120 research outputs found
Enhancing Nanoparticle-Based Visible Detection by Controlling the Extent of Aggregation
Visible indication based on the aggregation of colloidal nanoparticles (NPs) is highly advantageous for rapid on-site detection of biological entities, which even untrained persons can perform without specialized instrumentation. However, since the extent of aggregation should exceed a certain minimum threshold to produce visible change, further applications of this conventional method have been hampered by insufficient sensitivity or certain limiting characteristics of the target. Here we report a signal amplification strategy to enhance visible detection by introducing switchable linkers (SLs), which are designed to lose their function to bridge NPs in the presence of target and control the extent of aggregation. By precisely designing the system, considering the quantitative relationship between the functionalized NPs and SLs, highly sensitive and quantitative visible detection is possible. We confirmed the ultrahigh sensitivity of this method by detecting the presence of 20 fM of streptavidin and fewer than 100 CFU/mL of Escherichia coli
Gold Nanoparticle Delivery of Modified CpG Stimulates Macrophages and Inhibits Tumor Growth for Enhanced Immunotherapy
Gold nanoparticle accumulation in immune cells has commonly been viewed as a side effect for cancer therapeutic delivery;
however, this phenomenon can be utilized for developing gold nanoparticle mediated immunotherapy. Here, we
conjugated a modified CpG oligodeoxynucleotide immune stimulant to gold nanoparticles using a simple and scalable selfassembled
monolayer scheme that enhanced the functionality of CpG in vitro and in vivo. Nanoparticles can attenuate
systemic side effects by enhancing CpG delivery passively to innate effector cells. The use of a triethylene glycol (TEG) spacer
on top of the traditional poly-thymidine spacer increased CpG macrophage stimulatory effects without sacrificing DNA
content on the nanoparticle, which directly correlates to particle uptake. In addition, the immune effects of modified CpGAuNPs
were altered by the core particle size, with smaller 15 nm AuNPs generating maximum immune response. These TEG
modified CpG-AuNP complexes induced macrophage and dendritic cell tumor infiltration, significantly inhibited tumor
growth, and promoted survival in mice when compared to treatments with free CpG
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