Provided are a gene carrier using cell-derived nanovesicles and a method for preparing the same. The gene carrier prepared by inserting a gene into the nanovesicles artificially outbudded from a plasma membrane has excellent delivery efficiency to a target organ and cells, induces long-term regulation of gene expression, and facilitates mass production due to a simple preparation process, and thus can be used as a core technique for the gene or cell therapeutic agent field.

A method for intracellular delivery of single proteins or other cargo molecules by encapsulation within nanocapsules formed by interfacial polymerization of one or more types of monomers and selected protease cleavable cross-linkers is provided. The thin positively charged capsules are readily brought into the cytosol of target cells by endocytosis. The capsules are degraded by the action of endogenous proteases or co-delivered proteases on the cross-linkers releasing the functional cargo unaltered. The cross-linkers can be adapted to be cleavable by specific enzymes selected from available intracellular enzymes within the target cell or co-delivered or self-cleaving when the cargo itself is a protease. The nanocapsules produced by the methods have been shown to have long-term stability, high cell penetration capability, low toxicity and efficient protease-modulated specific degradability without affecting cargo protein function.

A process for obtaining compositions constituted by propolis nanoparticles is disclosed. The nanoparticles are optionally associated to a substance of interest such as active ingredients, and, optionally, substances of secondary effect such as synergists and adjuvants. The process includes preparing a fraction A, which consists of propolis extract dissolved in an organic solvent, to which stabilizer and/or emulsifier may be added, and, optionally, substances of interest and/or of secondary effect; ii) preparing a fraction B, aqueous phase, constituted by: (ii.1) water; or (ii.2) an aqueous solution or dispersion, to which stabilizer and/or emulsifier may be added; (iii) dropping the fraction A onto the fraction B or vice versa; iv) homogenizing the mixture by stirring and spontaneous formation of nanoparticles with average size from 1 to 1000 nm in a dispersion; and v) optionally (v-1) removing organic solvent and/or (v-2) drying the nanodispersion.

The invention relates to the field of analgesics. According to the invention, a kit or composition, particularly a pharmaceutical composition or a pharmaceutical kit, is provided, comprising a nanocarrier which is a hyperbranched polymer, such as a dendritic polymer or dendrimer, preferably having a molecular weight of 1,000-100,000 g/mol, and an analgesic which, when administered without nanocarrier, has both peripheral and central analgesic effect, preferably an opioid such as nalbuphine. According to the invention, the analgesic in this composition mainly or exclusively has a peripheral effect and thus reduces side effects triggered by the activation of central or intestinal opioid receptors. It is used for the treatment of peripheral pain and/or inflammation. The invention also relates to particularly suitable nanocarriers.

The present invention relates to a biodegradable multilayer nanocapsule for the delivery of at least one biologically active agent into at least one target cell consisting of at least two layers of at least two biodegradable polymers which are laid one onto the other and whereby the biologically active agent is layered onto a layer of a biodegradable polymer and covered with a further layer of a biodegradable polymer, whereby one biologically active agent is a nucleic acid.

Methods for efficient preparation of drug-polymer (or oligomer) conjugates useful in the preparation of particles, including microparticles and nanoparticles, for delivery of the drug in vivo for therapeutic applications are provided. The invention also provides nanoparticles prepared by nanoprecipitation using drug-polymer/oligomer conjugates of the invention. The drug conjugates are formed during polymerization of the polymer or oligomer in which the drug is employed as an initiator of the polymerization of the monomers which form the polymer and/or oligomer. More specifically, the drug conjugates are formed by ring-opening polymerization of cyclic monomers in the presence of an appropriate ring-opening polymerization catalyst and the initiator (the drug). The method is particularly useful for formation of polymer/oligomer conjugates with drugs and other chemical species containing one or more hydroxyl groups or thiol groups.

The present invention provides a composition and an antiviral drug preparation, each comprising at least one water-insoluble antiviral drug and at least one water-soluble carrier material, wherein the water-insoluble antiviral drug is dispersed through the water-soluble carrier material in nano-disperse form. The present invention further provides processes for preparing the compositions and drug preparations, and also aqueous nano-dispersions obtained by combining water and the compositions.

A method of preparing Adansonia digitata nanoparticles includes dissolving Adansonia digitata plant powder in an organic solvent to form a solution; spraying the solution in boiling water while applying ultrasonic energy to form a mixture; and stirring the mixture for at least about 15 minutes at a speed of about 200-800 rpm to obtain the Adansonia digitata nanoparticles.

The invention relates to a continuous method for producing inorganic or organic nanoparticles having multiple nuclei functionalised with proteins, using a T-type reactor that operates at high pressure, the primary particles that form the nuclei of the nanoparticles being smaller than 10 nm and said primary particles being immersed in a proteinaceous matrix that forms the nanoparticle in sizes of between 30 nm and 500 nm. The invention also relates to the nanoparticles produced by means of said method.

Novel siRNA and shRNA nanocapsules and delivery methods are disclosed herein. These siRNA and shRNA nanocapsules and delivery methods are highly robust and effective. This invention provides a platform for RNAi delivery with low toxicity and long intracellular half-life for practical therapeutic applications.