Polyoxazolines with Cholesterol Lipid Anchor for Fast Intracellular Delivery.

Due to the increasing challenges posed by the growing immunity to poly(ethylene glycol) (PEG), there is growing interest in innovative polymer-based materials as viable alternatives. In this study, the advantages of lipids and polymers are combined to allow efficient and rapid cytoplasmic drug delivery. Specifically, poly(2-methyl-2-oxazoline) is modified with a cholesteryl hemisuccinate group as a lipid anchor (CHEMSPOx).

Surface modification of extracellular vesicles with polyoxazolines to enhance their plasma stability and tumor accumulation.

Extracellular vesicles (EVs) are future promising therapeutics, but their instability in vivo after administration remains an important barrier to their further development. Many groups evaluated EV surface modification strategies to add a targeting group with the aim of controlling EV biodistribution. Conversely, fewer groups focused on their stabilization to obtain "stealth" allogenic EVs.

Regulations on excipients used in 3D printing of pediatric oral forms.

A promising solution to customize oral drug formulations for the pediatric population has been found in the use of 3D printing, in particular Fused Deposition Modeling (FDM) and Semi-Solid Extrusion (SSE). Although formulation development is currently limited to research studies, the rapid advances in 3D printing warn of the need for regulation. Indeed, even if the developed formulations include pharmaceutical excipients used to produce traditional oral forms such as tablets, the quantities of excipients used must be adapted to the process.

Various lipid anchors on amphiphilic polyoxazolines to reach efficient intracellular delivery.

This work aimed at evaluating the potential of amphiphilic polyoxazolines bearing lipid chain called lipopolyoxazolines to reach efficient intracellular delivery. Four lipid chains: linear saturated, linear unsaturated and two branched one of various length were associated to poly(2-methyl-2-oxazoline) block. The evaluation of their physicochemical features and their impact on cell viability and internalization capacity indicated that the linear saturated gathered the highest cell internalization with a good cell viability.

Interactions of amphiphilic polyoxazolines formulated or not in lipid nanocapsules with biological systems: Evaluation from membrane models up to in vivo mice epidermis.

In this study, we evaluated the potential of amphiphilic polyoxazolines (POx) to interact with biological membranes thanks to models of increasing complexity, from a simple lipid bilayer using giant unilamellar vesicles (GUV), to plasma membranes of three different cell types, fibroblasts, keratinocytes and melanocytes, which are found in human skin. Upon assessing an excellent penetration into GUV membranes and cultured cells, we addressed POx's potential to penetrate the murine skin within an in vivo model. Exposure studies were made with native POx and with POx encapsulated within lipid nanocapsules (LNC).