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.

The present disclosure provides extended release trihexyphenidyl compositions suitable for once- or twice-daily administration. The compositions comprise a core comprising organic acid that is coated with at least one drug layer comprising trihexyphenidyl hydrochloride, and a functional coat over the drug-layered core. The extended release compositions of the disclosure provide extended release of trihexyphenidyl hydrochloride, with reduced C.sub.max, and a C.sub.min:C.sub.max ratio of ≥0.4, while maintaining a therapeutically effective concentration for a period of at least about 16 hours. The compositions of the disclosure improve solubility of trihexyphenidyl hydrochloride, at a pH of greater than or equal to 5, to maintain its minimum effective concentration at such pH. In certain embodiments, the compositions of the disclosure comprise an IR drug layer to provide extended release with a minimal lag time, while maintaining a therapeutically effective concentration of trihexyphenidyl hydrochloride for a period of at least about 16 hours.

The application relates to the use of loaded red blood cells (e.g. “RBCs”, “red cells” or “erythrocytes”) or red blood cell precursors to produce red cell extracellular vesicles (RCEVs) containing cargos, including cargos comprising biologically active ingredients. Notable red cell precursors include hematopoietic stem cells (HSCs), induced pluripotent stem cells (iPSCs), and reticulocytes. The cargo may comprise nucleic acids, proteins, small molecules, or components of a gene editing system, including CRISPR/Cas9. The RCEVs may be used to treat of diseases and disorders including autoimmune disorders, cancers, cardiovascular diseases, gastrointestinal diseases, genetic disorders, or inflammatory diseases. The RCEVs may also be used to carry antigens and or immune modulator, for use in eliciting immune or immune tolerance responses. Also provided are methods for producing cargo loaded RCEVs (CLRCEVs) by first loading cargo into red cells and then by vesiculating the cargo loaded red cells to yield the CLRCEVs.

The disclosure features pharmaceutical compositions formed from prodrug dimers for the extended delivery of a drug and for the treatment of a disease or condition.

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.

There is provided a process for the preparation of composition in the form of a plurality of particles having a weight-, number-, and/or volume-based mean diameter that is between amount 10 nm and about 700 μm, which particles comprise: (a) solid cores, preferably comprising a biologically active agent; and (b) two or more sequentially applied, discrete layers, each of which comprises at least one separately applied coating material, and which two or more layers together surround, enclose and/or encapsulate said cores, which process comprises the sequential steps of: (1) applying an initial layer of at least one coating material to said solid cores by way of a gas phase deposition technique; (2) discharging the coated particles from the gas phase deposition reactor and subjecting the coated particles to agitation to disaggregate particle aggregates formed during step (1) by way of mechanical sieving technique; (3) reintroducing the disaggregated, coated particles from step (2) into the gas phase deposition reactor and applying a further layer of at least one coating material to the reintroduced particles; and (1) optionally repeating steps (2) and (3) one or more times to increase the total thickness of the at least one coating material that enclose(s) said solid core. The gas phase deposition technique is preferably atomic layer deposition. When the cores comprise biologically active agent, the compositions may provide for the delayed or sustained release of said active agent without a burst effect.

Provided is a granule in which an unpleasant taste of an active ingredient is masked and immediate release of the active ingredient is maintained, and a method for producing the granule. In particular, provided is the granule containing zinc acetate as an active ingredient having an unpleasant taste, and a method for producing the granule.

A method for producing a granule in which an unpleasant taste of an active ingredient is masked and immediate release of the active ingredient is maintained. The method includes a step (1) of obtaining a core particle containing an active ingredient having an unpleasant taste, a step (2) of coating a surface of the core particle obtained in the step (1) with ethylcellulose to obtain a particle, and a step (3) of subjecting the particle obtained in the step (2) to a heat treatment in a closed state.

The present disclosure provides for compositions, articles including the composition, and articles and structures having a superhydrophobic, a superoleophobic, or an omniphobic surface after disposing the composition onto a surface of the article or structure. In general, the composition includes a fluid and a plurality of composite particles having a hydrophilic core and hydrophobic agents on the surface of the hydrophilic core. The composition can be processed so that the composite particles are dispersible in water, while generating a superhydrophobic, superoleophobic, or omniphobic surface upon application.

Provided is a manufacturing method of particles coated with coatable microparticles. The method is a manufacturing method of particles coated with coatable microparticles, comprising the step of adding the coatable microparticles to an inner core comprising a component of interest and a macromolecule, and, while rolling the mixture, coating the mixture while spraying a solvent that can dissolve the macromolecule, wherein the particles coated with the coatable microparticles are coated, component of interest-containing hollow particles.

A particle includes at least one or more kinds of substrate and lipid nanoparticles. The lipid nanoparticles are dispersed in the substrate and contain a physiologically active substance. The lipid nanoparticles are one or more kinds selected from liposomes, lipid emulsions, and solid lipid nanoparticles. A corresponding powder inhalant contains the particle. A production method for the particle includes granulating and drying, in which a suspension containing the substrate and the lipid nanoparticles are granulated and dried in a gas medium.