A method of encapsulating content with calcium alginate membrane to form a capsule. The method includes embedding sodium alginate into a traditional gelatin ribbon used in gelatin encapsulation, adding calcium to a fill material, encapsulating the fill material, and then denaturing the gelatin in the shell. An exemplary use of this method is to form throwable paintballs; however, other products could be formed using this process. A paintball formed by this process is also disclosed.

Methods and apparatus are disclosed for producing seeds that are transformed into hollow spheres. A seed includes a core and a coating. Upon heating, the coating becomes viscous and expands responsive to an internal gas pressure created by the core. Example applications for the seeds and/or cores are disclosed, including bricks and other construction materials having the hollow spheres incorporated therein.

The present invention relates to a method for producing core-shell nanocrystals consisting of a metal-containing nanocrystal core and a shell layer comprising at least one metal oxide material having variable shell thicknesses, and use of the core-shell nanocrystals for different applications.

Hollow particles containing monocrystalline titanium oxide and silica, and having a titanium oxide content of 86.0-99.5 mol % and a silica content of 0.5-14.0 mol %; and a method of producing the particles. A white ink containing the hollow particles as a coloring agent; the use of the white ink in inkjet recording; and a method for inkjet recording using the white ink.

The present invention relates to a fire extinguishing micro-capsule, a method for manufacturing the same, and a fire extinguisher using the same. The fire extinguishing micro-capsule has a core-shell structure in which a core includes a liquid fire extinguishing agent and a shell uses a high-density non-porous polymer material. A decapsulation process of the fire extinguishing micro-capsule occurs in a narrow time and temperature range at a rate of at least 150%/min, and the stability of the agent in water and other solvents is significantly increased. A fire extinguisher including the fire extinguishing micro-capsule has increased lifetime and operational efficiency.

A method for controlling the encapsulation efficiency and burst release of water soluble molecules from nanoparticle and microparticle formulations produced by the inverted Flash NanoPrecipitation (iFNP) process and subsequent processing steps is presented. The processing steps and materials used can be adjusted to tune the encapsulation efficiency and burst release of the encapsulated water-soluble material. The encapsulation efficiency of the soluble agent in the particles and the burst release of the soluble agent from the particles can be controlled by: (1) the copolymers used in the assembly or coating process, (2) the degree of crosslinking of the nanoparticle core, (3) the incorporation of small molecule or polymeric additives, and/or (4) the processing and release conditions employed.

Ag—Fe3O4 immunomagnetic microsphere contains poly-D-lysine modified on the surface and S100β and/or MBP antibody linked by an amide bond. The Ag—Fe3O4 immunomagnetic microsphere can specifically capturing peripheral nerve tissue-derived exosomes. When the microsphere is used to extract nerve tissue-derived exosomes, the extraction yield of exosomes per unit volume of nerve tissue is high, and the nerve specificity is strong.

Ag—Fe3O4 immunomagnetic microsphere contains poly-D-lysine modified on the surface and S100β and/or MBP antibody linked by an amide bond. The Ag—Fe3O4 immunomagnetic microsphere can specifically capturing peripheral nerve tissue-derived exosomes. When the microsphere is used to extract nerve tissue-derived exosomes, the extraction yield of exosomes per unit volume of nerve tissue is high, and the nerve specificity is strong.

Microbubble production and size isolation with high yield processing. Specifically, a size isolation process is used in which a diffusion coefficient related to gas diffusion forces acting on microbubbles in suspension is controlled through maintaining diffusion parameters for the suspension. Diffusion parameters may include effective viscosity, which may be a function of microbubble volume fraction. Another diffusion parameter controlled may include temperature. In turn, microbubbles may be size isolated at high yields, which may provide for advantageous microbubble products that demonstrate increased stability for storage.

Methods of synthesizing colloidal ternary Group III-V nanocrystals are provided. Also provided are the colloidal ternary Group III-V nanocrystals made using the methods. In the methods, molten inorganic salts are used as high temperature solvents to carry out cation exchange reactions that convert binary nanocrystals into ternary nanocrystals.