V. P. Torchilin

Altered vasculature and the resultant chaotic tumor blood flow lead to the appearance in fast-growing tumors of regions with gradients of oxygen tension and acute hypoxia (less than 1.4% oxygen). Due to its roles in tumorigenesis and resistance to therapy, hypoxia represents a problem in cancer therapy. Insufficient delivery of therapeutic agents to the hypoxic regions in solid tumors is recognized as one of the causes of resistance to therapy. This led to the development of hypoxia imaging agents, and the use of hypoxia-activated anticancer prodrugs. Here we show the first example of the hypoxia-induced siRNA uptake and silencing using a nanocarrier consisting of polyethyleneglycol 2000, azobenzene, polyethyleneimine (PEI)(1.8 kDa), and 1,2-dioleyl-sn-glycero-3-phosphoethanolamine (DOPE) units (the nanocarrier is referred to as PAPD), where azobenzene imparts hypoxia sensitivity and specificity. We report hypoxia-activated green fluorescent protein (GFP) silencing in vitro and its downregulation in GFP-expressing tumors after intravenous administration. The proposed nanoformulation represents a novel tumor-environment-responsive modality for cancer targeting and siRNA delivery.

The less than optimal accumulation of immunoliposome-associated reagents at target sites has often been attributed to the rapid in vivo clearance of immunoliposomes from the blood. In an attempt to overcome the drawback of rapid clearance and use the targeting potential of immunoliposomes, we have prepared long-circulating, 111In-labeled immunoliposomes. Targeting properties and enhanced circulation times were demonstrated in a rabbit model of acute experimental myocardial infarct. The specificity of liposomes for newly exposed intracellular cardiac myosin at the necrotic sites was achieved by incorporating monoclonal antimyosin antibody. Extended circulation times were achieved by cocoating the antimyosin-liposomes with polyethylene glycol (PEG). The half-life of the immunoliposomes was 40 min, which increased to 200 min with 4% mol PEG and to approximately 1000 min with 10% mol PEG. The degree of binding of modified immunoliposomes at the target sites was also dependent on the concentration of PEG incorporated at the liposome surface. This study demonstrates the accumulation of long-circulating targeted liposomes at the area of acute rabbit experimental myocardial infarction.

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.