Synthesis and Characterization of Click Nucleic Acid Conjugated Polymeric Microparticles for DNA Delivery Applications.

Microparticle-mediated nucleic acid delivery is a popular strategy to achieve therapeutic outcomes via antisense gene therapy. However, current methods used to fabricate polymeric microparticles suffer from suboptimal properties such as particle polydispersity and low encapsulation efficiency. Here, a new particulate delivery system based on step-growth thiol-Michael dispersion polymerization is reported in which a low polydispersity microparticle is functionalized with a synthetic nucleic acid mimic, namely, click nucleic acids (CNA). CNA oligomers, exhibiting an average length of approximately four nucleic acid repeat units per chain for both adenine and thymine bases, were successfully conjugated to excess thiols present in the microparticles. Effective DNA loading was obtained by simple mixing, and up to 6 ± 2 pmol of complementary DNA/mg of particle was achieved, depending on the length of DNA used. In addition, DNA loading was orders of magnitude less for noncomplementary sequences and sequences containing an alternating base mismatch. The DNA release properties were evaluated, and it was found that release could be triggered by sudden changes in temperature but was unaffected over a range of pH. Finally, phagocytosis of loaded microparticles was observed by confocal microscopy and corroborated by an increase in cellular metabolic activity up to 90%. Overall, this work suggests that CNA functionalized microparticles could be a promising platform for controlled DNA delivery.

Thiol-Michael Addition Microparticles: Their Synthesis, Characterization, and Uptake by Macrophages.

Polymeric microparticles are promising biomaterial platforms for targeting macrophages in the treatment of disease. This study investigates microparticles formed by a thiol-Michael addition step-growth polymerization reaction with tunable physiochemical properties and their uptake by macrophages. The hexafunctional thiol monomer dipentaerythritol hexa-3-mercaptopropionate (DPHMP) and tetrafunctional acrylate monomer di(trimethylolpropane) tetraacrylate (DTPTA) were reacted in a stepwise dispersion polymerization, achieving tunable monodisperse particles over a size range (1-10 µm) relevant for targeting macrophages. An off-stoichiometry thiol-acrylate reaction afforded facile secondary chemical functionalization to create particles with different chemical moieties. Uptake of the microparticles by RAW 264.7 macrophages was highly dependent on treatment time, particle size, and particle chemistry with amide, carboxyl, and thiol terminal chemistries. The amide-terminated particles were non-inflammatory, while the carboxyl- and thiol-terminated particles induced pro-inflammatory cytokine production in conjunction with particle phagocytosis. Finally, a lung-specific application was explored through time-dependent uptake of amide-terminated particles by human alveolar macrophages in vitro and mouse lungs in vivo without inducing inflammation. The findings demonstrate a promising microparticulate delivery vehicle that is cyto-compatible, is non-inflammatory, and exhibits high rates of uptake by macrophages.

Assessing Different Reactive Oxygen Species as Potential Antibiotics: Selectivity of Intracellular Superoxide Generation Using Quantum Dots.

Reactive oxygen species (ROS) represent a broad range of chemical species including superoxide, hydroxyl, singlet oxygen, and hydrogen peroxide. Each species behaves differently in the cellular environment. Some can play specific roles as intracellular signaling molecules, while others act primarily as indiscriminate oxidants. Several recent reports have promoted the use of exogenous ROS as therapeutic agents with applications from cancer therapies to novel antimicrobials. However, therapeutics, specifically antibiotics, should either kill or inhibit the growth of harmful cells (bacteria here) without harming the host cells, and hence selectivity of action is of vital importance. Here, we show that among different ROS, only superoxide was found to be bactericidal, killing a range of multidrug-resistant (MDR) pathogens without affecting the viability or growth of mammalian cells. Superoxide has a high thermodynamic capacity to be a strong oxidant. However, its lack of reactivity with cellular components at a physiological pH, except for the inactivation of biosynthetic enzymes containing labile iron-sulfur clusters, is key to its selectivity. The role of iron in bacterial pathogenesis also makes superoxide a strong candidate for antimicrobial therapy. Additionally, using a series of selective scavengers, we show that the superoxide radical is therapeutically effective and selective compared to other ROS like hydroxyl radicals, confirming previous results that used Escherichia coli gene knockouts to show that superoxide selectively deactivates some enzymes rather than causing indiscriminate damage of cellular components. In our in vitro studies, intracellular superoxide generation using light-activated quantum dots yielded highly selective and effective antimicrobial action. We screened 45 clinical MDR bacterial isolates and observed inhibition/therapeutic action in all strains, highlighting the applicability of such nanoparticle superoxide therapy. These results can pave the way for rational design of nanoscale therapies as precision medicine.