Interfering with endolysosomal trafficking enhances release of bioactive exosomes.

Exosomes are cell-derived extracellular vesicles of 30-150 nm in size and are involved in intercellular communication. Because of their bioactive cargo, consisting of proteins, RNA and lipids, and their natural ability to deliver these biomolecules to recipient cells, exosomes are increasingly being studied as novel drug delivery vehicles or as cell-free approaches to regenerative medicine. However, one of the major hurdles for clinical translation of therapeutic strategies based on exosomes is their low yield when produced under standard culture conditions.

Liposomal prednisolone inhibits tumor growth in a spontaneous mouse mammary carcinoma model.

Cancers are abundantly infiltrated by inflammatory cells that are modulated by tumor cells to secrete mediators fostering tumor cell survival and proliferation. Therefore, agents that interfere with inflammatory signaling molecules or specific immune cell populations have been investigated as anticancer drugs. Corticosteroids are highly potent anti-inflammatory drugs, whose activity is intensified when targeted by nanocarrier systems.

Display of GPI-anchored anti-EGFR nanobodies on extracellular vesicles promotes tumour cell targeting.

Background: Extracellular vesicles (EVs) are attractive candidate drug delivery systems due to their ability to functionally transport biological cargo to recipient cells. However, the apparent lack of target cell specificity of exogenously administered EVs limits their therapeutic applicability. In this study, we propose a novel method to equip EVs with targeting properties, in order to improve their interaction with tumour cells.

An in situ gelling liquid crystalline system based on monoglycerides and polyethylenimine for local delivery of siRNAs.

The development of delivery systems able to complex and release siRNA into the cytosol is essential for therapeutic use of siRNA. Among the delivery systems, local delivery has advantages over systemic administration. In this study, we developed and characterized non-viral carriers to deliver siRNA locally, based on polyethylenimine (PEI) as gene carrier, and a self-assembling drug delivery system that forms a gel in situ.

A solid-phase platform for combinatorial and scarless multipart gene assembly.

With the emergence of standardized genetic modules as part of the synthetic biology toolbox, the need for universal and automatable assembly protocols increases. Although several methods and standards have been developed, these all suffer from drawbacks such as the introduction of scar sequences during ligation or the need for specific flanking sequences or a priori knowledge of the final sequence to be obtained. We have developed a method for scarless ligation of multipart gene segments in a truly sequence-independent fashion.

Biodistribution of polymer hydrogel capsules for the delivery of therapeutics.

A key phase in the development of intelligently designed nanoparticle delivery vehicles for new therapeutic agents is to gain an understanding of their interaction with tissues and cells. We report a series of in vitro and in vivo experiments aimed at tracking a potential delivery vehicle for therapeutic agents, including vaccine peptides and drugs derived from poly(methacrylic acid) hydrogel capsules in certain organs and cell types. For the in vitro studies, two immortal liver-derived cell lines (Huh7 and Hepa1-6) and primary cultures of mouse hepatocytes were incubated with Alexa 647 labelled fluorescent capsules to track their internalization and intracellular distribution by confocal microscopy.

Exosome mimetics: a novel class of drug delivery systems.

The identification of extracellular phospholipid vesicles as conveyors of cellular information has created excitement in the field of drug delivery. Biological therapeutics, including short interfering RNA and recombinant proteins, are prone to degradation, have limited ability to cross biological membranes, and may elicit immune responses. Therefore, delivery systems for such drugs are under intensive investigation.

The involvement of a Na⁺- and Cl⁻-dependent transporter in the brain uptake of amantadine and rimantadine.

Despite their structural similarity, the two anti-influenza adamantane compounds amantadine (AMA) and rimantadine (RIM) exhibit strikingly different rates of blood-brain barrier (BBB) transport. However, the molecular mechanisms facilitating the higher rate of in situ BBB transport of RIM, relative to AMA, remain unclear. The aim of this study, therefore, was to determine whether differences in the extent of brain uptake between these two adamantanes also occurred in vivo, and elucidate the potential carrier protein facilitating their BBB transport using immortalized human brain endothelial cells (hCMEC/D3).