Topical applicators containing mycological biopolymers are suitable for applying health or cosmetic products to the skin or lips of a subject. The applicators are made from biodegradable mycological biopolymers that are grown from fungi in the presence of a growth medium under a predetermined environment of relative humidity, temperature, carbon dioxide, oxygen and air flow. The topical applicators containing the mycological biopolymers may further contain beneficial agents or products that that may be transferred to the skin or lips, thereby enhancing the health or beauty of a subject.

The process of making a biocomposite material utilize a bacterial species and a fungal species in an agricultural feedstock composed of a substrate of non-nutrient discrete particles and a nutrient material wherein the bacterial species imparts mechanical properties to the biocomposite material and the fungal species binds the biocomposite material. Both bacterium and fungus can be genetically engineered to produce desired properties within the microbial communities.

Described herein are biological devices and methods for using the same to produce a polyactive carbohydrate. The biological devices include microbial cells transformed with a DNA construct containing genes for producing a chitin synthase, a chitosanase, and a chitin deacetylase. In some instances, the biological devices also include a gene for lipase. Methods for using the polyactive carbohydrate are also provided herein, including, but not limited to, enhancing the physiological properties of plants; medical applications; applications in the construction, materials science, and home goods industries; personal care, grooming, cosmetics, and oral care compositions containing the polyactive carbohydrate; methods for water decontamination; and the production of polyurethane s.

Described herein are biological devices and methods for using the same to produce a polyactive carbohydrate. The biological devices include microbial cells transformed with a DNA construct containing genes for producing a chitin synthase, a chitosanase, and a chitin deacetylase. In some instances, the biological devices also include a gene for lipase. Methods for using the polyactive carbohydrate are also provided herein, including, but not limited to, enhancing the physiological properties of plants; medical applications; applications in the construction, materials science, and home goods industries; personal care, grooming, cosmetics, and oral care compositions containing the polyactive carbohydrate; methods for water decontamination; and the production of polyurethanes.

An OLED display including a display panel and a color-correction component is described. A plurality of comparative display panels otherwise equivalent to the display panel but having one or more different optical thicknesses of OLED layers have a maximum white-point color shift from 0 to 45 degrees of WPCS.sup.C.sub.45 and a white-point axial efficiency of WPAE.sup.C. The plurality of comparative display panels defines a performance curve along a boundary of performance points. The OLED display and the display panel have respective maximum white-point color shifts from 0 to 45 degrees of WPCS.sub.45 and WPCS.sup.0.sub.45 and respective white-point axial efficiencies of WPAE and WPAE.sup.0. WPCS.sup.0.sub.45 and WPAE.sup.0 defines a performance point of the display panel to the right of the performance curve and WPCS.sub.45 and WPAE defines a performance point of the OLED display above or to the left of the performance curve. Methods of making the OLED display are described.

Described herein are biological devices and methods for using the same to produce a polyactive carbohydrate. The biological devices include microbial cells transformed with a DNA construct containing genes for producing a chitin synthase, a chitosanase, and a chitin deacetylase. In some instances, the biological devices also include a gene for lipase. Methods for using the polyactive carbohydrate are also provided herein, including, but not limited to, enhancing the physiological properties of plants; medical applications; applications in the construction, materials science, and home goods industries; personal care, grooming, cosmetics, and oral care compositions containing the polyactive carbohydrate; methods for water decontamination; and the production of polyurethanes.

Described herein are biological devices and methods for using the same to produce a polyactive carbohydrate. The biological devices include microbial cells transformed with a DNA construct containing genes for producing a chitin synthase, a chitosanase, 5 and a chitin deacetylase, and, optionally, lipase, regulatory sequence CHR1, transglycosylase, dehydrogenase, and/or (1.fwdarw.3), (1.fwdarw.4)-?-glucan synthase. Methods for using the polyactive carbohydrate are also provided herein including, but not limited to, increasing plant hormone production and improving the appearance and root strength of plants and production of polyurethane biofoams.

The process of making a biocomposite material utilize a bacterial species and a fungal species in an agricultural feedstock composed of a substrate of non-nutrient discrete particles and a nutrient material wherein the bacterial species imparts mechanical properties to the biocomposite material and the fungal species binds the biocomposite material. Both bacterium and fungus can be genetically engineered to produce desired properties within the microbial communities.

The process of making a biocomposite material utilize a bacterial species and a fungal species in an agricultural feedstock composed of a substrate of non-nutrient discrete particles and a nutrient material wherein the bacterial species imparts mechanical properties to the biocomposite material and the fungal species binds the biocomposite material. Both bacterium and fungus can be genetically engineered to produce desired properties within the microbial communities.

An OLED display including a display panel and a color-correction component is described. A plurality of comparative display panels otherwise equivalent to the display panel but having one or more different optical thicknesses of OLED layers have a maximum white-point color shift from 0 to 45 degrees of WPCS.sup.C.sub.45 and a white-point axial efficiency of WPAE.sup.C. The plurality of comparative display panels defines a performance curve along a boundary of performance points. The OLED display and the display panel have respective maximum white-point color shifts from 0 to 45 degrees of WPCS.sub.45 and WPCS.sup.0.sub.45 and respective white-point axial efficiencies of WPAE and WPAE.sup.0. WPCS.sup.0.sub.45 and WPAE.sup.0 defines a performance point of the display panel to the right of the performance curve and WPCS.sub.45 and WPAE defines a performance point of the OLED display above or to the left of the performance curve. Methods of making the OLED display are described.