Abstract: A method of forming multi-phasic nano-objects involves the jetting of two or more different liquids in side-by-side capillaries thereby generating a composite liquid stream. The composite then exposed to a force field which causes the composite liquid stream to at least partially solidify into a nano-object. The method forms a nano-object having a number of morphologies such as rods, spheres, and fibers.

Abstract: A method of manufacturing an implantable electronic device, including: providing a silicon wafer; building a plurality of layers coupled to the wafer including an oxide layer coupled to the silicon wafer; a first reactive parylene layer coupled to the oxide layer, an electrode layer coupled to the first reactive parylene layer, and a second reactive parylene layer, coupled to the electrode layer, that chemically bonds to the first reactive polymer layer, and a second polymer layer coupled to the second reactive parylene layer; coating the plurality of layers with an encapsulation, and modifying the encapsulation and at least one of the plurality of layers to expose an electrode site in the electrode layer.

Abstract: The present invention provides methods and compositions for establishing and maintaining growth of undifferentiated stem cells. In particular, the present invention provides synthetic growth matrices for stem cells, wherein said cells are capable of going through multiple passages while remaining in an undifferentiated state.

Abstract: Methods of forming a plurality multiphasic nano-components (MPNs) having at least two phases, with high selectivity for at least one of shape, size, or phase orientation in the nano-component are provided. The methods provide high yields of substantially similar nano-components by controlling one or more of: polymer concentration, liquid stream composition, liquid stream conductivity, flow rate, humidity, temperature, pressure, electrode design and/or configuration during an electrified jetting process. Such methods of making MPNs form shapes including disks, rods, spheres, rectangles, polygons, toroids, cones, pyramids, cylinders, fibers, and combinations thereof. Such MPNs can be used in various applications, including for medical diagnostics or with pharmaceutical, personal care, oral care, and/or nutritional compositions.

Abstract: The disclosure provides methods for preparation of multiphasic micro-components, such as core-shell or anisotropic (e.g., Janus) multiphasic particles with well-defined structures using electrohydrodynamic co-jetting of two polymer solutions containing polyelectrolytes. Suitable polyelectrolytes include polyacrylic acid (PAA), poly(acrylamide acrylic acid (PAAm), and/or poly(acryl amide-co-acrylic acid) (PAAm-AA), sodium polystyrene sulfonate (PSS), polyethylene imine (PEI), polypeptides, copolymers, and combinations of these. Control of certain variables, such as relative conductivities of the two jetting solutions, controls the particle morphologies formed, leading to a predetermined phase orientation for the same polymer system. In certain aspects, after cross-linking, core-shell particles are stable in aqueous solutions and exhibit reproducible swelling behavior, while maintaining the original core-shell geometry.

Abstract: A substrate having a surface with reversibly switchable properties. The surface comprises a nanolayer of a material that switches from a first conformation state to a second conformation state when an external stimulus is applied. When the nanolayer is in the first conformation state, the surface is characterized by a first property, and when the nanolayer is in the second conformation state, the surface is characterized by a second property.

Abstract: The disclosure provides for devices and coatings that are substantially free of organic solvent sand suitable for insertion into a patient, and that comprise a metal layer and a coating with a thickness of about 20 nm to about 2000 nm wherein the coating comprises a biocompatible polymer comprising at least one residue covalently bonded to a nitric oxide generating compound.

Abstract: Multifunctional reactive polymers created by chemical vapor deposition (CVD) and methods of making such polymeric systems are provided. Such polymers provide multifunctional surfaces which can present two or more different molecules (e.g. biological ligands) in controlled ratios. Polymers may include compositional gradients allowing attached ligands to be presented as continuous gradients across a surface. The polymer compositions are modularly designable and applicable to a wider range of applications, including biomedical devices and diagnostic systems.

Abstract: Multiphasic colorant nano-components (MPCs) having at least two phases and at least one colorant are provided. In certain aspects, the at least two phases are optically or visually distinct from one another. The MPCs can be used in various methods in various applications, such as visual, optical, and/or electronic displays, including in paints, inks, coatings, plastics, textiles, electronic display devices, pixels, or electronic paper. The MPCs are formed by methods of electrified jetting of polymers.

