Nano-ghosts: Novel biomimetic nano-vesicles for the delivery of antisense oligonucleotides.

Antisense oligonucleotides (ASOs) carry an enormous therapeutic potential in different research areas, however, the lack of appropriate carriers for their delivery to the target tissues is hampering their clinical translation. The present study investigates the application of novel biomimetic nano-vesicles, Nano-Ghosts (NGs), for the delivery of ASOs to human mesenchymal stem cells (MSCs), using a microRNA inhibitor (antimiR) against miR-221 as proof-of-concept. The integration of this approach with a hyaluronic acid-fibrin (HA-FB) hydrogel scaffold is also studied, thus expanding the potential of NGs applications in regenerative medicine. The study shows robust antimiR encapsulation in the NGs using electroporation and the NGs ability to be internalized in MSCs and to deliver their cargo while avoiding endo-lysosomal degradation. This leads to rapid and strong knock-down of miR-221 in hMSCs in vitro, both in 2D and 3D hydrogel culture conditions (>90% and > 80% silencing efficiency, respectively). Finally, in vivo studies performed with an osteochondral defect model demonstrate the NGs ability to effectively deliver antimiR to endogenous cells. Altogether, these results prove that the NGs can operate as stand-alone system or as integrated platform in combination with scaffolds for the delivery of ASOs for a wide range of applications in drug delivery and regenerative medicine.

Nano-Ghosts: Biomimetic membranal vesicles, technology and characterization.

Currently, nano-carriers for anti-cancer drug delivery are complex systems, which struggle with immunogenicity and enhanced permeability effect (EPR)-related problems that halt the clinical translation of many therapeutics. Consequently, a rapidly growing field of research has been focusing on biomimetic nano-vesicles (BNVs) as an effective delivery alternative. Nevertheless, the translation of many BNVs is limited due to scalability problems, inconsistent production process, and insufficient loading efficiency. Here we discuss the process of our previously published BNVs, termed Nano-Ghosts (NGs), which are produced from the membrane of mesenchymal stem cells. We demonstrate the flexibility of the process, while alternating physical methodologies (sonication or extrusion) to produce the NGs while preserving their desired characteristics. We also show that our NGs can be labeled using multiple methods (fluorescence, radiolabeling, and genetic engineering) for tracking and diagnostic purposes. Lastly, we demonstrate that the loading efficiency can be improved by using electroporation to accommodate a range of therapeutics (small molecules, peptides and DNA) that can be delivered by the NGs. Our results emphasize the robustness of the NGs technology, its versatility and a vast range of applications, differentiating it from other BNVs and leading the way towards clinical translation.

Radiolabeling of cell membrane-based nano-vesicles with 14C-linoleic acid for robust and sensitive quantification of their biodistribution.

The rapid development of biomimetic cell membrane-based nanoparticles is still overshadowed by many practical challenges, one of which is the difficulty to precisely measure the biodistribution of such nanoparticles. Currently, this challenge is mostly addressed using fluorescent techniques with limited sensitivity, or radioactive labeling methods, which rarely account for the nanoparticles themselves, but their payloads instead. Here we report the development of a robust method for the innate radioactive labeling of cells and membrane-based nanoparticles and their consequent sensitive detection and biodistribution measurements. The preclinical potential of this method was demonstrated with Nano-Ghosts (NGs), manufactured from the cytoplasmic membranes of mesenchymal stem cells cultured with radioactively-labeled linoleic acid and achieving a cell labeling efficiency of 36%. Radiolabeling did not affect the physiochemical properties of the NGs, which stably retained their radiolabels. Using radioactivity measurements, we are now able to determine precisely the amount of NGs uptaken by tissues and cells, thereby providing further support to our presumed active NG targeting mechanisms. Biodistribution studies comparing radiolabeled NGs to fluorescently-labeled ones have validated our method and revealed new information, which could not be obtained otherwise, regarding the NGs' unique kinetics and rapid clearance, supporting their excellent safety profiles. The reported approach may be expanded to other membrane-based entities to facilitate and hasten their preclinical development and be used in parallel with other labeling methods to provide different and additional information.