Development of DNase‐1 Loaded Polymeric Nanoparticles Synthesized by Inverse Flash Nanoprecipitation for Neutrophil‐Mediated Drug Delivery to In Vitro Thrombi
Sophie Maiocchi, Erica E. Burnham, Ana Cartaya, Veronica Lisi, Nancy Buechler, Rachel E. Pollard, Danial Babaki, Wolfgang Bergmeier, Nathalie M. Pinkerton, Edward Moreira Bahnson
Abstract
Activated neutrophils release Neutrophil Extracellular Traps (NETs), comprising decondensed chromatin, peroxidases, and serine proteases, which aid in host defense but are also implicated in thrombosis and resistance to thrombolysis. Recombinant DNase 1, which degrades NETs, may aid in thrombus dissolution synergistically with fibrinolytics. However, its short half-life and susceptibility to plasma proteases limit its therapeutic applicability. To address these limitations, DNase1 is encapsulated into polymeric nanoparticles (DNPs) using inverse Flash Nanoprecipitation (iFNP), a scalable nanoparticle synthesis technique. Previously only used with model proteins, the study demonstrates for the first time the feasibility of extending iFNP to the encapsulation of therapeutic proteins. Conditions that promote DNase1 solubility, preserve activity, and demonstrate release resulting in ex vivo NET degradation are detailed. Furthermore, the use of neutrophils, the source of NETs, as carriers for DNPs to enhance targeted delivery is investigated. These findings confirm that DNP-loaded neutrophils maintain key functionalities, including viability and oxidative burst, and associate with in vitro blood clots to deliver nanoparticles, and DNase1 protein. This study not only extends the feasibility of applying iFNP to encapsulate therapeutic proteins into polymeric nanoparticles, a promising alternative to lipid nanoparticles, but also contributes to the emerging literature on neutrophils as delivery vectors for nanocarriers.