A method for encapsulating active ingredients in liposomes having an active ingredient solution encapsulated with a bilayer composed of two monomolecular layers of a first and a second amphiphilic compound, wherein the method comprises: (a) providing the active ingredient solution; (b) providing an emulsion by emulsifying the active ingredient solution in a first liquid in the presence of the first amphiphilic compound; (c) providing a mixture with a liquid phase with the second amphiphilic compound; (d) contacting the first emulsion with the mixture to form a phase boundary; and (e) centrifuging the first emulsion and the mixture wherein, on passage of the phase boundary, the second amphiphilic compound enriched there is added onto the monomolecular inner layer of the pre-liposomes to form a monomolecular outer layer, in order to create the bilayer.

Provided are an irreversibly discoloring pigment for preventing overheating, a thermochromic molded article including the same, and a method of preparing the same, and more particularly, a discoloring pigment which becomes discolored when overheated, and then maintains the discoloration even after being cooled to room temperature, a thermochromic molded article including the discoloring pigment, and methods of preparing the discoloring pigment and the thermochromic molded article.

The disclosure provides methods and compositions for 3D printing using thermochromic additives. Thermochromic dyes change absorptivity with heat to selectively attenuate light transmission and control cure depth during 3D printing photopolymerization.

The present invention relates to a polyamide composition (PC) which comprises at least one polyamide (P) and at least one additive (A). The present invention further relates to the use of the polyamide composition (PC) in a selective laser sintering process, in an injection molding process, for producing molded articles and in an extrusion process.

The present invention discloses the morphology of hollow, double-shelled submicrometer particles generated through a rapid aerosol-based process. The inner shell is an essentially hydrophobic carbon layer of nanoscale dimension (5-20 nm), and the outer shell is a hydrophilic silica layer of approximately 5-40 nm, with the shell thickness being a function of the particle size. The particles are synthesized by exploiting concepts of salt bridging to lock in a surfactant (CTAB) and carbon precursors together with iron species in the interior of a droplet. This deliberate negation of surfactant templating allows a silica shell to form extremely rapidly, sealing in the organic species in the particle interior. Subsequent pyrolysis results in a buildup of internal pressure, forcing carbonaceous species against the silica wall to form an inner shell of carbon. The incorporation of magnetic iron oxide into the shells opens up applications in external stimuli-responsive nanomaterials.

Disclosed is a microcapsule composed of a transparent capsule wall material and configured to contain therein color particles selected from among color magnetic pigment particles and color pigment particles, magnetically color-tunable particles, and a solvent, thus exhibiting a superior structural color expression effect compared to a conventional microcapsule, and realizing a full range of colors, thereby enabling use thereof as a print medium.

Systems and methods are described herein that create discrete volumes associated with solid-phase particles (e.g., drop-carrier particles) suspended in an immiscible phase (e.g., dropicles). One embodiment of the system includes a plurality of hydrogel-based drop-carrier particles containing a microscale voids or cavities that hold an aqueous phase droplet of fluid within each drop-carrier particle. The plurality of hydrogel drop-carrier particles associated with aqueous drops are suspended as individual elements in an immiscible oil phase. The microscale hydrogel drop-carrier particles containing the voids or cavities may be manufactured using microfluidic droplet generators. The dropicles may be used to analyze single-entities (e.g., single-molecules and single-cells) and analytes.

A pigment composite particle is provided, which includes an organic pigment core, a polyelectrolyte shell wrapped around the organic pigment core, and an oxide shell wrapped around the polyelectrolyte shell. The organic pigment core is water-insoluble. The organic pigment core and the polyelectrolyte shell have a weight ratio of 1:0.25 to 1:1. The oxide shell is formed from tetraalkyl orthosilicate, tetraalkyl orthotitanate, or a combination thereof, and the organic pigment core and the tetraalkyl orthosilicate, tetraalkyl orthotitanate, or the combination thereof have a weight ratio of 1:0.7 to 1:3.

The present disclosure relates to a fluorogenic pH-sensitive dye and a film for detecting pH using the fluorogenic pH-sensitive dye on a polymer film. The fluorogenic pH-sensitive dye includes an aryl compound having a sulfonyl group (—SO.sub.2) and an agarose compound covalently bonded to the sulfonyl group (—SO.sub.2) of the aryl compound.

The present invention relates to dry particulate encapsulation compositions comprising a water-insoluble matrix comprising at least 70% by weight of proteins, based on the total weight of the matrix and a moisture content of about 5 to 10% by weight, based on the total weight of the matrix and an encapsulate encapsulated in the matrix, wherein the matrix once wetted in a clear colorless aqueous solution or in mineral oil has a lightness value (L*) greater than about 40, a color vividness or Chroma (C*) lower than about 33 and a hue angle between about 70 and 90. The encapsulation compositions of the present invention are useful in encapsulating dyes, medications and vitamins. Fine particulate encapsulation compositions comprising natural dyes can be used in lieu of artificial lakes in confectionery, cosmetics and caplets color coatings.