investigate the influence of the chelating agent citric acid on the colloidal stability and the mesoporosity of the obtained nanoparticles. With optimized synthesis conditions, a large BET surface area of 560 m2/g was achieved. We demonstrate the potential of these biocompatible and biodegradable mesoporous MPCs as a drug delivery system. Lipid-coated MPCs were used to load the fluorescent dye calcein and the chemotherapeutic agent MTX into the mesopores. In vitro experiments show very low premature release of the cargo but efficient stimuli-responsive release in an environment of pH 5.5, in which MPCs degrade. Lipid-coated MPCs are taken up by cancer cells and are nontoxic up to concentrations of 100 µg/mL. When loaded with MTX serving as a representative model drug for in vitro studies, MPCs induced efficient cell death with an IC50 value of 1.1 µg/mL. Compared to free MTX, its delivery with MPCs enhances its efficiency by an order of magnitude. In summary, we have developed a biodegradable nanomaterial synthesized from biocompatible precursors that are neither toxic by themselves nor in the form of nanoparticles. With these features, MPCs may be applied as drug delivery systems and have the potential to reduce the side effects of current chemotherapies.