Effect of Acoustic Radiation Force on the Distribution of Nanoparticles in Solid Tumors.

Acoustic radiation force (ARF) might improve the distribution of nanoparticles (NPs) in tumors. To study this, tumors growing subcutaneously in mice were exposed to focused ultrasound (FUS) either 15 min or 4 h after the injection of NPs, to investigate the effect of ARF on the transport of NPs across the vessel wall and through the extracellular matrix. Quantitative analysis of confocal microscopy images from frozen tumor sections was performed to estimate the displacement of NPs from blood vessels. Using the same experimental exposure parameters, ARF was simulated and compared with the experimental data. Enhanced interstitial transport of NPs in tumor tissues was observed when FUS (10 MHz, acoustic power 234 W/cm2, 3.3% duty cycle) was given either 15 min or 4 h after NP administration. According to acoustic simulations, the FUS generated an ARF per unit volume of 2.0×106 N/m3. The displacement of NPs was larger when FUS was applied 4 h after NP injection compared with after 15 min. This study shows that ARF might contribute to a modest improved distribution of NPs into the tumor interstitium.

Quantification and Qualitative Effects of Different PEGylations on Poly(butyl cyanoacrylate) Nanoparticles.

Protein adsorption on nanoparticles (NPs) used in nanomedicine leads to opsonization and activation of the complement system in blood, which substantially reduces the blood circulation time of NPs. The most commonly used method to avoid protein adsorption is to coat the NPs with polyethylene glycol, so-called PEGylation. Although PEGylation is of utmost importance for designing the in vivo behavior of the NP, there is still a considerable lack of methods for characterization and fundamental understanding related to the PEGylation of NPs. In this work we have studied four different poly(butyl cyanoacrylate) (PBCA) NPs, PEGylated with different types of PEG-based nonionic surfactants-Jeffamine M-2070, Brij L23, Kolliphor HS 15, Pluronic F68-or combinations thereof. We evaluated the PEGylation, both quantitatively by nuclear magnetic resonance (NMR), thermogravimetric analysis (TGA), and time-of-flight secondary ion mass spectrometry (ToF-SIMS) and qualitatively by studying ζ-potential, protein adsorption, diffusion, cellular interactions, and blood circulation half-life. We found that NMR and ToF-SIMS are complementary methods, while TGA is less suitable to quantitate PEG on polymeric NPs. It was found that longer PEG increases both blood circulation time and diffusion of NPs in collagen gels.

Labeling nanoparticles: Dye leakage and altered cellular uptake.

In vitro and in vivo behavior of nanoparticles (NPs) is often studied by tracing the NPs with fluorescent dyes. This requires stable incorporation of dyes within the NPs, as dye leakage may give a wrong interpretation of NP biodistribution, cellular uptake, and intracellular distribution. Furthermore, NP labeling with trace amounts of dye should not alter NP properties such as interactions with cells or tissues. To allow for versatile NP studies with a variety of fluorescence-based assays, labeling of NPs with different dyes is desirable. Hence, when new dyes are introduced, simple and fast screening methods to assess labeling stability and NP-cell interactions are needed. For this purpose, we have used a previously described generic flow cytometry assay; incubation of cells with NPs at 4 and 37°C. Cell-NP interaction is confirmed by cellular fluorescence after 37°C incubation, and NP-dye retention is confirmed when no cellular fluorescence is detected at 4°C. Three different NP-platforms labeled with six different dyes were screened, and a great variability in dye retention was observed. Surprisingly, incorporation of trace amounts of certain dyes was found to reduce or even inhibit NP uptake. This work highlights the importance of thoroughly evaluating every dye-NP combination before pursuing NP-based applications. © 2016 International Society for Advancement of Cytometry.

Cellular uptake of DNA-chitosan nanoparticles: the role of clathrin- and caveolae-mediated pathways.

The success of gene therapy depends on efficient delivery of DNA and requires a vector. A promising non-viral vector is chitosan. We tailored chitosan to optimize it for transfection by synthesizing self-branched and trisaccharide-substituted chitosan oligomers (SBTCO), which show superior transfection efficacy compared with linear chitosan (LCO). The aim of the work was to compare the cellular uptake and endocytic pathways of polyplexes formed by LCO and SBTCO. Both polyplexes were taken up by the majority of the cells, but the uptake of LCO was lower than SBTCO polyplexes. LCO polyplexes were internalized through both clathrin-dependent and clathrin-independent pathways, whereas SBTCO polyplexes were primarily taken up by clathrin-independent endocytosis. The different level of cellular uptake and the distinct endocytic pathways, may explain the difference in transfection efficacy. This was supported by the observation that photochemical internalization increased the transfection by LCO polyplexes considerably, whereas no effect on transfection was found for SBTCO polyplexes.

Effect of PEGylation on the diffusion and stability of chitosan-DNA polyplexes in collagen gels.

Diffusion through the extracellular matrix (ECM) is a critical step for the delivery of nanoparticles and genes. Gene delivery requires a carrier that protects the nucleic acid from degradation and facilitates transport. Chitosan is a promising carrier. To increase the circulation time, PEGylation of the carrier is performed. However, the effect of PEGylation on the transport and stability of gene delivery systems in the ECM has only been studied in solutions containing ECM components. We used polymerized collagen and collagen-hyaluronic acid (HA) gels to study the effects of PEGylation on the diffusion and stability of chitosan-DNA polyplexes. We found that PEGylation of the polyplexes was required for diffusion to occur, and PEGylation increased the dissociation between DNA and chitosan to some extent. The presence of HA had a contradictory role: it decreased the penetration depth of PEGylated polyplexes into the gels and increased the diffusion of the polyplexes being mixed into the gels.

Molecular design of chitosan gene delivery systems with an optimized balance between polyplex stability and polyplex unpacking.

Chitosan is an attractive gene delivery vehicle, but the criteria and strategies for the design of efficient chitosan gene delivery systems remain unclear. The purpose of this work was to investigate how the strength of the charge-based interaction between chitosan and DNA determines the gene expression levels and to design chitosan vectors with an optimized balance between polyplex stability and polyplex unpacking. Using 21 formulations based on low molecular weight chitosans with constant charge density and a number-average degree of polymerization (DPn) in the range of 21-88 (M(w) 4.7-33kDa), we studied the relationship between the chain length and the formulation properties, cellular uptake of polyplexes and gene transfer efficacy. We were able to identify a narrow interval of DPn31-42 that mediated the maximum level of transgene expression. An increase in chain length and/or the amino-phosphate (A/P) ratio reduced and delayed transgene expression. Compared to DPn31, transfection with the same amount of DPn72 or DPn88 resulted in 10-fold-lower expression levels. The gene transfer pattern correlated with the ability of heparin to release DNA from the polyplexes. As a tool to facilitate the unpacking of the polyplexes, we substituted the chitosans with uncharged oligosaccharides that reduced the interaction with DNA. The substitution of chitosans that originally yielded too stable polyplexes, such as DPn72 and DPn88 resulted in a 5-10-fold enhancement of the expression levels. However, the substitution of chitosans shorter than DP28 completely abolished transfection. Tailoring of the chain length and the substitution of chitosan were shown to be feasible tools to modulate the electrostatic interactions between the chitosan and DNA and to design chitosans with an optimized balance between polyplex stability and polyplex unpacking.