1003 results about "Polymer architecture" patented technology

The personal care compositions of the present invention are in the form of an Article comprising a dissolvable fibrous web structure. The fibers of the dissolvable fibrous web structure comprise a surfactant; a water soluble polymeric structurant; and a plasticizer. Additionally the ratio of the water soluble water soluble polymeric structurant to the active agent in the fiber is 3.5 or less.

A polymer is directed from a source electrode into an electric field that drives the formation of electrospun fibers that are deposited onto a collecting surface to thereby form a patterned polymer structure. The collecting surface can be a counterelectrode or a collecting surface that is between the source electrode and a counterelectrode. Apparatus employed to conduct the method include an electrospinning source that directs polymer into an electric field formed by source and counterelectrodes. A collecting surface, such as the counterelectrode or a surface interposed between the source and counterelectrodes, collects electrospun fibers. Articles of manufacture formed by the method of apparatus include, for example, a structure of patterned electrospun fibers comprising multiple aggregations of polymeric electrospun fibers.

Connective tissue, including neo-tendons and ligaments, has been constructed using biodegradable synthetic scaffolds seeded with tenocytes. The scaffolds are preferably formed from biodegradable fibers formed of a polymer such as polyglycolic acid-polylactic acid copolymers, and seeded with cells isolated from autologous tendon or ligament by means of enzymatic digestion or direct seeding into tissue culture dishes from explants. The cell polymer constructs are then surgically transplanted to replace missing segments of functioning tendon or ligament.

The present invention generally provides improved methods of fabricating polymeric microfluidic devices that incorporate microscale fluidic structures, whereby the fabrication process does not substantially distort or deform such structures. The methods of the invention generally provide enhanced bonding processes for mating and bonding substrate layers to define the microscale channel networks therebetween.

Composite webs having one or more polymeric structures located on a substrate, closure systems comprising composite webs, and methods of attaching articles are disclosed. The polymeric structures are formed using thermoplastic compositions and are attached to a surface of a substrate. The polymeric structures include an area that is attached to the substrate and a detached area that is not attached to a surface of a substrate.

A non-lathering personal care article in the form of a porous dissolvable solid structure, comprising: from about 0% to about 10% ionic surfactant; from about 1% to about 60% of a non-surfactant cosmetic active; from about 15% to about 70% polymeric structurant, wherein the polymeric structurant has a weighted average molecular weight of from about 40,000 to about 500,000; and from about 1% to about 30% plasticizer. The article has a density of from about 0.03 g / cm3 to about 0.15 g / cm3.

Cationic polymerization of mono and polyfunctional benzoxazine monomers is described. The chemical structure of the polymers from cationic polymerization of benzoxazine monomers has been identified and distinguished from thermally polymerized products from the same monomers. The controllable microstructure of the polymers from benzoxazines prepared by cationic polymerization offers opportunities to prepare and optimize the polymer structure for specific applications.

System-in packages, or multichip modules, are described which can include multi-layer chips in a multi-layer polymer structure, on-chip metal bumps on the multi-layer chips, intra-chip metal bumps in the multi-layer polymer structure, and patterned metal layers in the multi-layer polymer structure. The multi-layer chips in the multi-layer polymer structure can be connected to each other or to an external circuit through the on-chip metal bumps, the intra-chip metal bumps and the patterned metal layers. The system-in packages can be connected to external circuits through solder bumps, meal bumps or wirebonded wires.

Novel electrically conductive polymer composite structures having a horizontal plane that contain effective amounts of two different types of conductive graphitic nanofibers. The first type of graphitic nanofiber is aligned substantially parallel to the horizontal plane of the polymer structure and are comprised of graphite platelets that are aligned substantially parallel to the longitudinal axis of the nanofiber. The second type of conductive graphite nanofiber are aligned at an angle to the horizontal plane of the polymer structure and are comprised of graphite platelets aligned at an angle to the longitudinal axis of the nanofiber. The conductive polymer composite structures are further comprised of one or more polymer layers.

Chemically or biochemically active agents or other species are patterned on a substrate surface by providing a micromold having a contoured surface and forming, on a substrate surface, a chemically or biochemically active agent or fluid precursor of a structure. A chemically or biochemically active agent or fluid precursor also can be transferred from indentations in an applicator to a substrate surface. The substrate surface can be planar or non-planar. Fluid precursors of polymeric structures, inorganic ceramics and salts, and the like can be used to form patterned polymeric articles, inorganic salts and ceramics, reactive ion etch masks, etc. at the surface. The articles can be formed in a pattern including a portion having a lateral dimension of less than about 1 millimeter or smaller. The indentation pattern of the applicator can be used to transfer separate, distinct chemically or biochemically active agents or fluid precursors to separate, isolated regions of a substrate surface. Waveguide arrays, combinatorial chemical or biochemical libraris, etc. can be made. Differences in refractive index of waveguide and cladding can be created by subjecting the waveguide and cladding, made of indentical prepolymeric material, to different polymerization or cross-linking conditions. Interferometers are defined by coupling arrays of waveguides, where coupling can be controlled by altering the difference in refractive index between cladding and waveguide at any desired location of the array. Alteration and refractive index can be created photochemically, chemically, or the like. Sensors also are disclosed, including biochemical sensors.

Polymeric structures, methods for making same, fibrous structures comprising same and fibrous product incorporating same are provided.

Disclosed herein are vaso-occlusive devices for forming occluding the vasculature of a patient. More particularly, disclosed herein are vaso-occlusive devices comprising at least one polymer structure and methods of making and using these devices.

Disclosed herein are vaso-occlusive devices for forming occluding the vasculature of a patient. More particularly, disclosed herein are vaso-occlusive devices comprising at least one polymer structure and methods of making and using these devices.

The invention is to methods of deploying polymeric biodegradable or non biodegradable stents by use of stepwise creases in the pressure placed upon the inner diameter of the stent to slowly increase the stent diameter. In one embodiment, the pressure on the interior stent diameter is slowly increased. The stent is allowed to acclimate to this diameter for a set period of time, and then the pressure is again increased. This series of steps continues until the stent reaches its final diameter and a final period of acclimatization is maintained prior to the removal of the deployment / delivery device.