Magnetic nanocarriers for the specific delivery of siRNA: Contribution of breast cancer cells active targeting for down-regulation efficiency.

The association between superparamagnetic iron oxide nanoparticles (SPION), carrying small interfering RNA (siRNA) as therapeutic agents and humanized anti- human epidermal growth factor receptor-2 (HER2) single-chain antibody fragments (scFv) for the active delivery into HER2-overexpressing cells appears as an interesting approach for patients with HER2-overexpressing advanced breast cancer. The obtained Targeted Stealth Magnetic siRNA Nanovectors (TS-MSN) are formulated by combining: (i) the synthesis protocol of Targeted Stealth Fluorescent Particles (T-SFP) which form the core of TS-MSN and (ii) the formulation protocol allowing the loading of T-SFP with polyplexes (siRNA and cationic polymers). TS-MSN have suitable physico-chemical characteristics for intravenous administration and protect siRNA against enzymatic degradation up to 24 h. The presence of HER2-targeting scFv on TS-MSN allowed an improved internalization (3-4 times more compared to untargeted S-MSN) in HER2-overexpressing breast cancer cells (BT-474). Furthermore, anti-survivin siRNA delivered by TS-MSN in HER2-negative breast-cancer control cells (MDA-MB-231) allowed significant down-regulation of the targeted anti-apoptotic protein of about 70%. This protein down-regulation increased in HER2+ cells to about 90% (compared to 70% with S-MSN in both cell lines) indicating the contribution of the HER2-active targeting. In conclusion, TS-MSN are promising nanocarriers for the specific and efficient delivery of siRNA to HER2-overexpressing breast cancer cells.

Versatile electrostatically assembled polymeric siRNA nanovectors: Can they overcome the limits of siRNA tumor delivery?

The application of small interfering RNA (siRNA) cancer therapeutics is limited by several extra- and intracellular barriers including the presence of ribonucleases that degrade siRNA, the premature clearance, the impermeability of the cell membrane, or the difficulty to escape endo-lysosomal degradation. Therefore, several delivery systems have emerged to overcome these limitations and to successfully deliver siRNA to the tumor site. This review is focused on polymer-based siRNA nanovectors which exploit the negative charge of siRNA, representing a major challenge for siRNA delivery, to their advantage by loading siRNA via electrostatic assembly. These nanovectors are easy to prepare and to adapt for an optimal gene silencing efficiency. The ability of electrostatically assembled polymeric siRNA nanovectors (EPSN) to improve the half-life of siRNA, to favor the specificity of the delivery and the accumulation in tumor and to enhance the cellular uptake and endosomal escape for an efficient siRNA delivery will be discussed. Finally, the influence of the versatility of the structure of these nanovectors on the protein down-regulation will be evaluated.

Bacterial cellulose hydrogel loaded with lipid nanoparticles for localized cancer treatment.

The use of hybrid materials, where a matrix sustains nanoparticles controlling the release of the chemotherapeutic drug, could be beneficial for the treatment of primary tumors prior or after surgery. This localized chemotherapy would guarantee high drug concentrations at the tumor site while precluding systemic drug exposure minimizing undesirable side effects. We combined bacterial cellulose hydrogel (BC) and nanostructured lipid carriers (NLCs) including doxorubicin (Dox) as a drug model. NLCs loaded with cationic Dox (NLCs-H) or neutral Dox (NLCs-N) were fully characterized and their cell internalization and cytotoxic efficacy were evaluated in vitro against MDA-MB-231 cells. Thereafter, a fixed combination of NLCs-H and NLCs-N loaded into BC (BC-NLCs-NH) was assayed in vivo into an orthotopic breast cancer mouse model. NLCs-H showed low encapsulation efficiency (48%) and fast release of the drug while NLCs-N showed higher encapsulation (97%) and sustained drug release. Both NLCs internalized via endocytic pathway, while allowing a sustained release of the Dox, which in turn rendered IC50 values below of those of free Dox. Taking advantage of the differential drug release, a mixture of NLCs-N and NLCs-H was encapsulated into BC matrix (BC-NLCs-NH) and assayed in vivo, showing a significant reduction of tumor growth, metastasis incidence and local drug toxicities.

Efficacy and Hemotoxicity of Stealth Doxorubicin-Loaded Magnetic Nanovectors on Breast Cancer Xenografts.