Abstract: Methods for bonding include deposition an adhesion layer on at least one substrate using chemical vapor deposition. The two adhesion layers each have a reactive group that is complementary to the other, thus enabling strong adhesion between the bonded substrates. Devices include two substrates that can be adhered together by chemically depositing an adhesion layer on at least one substrate using chemical vapor deposition. The substrates each have a reactive group that is complementary to the other, thus enabling strong adhesion between the bonded substrates.

Abstract: Reactive polymer coatings that undergo regioselective reactions with target biomolecules are provided. The polymers of the coatings are deposited via chemical vapor deposition and comprise one or more functional groups that exhibit regioselective bonding with a functional group or a target molecule. Such polymers include poly-xylylenes having functional groups such as alkynes or azides. The regioselective bonding of the reactive polymers provide stable immobilization of target molecules and/or ligands and can create biofunctional surfaces having a wide range of applications.

Abstract: Multiphasic nano-components (MPNs) having at least two phases and at least one active ingredient are provided. The MPNs can be used in various methods for medical diagnostics or with pharmaceutical, personal care, oral care, and/or nutritional compositions, for example, in oral care, hair, or skin products. The MPNs can be designed to have targeted delivery within an organism, while providing controlled release systems or combining incompatible active ingredients. Further, the MPNs can be used as biomedical coatings (such as anti-microbial coatings), or anti-corrosive coatings, bioimaging probes with combined diagnostic and therapeutic use, and fragrance release systems, among others. The MPNs can be formed by electrified jetting of polymers.

Abstract: A substrate having a surface with reversibly switchable properties. The surface comprises a nanolayer of a material that switches from a first conformation stateto a second conformation state when an external stimulus is applied. When the nanolayer is in the first conformation state, the surface is characterized by a first property, and when the nanolayer is in the second conformation state, the surface is characterized by a second property.

Abstract: A method of forming multi-phasic nano-objects involves the jetting of two or more different liquids in side-by-side capillaries thereby generating a composite liquid stream. The composite then exposed to a force field which causes the composite liquid stream to at least partially solidify into a nano-object. The method forms a nano-object having a number of morphologies such as rods, spheres, and fibers.

Abstract: A substrate having a surface with reversibly switchable properties. The surface comprises a nanolayer of a material that switches from a first conformation state to a second conformation state when an external stimulus is applied. When the nanolayer is in the first conformation state, the surface is characterized by a first property, and when the nanolayer is in the second conformation state, the surface is characterized by a second property.

Abstract: A method for coating of variable substrates with highly reactive polymers. Its combination with microcontact printing is used for generating several devices such as patterned arrays of ligands for high throughput screening.

Abstract: A polymer having the following structure: where m is 0 to 10000 and n is 0 to 10000. The polymer may be used in a coating such as on a biomedical device. The polymer is an adhesion promotor for a drug delivery system wherein the polymer is coated onto a substrate such that it may be a reactive coating for UV crosslinking. The polymeric coating may also provide an interface for an implant and can be modified with a secondary polymer or polymer combination. The secondary polymer is capable of eluding drugs or encapsulating cells.

Abstract: Fabrication of surfaces with reduced protein adsorption and/or cell adhesion comprising a vapor deposition coating process such that the coating includes polymer interfaces containing chemical groups reducing the protein adsorption and/or cell adhesion. The invention allows precise anchoring and presentation of biomolecules in their biological context. The resulting systems comprise superior surfaces for design of protein- or cellbased bioassays, because of high-signal-to-noise ratios. Background adsorption is suppressed while specific interaction with capturing molecules is not affected.

Abstract: A substrate having a surface with reversibly switchable properties. The surface comprises a nanolayer of a material that switches from a first conformation state to a second conformation state when an external stimulus is applied. When the nanolayer is in the first conformation state, the surface is characterized by a first property, and when the nanolayer is in the second conformation state, the surface is characterized by a second property.