Fluorescent Nanorods and Nanospheres for Real-Time In Vivo Probing of Nanoparticle Shape-Dependent Tumor Penetration

Shape dependent: Fluorescent quantum-dot-based nanospheres and nanorods with identical hydrodynamic size and surface properties but different aspect ratios were developed for real-time in vivo tumor imaging. The nanorods exhibited superior transport and distribution into mammary tumors in vivo versus nanospheres of similar plasma half-life.National Cancer Institute (U.S.) (Grant Number R01-CA126642)MIT-Harvard Center for Cancer Nanotechnology Excellence (1U54-CA119349)Massachusetts Institute of Technology. Dept. of Chemistry Instrumentation Facility (CHE-980806)Massachusetts Institute of Technology. Dept. of Chemistry Instrumentation Facility (DBI-9729592)ISN (W911NF-07-D-0004

Study of cellular delivery of siRNA and shRNA targeting bcr-abl in chronic myeloid leukemia using Tat derived peptide

Chronic Myeloid Leukemia is characterised by the formation of a fusion gene bcr-abl. The gene product BCR-ABL has deregulated tyrosine kinase activity that plays a direct role in the pathogenesis of the disease. Recently, use of siRNA in leukaemic cells has led to effective gene silencing of bcr-abl. Gene delivery systems like viral vectors, electroporation and lipid based vectors have showed varying efficiencies but are limited by their level of toxicity and immunogenicity. Developments in the field of Cell Penetrating Peptides have shown effective cellular uptake of nucleic acids and proteins by the CPPs in vitro and in vivo. Report from our lab has shown the use of CPP Tat along with membrane active peptide LK15 to improve the transfection efficiency of both Tat and LK15 peptides individually. Hence, this study will focus on the use of Tat-LK15 peptide to study the delivery of siRNA and shRNA plasmid in K562 cells and observe the BCR-ABL protein expression. Cellular uptake studies using Tat-LK15 based complexes of Cy5-labelled DNA and siRNA showed a concentration dependent uptake leading to increase in percentage transfected cells. Tat-LK15 based DNA complexes achieved 80% transfected cells (charge ratio of 2:1) while siRNA complexes resulted in a maximum of 60% (charge ratio of 3:1). However, Lipofectamine based DNA complexes did not show a concentration dependent increase in percentage transfected cells. Interestingly, Tat-LK15 based siRNA complexes showed a similar level of uptake and percentage transfected cells as that of Lipofectamine based siRNA complexes. Cellular uptake studies using confocal microscopy 4 hours post transfection, showed that when 1μg of DNA was transfected, the labelled DNA was primarily localised on the cell membrane. Interestingly, using 5μg of DNA led to increased intracellular localisation of the labelled DNA, but this observation was not made with Lipofectamine based complexes. The observation at 24 hours post transfection of Tat-LK15/labelled DNA complexes was of higher intensity when compared to that of Lipofectamine based DNA complexes. The reason for this is however not known. Interestingly, the cellular uptake profile using siRNA based complexes was different. At 4 hours post transfection, there was intracellular localisation of labelled siRNA. 24 hours post transfection, there was diffuse cytoplasmic localisation using lower concentration of siRNA whereas using higher concentration led to more high intensity punctate localisations within the cell. Similar observations were made for both Tat-LK15 and Lipofectamine based siRNA complexes.Gene silencing studies of Tat-LK15/shRNA plasmid complex resulted in 80% reduction in protein levels 96 hours post transfection for higher concentrations of shRNA plasmid treated. Similar level of reduction in BCR-ABL was observed with Lipofectamine based complex. Supporting evidence of reduction in mRNA levels was observed using qRT-PCR 48 hours post transfection. However, Tat-LK15/shRNA plasmid complexes led to around 80% of protein reduction 192 hours post transfection while Lipofectamine based complexes resulted in only 40% of protein reduction. Transfection using increasing concentrations of siRNA complexed to Tat-LK15 and Lipofectamine led to greater than 70% reduction in protein levels for most concentration ranges tested. This reduction in protein levels lasted only 48 hours post transfection. In conclusion, Tat-LK15 peptide could be used for shRNA plasmid and siRNA based delivery and could offer an efficient gene delivery model for studying RNAi.EThOS - Electronic Theses Online ServiceGBUnited Kingdo

Comparison of IgG diffusion and extracellular matrix composition in rhabdomyosarcomas grown in mice versus in vitro as spheroids reveals the role of host stromal cells

The tumour extracellular matrix acts as a barrier to the delivery of therapeutic agents. To test the hypothesis that extracellular matrix composition governs the penetration rate of macromolecules in tumour tissue, we measured the diffusion coefficient of nonspecific IgG in three rhabdomyosarcoma subclones growing as multicellular spheroids in vitro or as subcutaneous tumours in dorsal windows in vivo. In subcutaneous tumours, the diffusion coefficient decreased with increasing content of collagen and sulphated glycosaminoglycans. When grown as multicellular spheroids, no differences in either extracellular matrix composition or diffusion coefficient were found. Comparison of in vitro vs in vivo results suggests an over-riding role of host stromal cells in extracellular matrix production subjected to modulation by tumour cells. Penetration of therapeutic macromolecules through tumour extracellular matrix might thus be largely determined by the host organ. Hence, caution must be exercised in extrapolating drug penetrability from spheroids and multilayer cellular sandwiches consisting of only tumour cells to tumours in vivo

Evaluation of aggregate and silicone-oil counts in pre-filled siliconized syringes: An orthogonal study characterising the entire subvisible size range.

