Abstract: A method of forming a voided polymer includes forming a polymerizable composition containing a polymer precursor and a solid templating agent, forming a coating of the polymerizable composition, processing the coating to form a cured polymer material having a solid phase in a plurality of defined regions, and removing at least a portion of the solid phase from the cured polymer material to form a voided polymer layer.

Abstract: Heat-triggered colorants for altering the color of a food, methods for changing the color of a food using heat-triggered colorants, and methods for making heat-triggered colorants for food. The heat-triggered colorants may comprise a mixture comprising a carrier having a melting point and a GRAS (Generally Recognized as Safe) first food colorant having a color, and a coating encapsulating the mixture and masking the color of the first food colorant. When the heat-triggered colorant is exposed to a temperature greater than the melting point of the carrier, the carrier melts and releases the first food colorant, thereby unmasking the color of the first food colorant.

Abstract: An encapsulated material containing an oxidation-sensitive core is covered by at least a dried phospholipid layer, and contains at least one phytosterol in the core, the phospholipid layer or in a further layer or layers. By using microencapsulation, oxidatively unstable materials may be provided with a synthetic protective barrier and rendered less susceptible to oxidative degradation.

Abstract: A method is used to separate fractions from a seed. This can be done by: a) Physically breaking down the Chia seed into smaller particles; b) Adding a liquid carrier to the broken Chia seed to form a Chia liquid carrier blend; c) Optionally providing further processing of the Chia liquid carrier blend to further reduce the particle size of the Chia particles d) Optionally centrifuging the Chia liquid carrier blend; e) Optionally forming at least three discernible layers of materials within the centrifuged Chia liquid carrier blend; f) Optionally separating the composition of at least one layer from remaining layers; and g) Optionally combining the separated layers together into a desired combination/ratios h) Drying the separated layers or combined layers into a flowable powder.

Abstract: A method is used to separate fractions from a seed. This can be done by: a) Physically breaking down the Chia seed into smaller particles; b) Adding a liquid carrier to the broken Chia seed to form a Chia liquid carrier blend; c) Optionally providing further processing of the Chia liquid carrier blend to further reduce the particle size of the Chia particles d) Optionally centrifuging the Chia liquid carrier blend; e) Optionally forming at least three discernible layers of materials within the centrifuged Chia liquid carrier blend; f) Optionally separating the composition of at least one layer from remaining layers; and g) Optionally combining the separated layers together into a desired combination/ratios h) Drying the separated layers or combined layers into a flowable powder.

Abstract: Microencapsulated delivery vehicles comprising an active agent are disclosed. The microencapsulated delivery vehicles may be introduced into products such that, upon activation, the product provides a functional benefit to a substrate, such as a user's skin.

Abstract: A method provides a milled whole seed product from a whole seed having at least 0.01% by total weight of oil therein. The whole seed is added to an aqueous carrier which is physically milled at a shear rate of at least 3,000 r.p.m. The shearing is continued until at least 50% by weight of seed solids will pass through a square mesh screen having 1.2 mm screen hole dimensions. The solids in aqueous carrier is collected as a suspension or dispersion in the aqueous carrier. The collected seed solids in aqueous carrier are dried to form a free-flowing powder. The free-flowing powder is rehydrated with a second aqueous medium to form a non-mucilaginous suspension or dispersion.

Abstract: An article and process provides a stable technology that reduces the microbial content by providing molecular iodine to the stabilized reagents when at least two reactants are activated by aqueous and/or alcohol materials.

Abstract: An encapsulated material containing an oxidation-sensitive core is covered by at least a dried synthetic organelle layer and optional additional ingredients in the organelle layer or additional layers. By using microencapsulation to mimic or otherwise adapt the storage concepts used by seeds to protect triacylglycerol cores, oxidatively unstable materials may be provided with a synthetic, seed-like oxygen-resistant protective barrier and rendered less susceptible to oxidative degradation.

Abstract: An encapsulated material containing an oxidation-sensitive core is covered by at least a dried phospholipid layer, and contains at least one phytosterol in the core, the phospholipid layer or in a further layer or layers. By using microencapsulation, oxidatively unstable materials may be provided with a synthetic protective barrier and rendered less susceptible to oxidative degradation.

