Abstract: The present invention is directed to a separator for an electrochemical cell comprising a web, the web comprising fibers of a polyimide and a protective region wherein the protective region impedes electrochemical reduction of the polyimide inside the electrochemical cell. The present invention is further directed to a multi-layer article and electrochemical cell containing the separator.

Abstract: Optical display devices and methods of operating such devices are provided. The optical device includes a display component having a plurality of anisotropic multiphasic particles with at least two optically distinct phases. The plurality of anisotropic multiphasic particles is disposed in one or more regions of the display component that define an optic feature. Further, at least one of the phases of the anisotropic multiphasic particle comprises a material receptive to a force field, such as a magnetic material is receptive to an applied magnetic field. In this manner, the display component can reversibly exhibit a first optical state in the presence of the force field and thus is optionally switchable.

Abstract: The present invention is directed to a separator for an electrochemical cell comprising a web, the web comprising fibers of a polyimide and a protective region wherein the protective region impedes electrochemical reduction of the polyimide inside the electrochemical cell. The present invention is further directed to a multi-layer article and electrochemical cell containing the separator.

Abstract: Provided herein are methods of making and controlling multiphasic polymeric micro-components capable of shape-shifting. Such a multiphasic micro-component comprises a first phase (that can include a first polymer) and at least one additional phase distinct from said first phase (that can include a second polymer). One or more of the first phase and additional phase comprises a component that is responsive to an external stimulus. Thus, the micro-component exhibits a substantial physical deformation in response to: (i) the presence of the external stimulus or (ii) a change in the external stimulus. Exemplary external stimuli include temperature, pressure, light, pH, ionic strength, hydrophobicity/hydrophilicity, solvent, concentration, a stimulator chemical, sonic energy, electric energy, pressure, magnetic fields, and combinations thereof.

Abstract: Optical display devices and methods of operating such devices are provided. The optical device includes a display component having a plurality of anisotropic multiphasic particles with at least two optically distinct phases. The plurality of anisotropic multiphasic particles is disposed in one or more regions of the display component that define an optic feature. Further, at least one of the phases of the anisotropic multiphasic particle comprises a material receptive to a force field, such as a magnetic material is receptive to an applied magnetic field. In this manner, the display component can reversibly exhibit a first optical state in the presence of the force field and thus is optionally switchable.

Abstract: The present technology provides synthesized particles that mimic key structural and functional features of red blood cells. Such RBC-mimicking particles possess the ability to carry oxygen (and carbon dioxide) and flow through capillaries smaller than their own diameter. Further, such particles can also deliver drugs and imaging agents. These particles provide a new paradigm for the design of drug delivery and imaging carriers since they combine the functionality of natural RBCs with the broad applicability and versatility of synthetic drug delivery particles. Further, such particles can be used for detoxification and other biomedical applications.

Abstract: A multiphasic microfiber for a three-dimensional tissue scaffold and/or cellular support is provided in one aspect that includes at least one biocompatible material. The multiphasic microfiber optionally has a first phase and at least one distinct additional phase and is formed by electrohydrodynamic jetting. Further, such microfibers optionally have one or more biofunctional agents, which may be surface-bound moieties provided in spatial patterns. Multiphasic microfibers formed in accordance with the disclosure may form, in some cases, three-dimensional fiber scaffolds with precisely engineered, micrometer-scaled patterns for cellular contact guidance, which may thus support and/or promote cellular growth, proliferation, differentiation, repair, and/or regeneration for tissue and bioengineering applications.

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: 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.