Patent application number | Description | Published |
20090038628 | Smoking articles enhanced to deliver additives incorporated within electroprocessed microcapsules and nanocapsules, and related methods - A large variety of electroprocessed capsules can be produced to encapsulate a variety of additives within the subcompartments or substructures of the manufactured capsule. Furthermore, the manufactured capsules can be arranged within a filter of a smoking article during the manufacturing process. By modifying the various parameters that control the electrospraying or electrospinning processes, capsules can be manufactured that vary in composition, in substructural organization, and in dimension. A capsule produced by electrospraying comprises at least one polymeric material that encapsulates or supports the retention of at least one flavorant and/or non-flavorant within the capsule. A polymeric material provides a supporting structure for encapsulating at least one flavorant and/or non-flavorant additive. The capsules that can be produced by various electrospraying processes described below include microcapsules in a micro-scaled range, nanocapsules in a nano-scaled range, and various mixtures of microcapsules and nanocapsules. | 02-12-2009 |
20100076105 | MONODISPERSE THERMO-RESPONSIVE MICROGELS OF POLY(ETHYLENE GLYCOL) ANALOGUE-BASED BIOPOLYMERS, THEIR MANUFACTURE, AND THEIR APPLICATIONS - Composition, processes, techniques, and apparatus for synthesizing monodisperse microgels based on poly(ethylene glycol) (PEG) derivative polymers by using precipitation polymerization. These microgels are hydrophilic and have the adjustable volume phase transition temperature in aqueous environment. Microgels can be added with various functional groups. These microgels in water can self-assemble into various phases, including a crystalline phase. Hydrogel films with iridescent colors were formed using these microgels as crosslinkers to connect poly(ethylene glycol) chains. The colors of these hydrogel films change with changes of environment such temperature, pH, salt concentration, etc. | 03-25-2010 |
20100247908 | NANOSPINNING OF POLYMER FIBERS FROM SHEARED SOLUTIONS - Nanofibers are fabricated by introducing a polymer solution into a dispersion medium and shearing the dispersion medium. Droplets of the polymer solution are spun into elongated fibers that are insoluble in the dispersion medium. | 09-30-2010 |
20100255059 | Artificial micro-gland - A micro-scale artificial gland is disclosed in the form of an independent unit for promoting biological activity. The artificial gland includes cells formed in a membrane enclosing a reservoir. The reservoir is a bio-reactor capable of containing a product of activity of the cells. The reservoir comprises a gas, a liquid, and a gel and preferably also contains nanoparticles, a buffer, a surfactant, and, a gel precursor. The reservoir may also contain cells. Nanoparticles may also surround the artificial gland to form a protective coating. A variety of methods are disclosed for making the artificial gland by directed assembly of cells into the artificial micro-gland by gel, liquid or bubble templating. All involve coating the surface of gel, droplet or bubble with the living cells and the stabilizing the cells on the surface of gels, droplets or bubbles. | 10-07-2010 |
20100261814 | Synthesis of columnar hydrogel colloidal crystals in water-organic solvent mixture - The compositions of hydrogel colloidal crystals are made from mixing an aqueous suspension of poly-N-isopropylacrylamide (“PNIPAM”)-co-allylamine microgels with dichloromethane, forming a PNIPAM-co-allylamine/dichloromethane mixture. The PNIPAM-co-allylamine/dichloromethane mixture is incubated for a period of time at a given temperature, forming the colloidal crystal material. The colloidal crystals can be stabilized by diffusing a glutaric dialdehyde solution into the colloidal crystal material. The concentration of polymer matrix microgels can determine the orientation of random or columnar crystals. | 10-14-2010 |
20110104777 | Method of making an artificial micro-gland that is anisotropic - A method is disclosed for making an artificial micro-gland having a continuous anisotropic membrane of two or more types of living cells. A first step includes forming a carrier fluid in a microchannel in a laminar flow of two distinct fluid flows. Another step includes introducing a template, which may itself be anisotropic, into the microchannel in a manner such that the template straddles the interface between the first fluid-flow and the second fluid-flow. In some embodiments two types of living cells within the template are separately attracted one of the fluid flows by the presence of an agent of taxis. In other embodiments, cells within one or the other of the fluid flows are attracted to agents within the template. Membranes form on the template and join together to form a complete cellular membrane around a reservoir. | 05-05-2011 |
20110129903 | Method of making an artificial micro-gland using taxis - A method is used for making an artificial micro-gland by taxis. A monodisperse multiple emulsion is produced with a first fluid; a second fluid confined within the first fluid; a third fluid within the second fluid. Interfaces between the fluids permit living cells dispersed in the one of the fluids to migrate towards an adjacent fluid having a different concentration of an agent affecting the metabolic activity of the living cells. Waiting, usually about 30 minutes, allows the living cells to migrate to the interface, forming the continuous membrane. Once formed, the artificial micro-gland is removed from the remains of the emulsion. The artificial micro-gland may also be given a second layer of different cells when the emission of the cells of the artificial micro-gland is used as the agent to attract the different cells. The method may also be used to produce an artificial micro-gland within an artificial micro-gland. | 06-02-2011 |
20130180534 | SMOKING ARTICLES ENHANCED TO DELIVER ADDITIVES INCORPORATED WITHIN ELECTROPROCESSED MICROCAPSULES AND NANOCAPSULES, AND RELATED METHODS - A large variety of electroprocessed capsules can be produced to encapsulate a variety of additives within the subcompartments or substructures of the manufactured capsule. Furthermore, the manufactured capsules can be arranged within a filter of a smoking article during the manufacturing process. By modifying the various parameters that control the electrospraying or electrospinning processes, capsules can be manufactured that vary in composition, in substructural organization, and in dimension. A capsule produced by electrospraying comprises at least one polymeric material that encapsulates or supports the retention of at least one flavorant and/or non-flavorant within the capsule. A polymeric material provides a supporting structure for encapsulating at least one flavorant and/or non-flavorant additive. The capsules that can be produced by various electrospraying processes described below include microcapsules in a micro-scaled range, nanocapsules in a nano-scaled range, and various mixtures of microcapsules and nanocapsules. | 07-18-2013 |
20140060553 | SMOKING ARTICLES ENHANCED TO DELIVER ADDITIVES INCORPORATED WTIHIN ELECTROSPUN MICROFIBERS AND NANOFIBERS, AND RELATED METHODS - A large variety of electrospun fibers can be produced to encapsulate a large variety of additives within the subcompartments or substructures of the manufactured electrospun fiber. Furthermore, the manufactured electrospun fibers can be electrostatically arranged within a filter component of a smoking article during the manufacturing process. By modifying the various parameters that control the electrospinning process, a diverse set of electrospun fibers can be manufactured that vary in composition, in substructural organization, and in dimension. The electrospun fiber produced by electrospinning comprises at least one type of polymeric material that encapsulates or supports the retention of at least one type of a flavorant or a non-flavorant within the electrospun fiber. A polymeric material provides a supporting structure for encapsulating at least one type of a flavorant or a non-flavorant. The electrospun fibers that can be produced by various electrospinning processes described below include microfibers in a micro-scaled range, nanofibers in a nano-scaled range, and various mixtures of microfibers and nanofibers. | 03-06-2014 |