In the field of oncology, research is now focused on the development of theranostic nanosystems that combine the functions of drug delivery and imaging for diagnosis/monitoring. In this context, we designed polyethylene glycol (PEG)ylated superparamagnetic iron oxide nanoparticles (SPIONs) for the delivery of doxorubicin (DOX), an antineoplastic agent. These DOX-loaded PEGylated SPIONs, or DLPS, should be useful for the delivery of DOX in vivo, as well as for magnetic drug targeting (MDT) and magnetic resonance imaging (MRI). The aim of this study was to evaluate the potential applications of DLPS in vivo as drug carrier systems for the reduction of xenograft breast tumors induced in nude mice. Prior to the animal model experiments, the main internalization pathways for the nanovectors in MDA-MB435 breast cancer cells were determined to be based on caveolae- and clathrin-mediated endocytosis. The time- and quantity-dependence of the nanoparticle uptake by the cells altered the in vitro cytotoxicity of the DLPS. The in vitro antiproliferative effect of the DLPS was dependent not only on DOX concentration, but also on the efficacy of nanoparticle internalization. Evaluation of the effect of DLPS treatment on xenograft tumors in nude mice showed that DLPS limited tumor growth in a manner comparable to that of free DOX under normal conditions of tumor growth. The application of an external magnetic field on tumors, i.e., MDT, did not improve the efficacy of the DLPS treatment. Nevertheless, the vectorization of DOX with DLPS appears to limit the hematologic side effects usually associated with DOX treatment.

Design strategies of hybrid metallic nanoparticles for theragnostic applications.

Metallic nanoparticles (MNPs) such as iron oxide and gold nanoparticles are interesting platforms to build theragnostic nanocarriers which combine both therapeutic and diagnostic functions within a single nanostructure. Nevertheless, their surface must be functionalized to be suitable for in vivo applications. Surface functionalization also provides binding sites for targeting ligands, and for drug loading. This review focuses on the materials and surface chemistry used to build hybrid nanocarriers that are inorganic cores functionalized with organic materials. The surface state of the MNPs largely depends on their synthesis routes, and dictates the strategies used for functionalization. Two main strategies can be found in the literature: the design of core-shell nanosystems, or embedding nanoparticles in organic materials. Emerging tendencies such as the use of clusters or alternative coating materials are also described. To present both hydrophilic and lipophilic nanosystems, we chose the doxorubicin anticancer agent as an example, as the molecule presents an affinity for both types of materials.

Recent advances in theranostic nanocarriers of doxorubicin based on iron oxide and gold nanoparticles.

Hybrid (organic/inorganic) nanoparticles emerged as a simple solution to build "theranostic" systems. Due to their physical properties, superparamagnetic iron oxide nanoparticles (SPIONs) and plasmonic gold nanoparticles (Au-NPs) are extensively studied as a part of diagnostic and therapeutic strategies in cancer treatments. They can be used as agents for in vitro or in vivo imaging, for magnetic drug targeting and/or thermal therapy. Their functionalization with organic shells enhances their potential performance in tumor targeting and drug delivery. The advances in such hybrid nanocarriers are well illustrated with the example of the anticancer drug doxorubicin (DOX). The aim of this review is to give a multidisciplinary overview of such smart nanosystems loaded with DOX, based on examples taken from recent publications. From a physico-chemical point of view, we discuss the choices for the strategies for loading DOX and the consequences on drug release. From a biological point of view, we analyze the in vitro and in vivo assays concerning tumor imaging, targeted drug delivery and anticancer efficiency. Future opportunities and challenges are also addressed.

Pegylated magnetic nanocarriers for doxorubicin delivery: a quantitative determination of stealthiness in vitro and in vivo.

The aim of this work was to elucidate the impact of polyethylene glycol (PEG) polymeric coating on the in vitro and in vivo stealthiness of magnetic nanocarriers loaded or not with the anticancer drug doxorubicin. The comparison was made between aqueous suspensions of superparamagnetic iron oxide nanoparticles (SPIONs) stabilized by either citrate ions (C-SPIONs) or PEG(5000) (P-SPIONs), the latter being loaded or not with doxorubicin via the formation of a DOX-Fe(2+) complex (DLP-SPIONs). After determination of their relevant physico-chemical properties (size and surface charge), nanoparticle (NP) stealthiness was studied in vitro (ability to activate the complement system and uptake by monocytes and macrophage-like cells) and in vivo in mice (blood half-life; t(1/2), and biodistribution in main clearance organs). These aspects were quantitatively assessed by atomic absorption spectrometry (AAS). Complement activation dramatically decreased for sterically stabilized P-SPIONs and DLP-SPIONs in comparison with C-SPIONs stabilized by charge repulsion. Monocyte and macrophage uptake was also largely reduced for pegylated formulations loaded or not with doxorubicin. The t(1/2) in blood for P-SPIONs was estimated to be 76 ± 6 min, with an elimination mainly directed to liver and spleen. Thanks to their small size (<80 nm) and a neutral hydrophilic polymer-extended surface, P-SPIONs exhibit prolonged blood circulation and thus potentially an increased level in tumor delivery suitable for magnetic drug targeting applications.