Generation and functional assessment of 3D multicellular spheroids in droplet based microfluidics platform

Here we describe a robust, microfluidic technique to generate and analyze 3D tumor spheroids, which resembles tumor microenvironment and can be used as a more effective preclinical drug testing and screening model. Monodisperse cell-laden alginate droplets were generated in polydimethylsiloxane (PDMS) microfluidic devices that combine T-junction droplet generation and external gelation for spheroid formation. The proposed approach has the capability to incorporate multiple cell types. For the purposes of our study, we generated spheroids with breast cancer cell lines (MCF-7 drug sensitive and resistant) and co-culture spheroids of MCF-7 together with a fibroblast cell line (HS-5). The device has the capability to house 1000 spheroids on chip for drug screening and other functional analysis. Cellular viability of spheroids in the array part of the device was maintained for two weeks by continuous perfusion of complete media into the device. The functional performance of our 3D tumor models and a dose dependent response of standard chemotherapeutic drug, doxorubicin (Dox) and standard drug combination Dox and paclitaxel (PCT) was analyzed on our chip-based platform. Altogether, our work provides a simple and novel, in vitro platform to generate, image and analyze uniform, 3D monodisperse alginate hydrogel tumors for various omic studies and therapeutic efficiency screening, an important translational step before in vivo studies.

Raman microscopy for noninvasive imaging of pharmaceutical nanocarriers: intracellular distribution of cationic liposomes of different composition

Nanotechnology is playing an increasing role in targeted drug delivery into pathological tissues. Drug-loaded pharmaceutical nanocarriers can be delivered into diseased sites by passive targeting (spontaneous accumulation of nanocarriers in the areas with affected vasculature) or by active targeting (via site-specific ligands attached to the surface of drug-loaded nanocarriers). Subsequent level of targeting requires cellular internalization of nanocarriers and their specific association with certain individual cell organelles. The control over intracellular distribution of pharmaceutical nanocarriers requires effective and noninvasive methods of their visualization inside cells. In an attempt to enhance cellular internalization of pharmaceutical nanocarriers and their association with mitochondria specifically, we have prepared three types of cationic liposomes and investigated their intracellular distribution. The analysis was performed using Raman microspectroscopy in order to provide morphological information as well as biochemical signatures of the sample. It was demonstrated that Raman microscopy allows evaluation of the extent of mitochondrial association depending on the liposome composition.

Top-down and bottom-up approaches in production of aqueous nanocolloids of low solubility drug paclitaxel

Nano-encapsulation of a poorly soluble anticancer drug was demonstrated with a sonication assisted layer-by-layer polyelectrolyte coating (SLbL). We changed the strategy of LbL-encapsulation from making microcapsules with many layers in the walls for encasing highly soluble materials to using a very thin polycation/polyanion coating on low solubility nanoparticles to provide them with good colloidal stability. SLbL encapsulation of paclitaxel resulted in stable 100-200 nm diameter colloids with a high electrical surface ξ-potential (of -45 mV) and drug content in the nanoparticles of 90 wt%. In the top-down approach, nanocolloids were prepared by rupturing a powder of paclitaxel using ultrasonication and simultaneous sequential adsorption of oppositely charged biocompatible polyelectrolytes. In the bottom-up approach paclitaxel was dissolved in organic solvent (ethanol or acetone), and drug nucleation was initiated by the addition of aqueous polyelectrolyte assisted by ultrasonication. Paclitaxel release rates from such nanocapsules were controlled by assembling multilayer shells with variable thicknesses and were in the range of 10-20 h.

Lectin-bearing polymerized liposomes as potential oral vaccine carriers

PURPOSE

The potential of using lectin-modified polymerized liposomes as Peyer's patch targeted oral delivery vehicles was examined.

METHODS

Two types of lectins, Ulex Europaeus Agglutinin I (UEA I) and Wheat Germ Agglutinin (WGA), were modified with a hydrophobic anchor N-glutaryl-phosphotidylethanolamine (NGPE). The modified lectins were incorporated into liposome bilayers and the liposomes were subsequently stabilized through polymerization. The presence of the lectins on the liposome surfaces was first confirmed with X-ray photoelectron spectroscopy. Surface-immobilized lectins were then shown to retain their carbohydrate binding activities as well as specificities based on an in vitro aggregation assay. Finally, delivery efficiencies of lectin-bearing liposomes were determined in mice.

RESULTS

About 10.5% UEA I liposomes and 5.8% WGA liposomes were taken up from the gastrointestinal tract. These numbers are significantly higher than the 3.2% observed in the case of lectin-free liposomes. At the same time, UEA I liposomes exhibited the most effective Peyer's patch targeting among the three, which directly correlated with the highest delivery efficiency observed.

CONCLUSIONS

This establishes that lectin modification of liposomes can promote binding to Peyer's patches, which will give improved efficiency for Peyer's patch targeted delivery. All these point to the potential for these lectin-modified liposomes as novel vehicles for oral vaccination.

Biodegradable long-circulating polymeric nanospheres

Injectable nanoparticulate carriers have important potential applications such as site-specific drug delivery or medical imaging. Conventional carriers, however, cannot generally be used because they are eliminated by the reticulo-endothelial system within seconds or minutes after intravenous injection. To address these limitations, monodisperse biodegradable nanospheres were developed from amphiphilic copolymers composed of two biocompatible blocks. The nanospheres exhibited dramatically increased blood circulation times and reduced liver accumulation in mice. Furthermore, they entrapped up to 45 percent by weight of the drug in the dense core in a one-step procedure and could be freeze-dried and easily redispersed without additives in aqueous solutions.

Purification of radiolabeled monoclonal antibodies to angiotensin-converting enzyme significantly improves specificity and efficacy of its targeting into the lung

The aim of this study was to improve the labeling/purification procedures for monoclonal antibody (MoAb) to angiotensin-converting enzyme (ACE). MoAb 9B9 was very stable upon iodination at a wide range of iodogen concentrations and incubation times, and was also very stable upon storage, indicating the high technological potential of this MoAb. Radiolabeled MoAb 9B9 was purified by (i) adsorption chromatography on cellulose, (ii) HPLC (gel filtration) and (iii) affinity chromatography on ACE-Sepharose. The best result was obtained with cellulose: specificity of MoAb 9B9 accumulation in the lung increased 2-fold. We conclude that the phenomenon of specific lung accumulation of MoAb 9B9 may serve as an ideal (convenient, cheap and technological) assay system for evaluation of monoclonal antibody modification and labeling.