Provided are stem cell biomimetic microparticles comprised of at least one stem cell-derived paracrine polypeptide or growth factor embedded in a polymer core particle that further comprises an outer layer of at least one fragment of a cell membrane of a stem cell disposed on the core particle. The polymer core may be constituted of any biocompatible and biodegradable polymer or copolymer, or a combination thereof that allows the embedding of the paracrine factors and their prolonged release from the core. The core and hence the microparticles can be biodegradable, allowing eventual elimination from the recipient animal or human subject. The core particles are sized to allow both transport through blood vessels and extravasation from the blood vessels into the surrounding tissues. The core particle may further include at least one polypeptide or peptide growth factor to induce the generation and proliferation of a population of stem cells.

Processes for producing polymer microcapsules using vicinal functional oligomers are also described. The vicinal functional oligomers can be made by polymerizing an acrylate monomer, a styrene monomer, or both in the presence of a chain transfer agent. The vicinal functional oligomers can be reacted with epichlorohydrin to form vicinal epoxies. The vicinal epoxies can be reacted with polyamines to form epoxy polymer microspheres. The vicinal epoxies can be reacted with carbon dioxide in the presence of a catalyst to form vicinal cyclic carbonates. The vicinal cyclic carbonates can be reacted with polyamines to form isocyanate-free polymer microspheres. Polymer microspheres made by the processes are also described.

The present invention relates to a process for the production of multilayer microcapsules, in particular multilayer odiferous substance capsules or fragrance compound capsules, which have improved stability and odiferous substance release or fragrance compound release compared to prior art capsules. In addition, the present invention relates to multilayer microcapsules comprising at least one hydrophobic odiferous substance or fragrance compound obtainable by the process of the invention. In another aspect, the invention described herein relates to multilayer microcapsules comprising a core comprising at least one hydrophobic odiferous substance or fragrance compound, and a capsule shell. In addition, the present invention relates to the use of the multilayer microcapsules and suspensions of the multilayer microcapsules as an ingredient in detergents, fabric softeners, cleaning products, scent boosters in liquid or solid form, cosmetics, personal care products, agricultural products or pharmaceutical products.

A facilitated method for use in efficient delivery of a pharmaceutical composition over a tissue such as the blood brain barrier and into neurons in the CNS for the treatment of Alzheimer's disease in a mammal, including man is provided. The method is comprising the steps of administrating a therapeutically effective amount of the isolated recombinant Bri2 BRICHOS and lipid microbubbles and enables an increased amount of the isolated recombinant protein to reach the brain to efficiently combat Aβ42 neurotoxicity.

Furthermore, a method for use in enhanced delivery of proteins comprising Bri2 BRICHOS and variants thereof over the blood-brain barrier, facilitating treatment and/or diagnostics of Alzheimer's disease and other neurological diseases is described herein. The method is comprising the steps of administrating a therapeutically effective amount of proteins comprising Bri2 BRICHOS and variants thereof as a first protein moiety coupled to another (non-Bri2) second protein or polypeptide moiety and optionally lipid microbubbles, in the absence of ultrasound treatment.

Compositions that increase the bioavailability of dihydromyricetin are presented. The bioavailability is increased by methods including formulating dihydromyricetin in nanoparticle form, delivering dihydromyricetin with permeabilizers, and encapsulating dihydromyricetin with an enteric coating.

An implantable device for delivery of a macromolecular drug compound is provided. The device comprises a core having an outer surface and a membrane layer positioned adjacent to the outer surface of the core. The core comprises a core polymer matrix within which is dispersed a drug compound having a molecular weight of about 0.5 kDa or more, the polymer matrix containing a hydrophobic polymer. Further, the membrane layer comprises a membrane polymer matrix within which the macromolecular drug compound is optionally dispersed. The concentration of the macromolecular drug compound in the core is greater than the concentration of the macromolecular drug compound in the membrane layer.

An implantable device for delivery of a macromolecular drug compound is provided. The device comprises a core having an outer surface and a membrane layer positioned adjacent to the outer surface of the core. The core comprises a core polymer matrix within which is dispersed a drug compound having a molecular weight of about 0.5 kDa or more, the polymer matrix containing a hydrophobic polymer. Further, the membrane layer comprises a membrane polymer matrix within which the macromolecular drug compound is optionally dispersed. The membrane polymer matrix contains a hydrophobic polymer in combination with a hydrophilic compound, and the weight ratio of the hydrophobic polymer to the hydrophilic compound within the membrane polymer matrix ranges from about 0.25 to about 200.

The present invention provides polymers, particles, and compositions thereof that selectively and efficiently deliver various therapeutic agents, such as metabolites, to a cell. The present invention further relates to methods relating to the said polymers, particles, and compositions for enhancing biological tissue growth (e.g. biological tissue regeneration in wound healing) in a subject. The present invention additionally provides kits that find use in the practice of the methods of the invention.

An encapsulated bacteriophage formulation and a method for encapsulating bacteriophages and bacteriophage-related products in polymeric microcapsules is provided. Some embodiments of the method of producing the encapsulated bacteriophages involves a water-in-oil-in-water double emulsion.

The present disclosure relates to microcapsules, methods of using such microcapsules in the delivery of drugs and probiotic microbes to subjects in need thereof, and methods of using such microcapsules for in vitro culture of microbes. In particular, the microcapsules comprise novel siloxane-based membranes that maintains transport properties essential to communication and growth of microbes.