Abstract: An encapsulated material is formed by congealing droplets of a molten blend of oxidatively unstable material and phytosterol in a chilling gas stream to form prilled cores containing oxidatively unstable material and phytosterol, and encapsulating the prilled cores in one or more protective shell layers to form free-flowing microparticles.

Abstract: A method provides a redispersible nanoparticle powder. The method includes: a) providing within a liquid carrier a first dispersion of nanoparticles having surface hydroxyl groups; b) adding a non-metal-ester molecular reactant for the hydroxyl group into the liquid carrier; c) reacting the reactant with the hydroxyl group to form individual, non-continuous sites having reaction product of the hydroxyl group and the reactant to form a surface treated nanoparticle; and d) drying the surface treated nanoparticle to at least reduce the presence of any excess non-metal-ester molecular reactant and providing non-aggregated powder of the surface treated nanoparticles such that when the dried, treated nanoparticle powder is redispersed as a second dispersion in a carrier or solvent having affinity for the non-metal-ester reactant product, a nano-sized particle is formed.

Abstract: Heat-triggered colorants for altering the color of a food, methods for changing the color of a food using heat-triggered colorants, and methods for making heat-triggered colorants for food. The heat-triggered colorants may comprise a mixture comprising a carrier having a melting point and a GRAS (Generally Recognized as Safe) first food colorant having a color, and a coating encapsulating the mixture and masking the color of the first food colorant. When the heat-triggered colorant is exposed to a temperature greater than the melting point of the carrier, the carrier melts and releases the first food colorant, thereby unmasking the color of the first food colorant.

Abstract: A method for polishing a wafer comprising an aqueous solution having a pH in the range of 6 to 8, wherein the aqueous solution comprises at least one compound selected from the group consisting of a polymethacrylic acid, a polysulfonic acid, and combinations thereof, and wherein the compound is present in the range of 1.5 to 4 percent by weight of the aqueous solution. The wafer polishing solution can be adjusted to control cut rate and selectivity for modifying semiconductor wafers using a fixed abrasive CMP process.

Abstract: An article and process provides a stable technology that reduces the microbial content by providing molecular iodine to the stabilized reagents when at least two reactants are activated by aqueous and/or alcohol materials.

Abstract: Microencapsulated delivery vehicles comprising an active agent are disclosed. The microencapsulated delivery vehicles may be introduced into products such that, upon activation, the product provides a functional benefit to a substrate, such as a user's skin.

Abstract: Microencapsulated delivery vehicles comprising an active agent are disclosed. In one embodiment, the microencapsulated delivery vehicles are heat delivery vehicles capable of generating heat upon activation. The microencapsulated heat delivery vehicles may be introduced into wet wipes such that, upon activation, the wet wipe solution is warmed resulting in a warm sensation on a user's skin. Any number of other active ingredients, such as cooling agents and biocides, can also be incorporated into a microencapsulated delivery vehicle.

Abstract: A wafer polishing solution and method for polishing a wafer comprising an amino acid and calcium ions or barium ions. The wafer polishing solution can be adjusted to control cut rate and selectivity for modifying semiconductor wafers using a fixed abrasive CMP process.

Abstract: A wafer polishing solution and method for polishing a wafer comprising an amino acid and calcium ions or barium ions. The wafer polishing solution can be adjusted to control cut rate and selectivity for modifying semiconductor wafers using a fixed abrasive CMP process.

Abstract: The present invention provides an optical fluorescence based sensor for measuring the concentration of a gas (e.g., CO2 or ammonia) in a medium such as blood which has superior dry web sensor performance, enhanced sensor consistency for transparent sensor calibration, improved autoclave stability and rapid rehydration of the sensor. In a preferred embodiment, the sensors of the present invention comprise microcompartments of an aqueous phase having a pH sensitive indicator component and a nonionic amphipathic surfactant within a hydrophobic barrier phase comprising a plurality of dispersed hydrophobic particles.