Characterisation of particulates in therapeutic monoclonal antibody (mAb) formulations is routinely extended to the sub-visible size-range (0.1–10 μm). Additionally, with the increased use of pre-filled syringes (PFS), particle differentiation is required between proteinaceous and non-proteinaceous particles such as silicone-oil droplets. Here, three orthogonal techniques: Raster Image Correlation Spectroscopy (RICS), Resonance Mass Measurements (RMM) and Micro-Flow Imaging (MFI), were evaluated with respect to their sub-visible particle measurement and characterisation capabilities. Particle formation in mAb PFS solutions was evaluated with increasing polysorbate-20 (PS-20) concentrations. All three techniques provided complementary but distinct information on protein aggregate and silicone-oil droplet presence. PS-20 limited the generation of mAb aggregates during agitation, while increasing the number of silicone-oil droplets (PS-20 concentration dependant). MFI and RMM revealed PS-20 lead to the formation of larger micron-sized droplets, with RICS revealing an increase in smaller sub-micron droplets. Subtle differences in data sets complicate the apparent correlation between silicone-oil sloughing and mAb aggregates’ generation. RICS (though the use of a specific dye) demonstrates an improved selectivity for mAb aggregates, a broader measurement size-range and smaller sample volume requirement. Thus, RICS is proposed to add value to the currently available particle measurement techniques and enable informed decisions during mAb formulation development

3D simulations of early blood vessel formation

Blood vessel networks form by spontaneous aggregation of individual cells migrating toward vascularization sites (vasculogenesis). A successful theoretical model of two dimensional experimental vasculogenesis has been recently proposed, showing the relevance of percolation concepts and of cell cross-talk (chemotactic autocrine loop) to the understanding of this self-aggregation process. Here we study the natural 3D extension of the computational model proposed earlier, which is relevant for the investigation of the genuinely threedimensional process of vasculogenesis in vertebrate embryos. The computational model is based on a multidimensional Burgers equation coupled with a reaction diffusion equation for a chemotactic factor and a mass conservation law. The numerical approximation of the computational model is obtained by high order relaxed schemes. Space and time discretization are performed by using TVD schemes and, respectively, IMEX schemes. Due to the computational costs of realistic simulations, we have implemented the numerical algorithm on a cluster for parallel computation. Starting from initial conditions mimicking the experimentally observed ones, numerical simulations produce network-like structures qualitatively similar to those observed in the early stages of \emph{in vivo} vasculogenesis. We develop the computation of critical percolative indices as a robust measure of the network geometry as a first step towards the comparison of computational and experimental data.Comment: 25 pages, 9 figures Submitted to: JC

Modeling ssDNA electrophoretic migration with band broadening in an entangled or cross-linked network

We use a coarse-grained model proposed by Graham and Larson based on the temporary network model by Schieber et al.. [1] to simulate the electrophoretic motion of ssDNA and corresponding band broadening due to dispersion. With dimensionless numbers reflecting the experimental physical properties, we are able to simulate ssDNA behavior under weak to moderate electric field strengths for chains with 8–50 entanglements per chain (∼1000–8500 14base pairs), and model smoothly the transition from reptation to oriented reptation. These results are fitted with an interpolation equation, which allows the user to calculate dimensionless mobilities easily from input parameters characterizing the gel matrix, DNA molecules, and field strengths. Dimensionless peak widths are predicted from mobility fluctuations using the central limit theorem and the assumption that the mobility fluctuations are Gaussian. Using results from previous studies of ssDNA physical properties (effective charge Ξq and Kuhn step length b K ) and sieving matrix properties (pore size or tube diameter a ), we give scaling factors to convert the dimensionless values to “real” experimental values, including the mobility, migration distance, and time. We find that the interpolation equation fits well the experimental data of ssDNA mobilities and peak widths, supporting the validity of the coarse-grained model. The model does not account for constraint release and hernia formation, and assumes that the sieving network is a homogeneous microstructure with no temperature gradients and no peak width due to injection. These assumptions can be relaxed in future work for more accurate prediction.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/56125/1/2783_ftp.pd

Solid stress facilitates spheroid formation: potential involvement of hyaluronan

When neoplastic cells grow in confined spaces in vivo, they exert a finite force on the surrounding tissue resulting in the generation of solid stress. By growing multicellular spheroids in agarose gels of defined mechanical properties, we have recently shown that solid stress inhibits the growth of spheroids and that this growth-inhibiting stress ranges from 45 to 120 mmHg. Here we show that solid stress facilitates the formation of spheroids in the highly metastatic Dunning R3327 rat prostate carcinoma AT3.1 cells, which predominantly do not grow as spheroids in free suspension. The maximum size and the growth rate of the resulting spheroids decreased with increasing stress. Relieving solid stress by enzymatic digestion of gels resulted in gradual loss of spheroidal morphology in 8 days. In contrast, the low metastatic variant AT2.1 cells, which grow as spheroids in free suspension as well as in the gels, maintained their spheroidal morphology even after stress removal. Histological examination revealed that most cells in AT2.1 spheroids are in close apposition whereas a regular matrix separates the cells in the AT3.1 gel spheroids. Staining with the hyaluronan binding protein revealed that the matrix between AT3.1 cells in agarose contained hyaluronan, while AT3.1 cells had negligible or no hyaluronan when grown in free suspension. Hyaluronan was found to be present in both free suspensions and agarose gel spheroids of AT2.1. We suggest that cell–cell adhesion may be adequate for spheroid formation, whereas solid stress may be required to form spheroids when cell–matrix adhesion is predominant. These findings have significant implications for tumour growth, invasion and metastasis