A process for forming microspheres is disclosed. The process includes contacting a solvent with a modified cellulose to form a solution; contacting the modified cellulose solution with at least one bioactive agent to form a discontinuous phase liquid; contacting the discontinuous phase liquid with a continuous phase liquid to form an emulsion; and contacting the emulsion with a third phase liquid to extract the solvent from the emulsion, thereby forming a plurality of modified cellulose microspheres.

The present application provides for water capsules, preparation methods of water capsules, a preparation method for lightweight concrete and a structure of lightweight concrete. Each of the water capsules comprises an alkali-sensitive shell and water inside; the water capsules are used to mix with a cementitious matrix, the water capsules can survive during concrete mixing and transportation processes but then gradually rupture in hardened concrete; the water released during the hardening of the concrete is beneficial for the hydration of the concrete. The water capsules and their preparation method, the preparation method for and structure of the lightweight concrete of the present application are of unique design and strong practicability.

A porous microsphere and a method for preparing the same includes the following steps. A copolymer having a vinylbenzyl chloride unit and a vinylbenzyl alcohol unit is dissolved in an organic solvent, and inorganic particles are dispersed in the organic solvent to form a mixed suspension. An aqueous solution containing a surfactant is provided. The mixed suspension is emulsified in the aqueous solution to form an emulsion. The emulsion is heated to evaporate the organic solvent to obtain inorganic-composite porous microspheres suspended in water. The copolymer in the formed porous microspheres can be further carbonized or removed to produce inorganic-based porous microspheres containing carbon or not containing carbon.

The present invention provides a capsule that is capable of suppressing volatilization of a highly volatile capsule content through the capsule shell and that is breakable. A breakable seamless capsule for a smoking equipment, comprising a content containing an oily ingredient and a capsule shell for encapsulating said content, wherein: the capsule shell contains a polysaccharide; the thickness of the capsule shell is 60 m or more; the volatilization content (VC) of the content after leaving the content to stand under an environment at a temperature of 25 C. and a relative humidity of 40% for 4 hours is 3.0 wt % or more with respect to the total weight of the encapsulated content; and the crush strength per diameter of the capsule is 3-8 N/mm.

Systems and methods for preparing encapsulant-containing polymer capsules and fibers, as well as the encapsulant-containing polymer capsules and fibers and composites including the same are described. In one example, forming a plurality of encapsulant-containing polymer capsules includes preparing a mixture comprising a polymer, a solvent, an encapsulant, and a polymer that is soluble in the solvent, and removing some of the solvent from the mixture to yield the plurality of polymer capsules. Each polymer capsule include a shell formed of the polymer and contains the encapsulant. In another example, forming a plurality of polymer fibers containing an encapsulant includes providing the mixture to an electrospin apparatus and electrospinning the mixture to yield the plurality polymer fibers, where each polymer fiber defines a hollow core that contains the encapsulant.

The present invention provides a capsule that is capable of suppressing volatilization of a highly volatile capsule content through the capsule shell and that is breakable.

A breakable seamless capsule for a smoking equipment, comprising a content containing an oily ingredient and a capsule shell for encapsulating said content, wherein: the capsule shell contains a polysaccharide; the thickness of the capsule shell is 60 m or more; the volatilization content (VC) of the content after leaving the content to stand under an environment at a temperature of 25 C. and a relative humidity of 40% for 4 hours is 3.0 wt % or more with respect to the total weight of the encapsulated content; and the crush strength per diameter of the capsule is 3-8 N/mm.

The present invention provides polymersomes comprising amphiphilic block-copolymers and their use to quantify ammonia in samples (e.g., body fluid samples). More particularly, it provides a polymersome comprising (a) a membrane, which comprises a block copolymer of poly(styrene) (PS) and poly(ethylene oxide) (PEO), wherein the PS/PEO molecular weight ratio is higher than 1.0 and lower than 4.0; and (b) a core which encloses an acid and at least one pH-sensitive dye. Compositions, strips and kits comprising the polymersomes are also provided along with methods of quantifying ammonia in a sample using the polymersomes, compositions and kit.

The present disclosure is a cationic electrodeposition coating composition comprising an emulsion particle (A) containing a Michael addition reaction donor component and an emulsion particle (B) containing a Michael addition reaction acceptor component wherein a Michael addition reaction catalyst (C) is contained in the emulsion particle (A) or the emulsion particle (B) or is contained in the cationic electrodeposition coating composition by being microencapsulated.

Methods of making personal care compositions including microcapsules and methods of enhancing the efficacy of the microcapsules in said personal care compositions.

Methods and devices for producing a population of liposomes are provided. Aspects of the methods include applying a centrifugal force to a suspension of liposomes in a manner sufficient to pass the liposomes through a porous membrane to produce a population of liposomes. Aspects of the invention further include devices, systems and kits useful for performing the methods.