The present disclosure provides functional fibrous material comprising fibers associated with hydrogel containing micro-flakes. The present disclosure also provides a method of forming hydrogel micro-flakes having embedded therein at least one microorganism and a method of preparing functional fibrous material, both methods comprise a step of subjecting a mixture of hydrogel and microbial material to high shear forces to form micro-flakes comprising the hydrogel with at least one microorganism embedded therein. Further provided is a method of treatment of a target comprising contacting the target with the disclosed functional fibrous material as well as the micro-flakes disclosed herein.

The present disclosure provides functional fibrous material comprising fibers associated with hydrogel containing micro-flakes. The present disclosure also provides a method of forming hydrogel micro-flakes having embedded therein at least one microorganism and a method of preparing functional fibrous material, both methods comprise a step of subjecting a mixture of hydrogel and microbial material to high shear forces to form micro-flakes comprising the hydrogel with at least one microorganism embedded therein. Further provided is a method of treatment of a target comprising contacting the target with the disclosed functional fibrous material as well as the micro-flakes disclosed herein.

The present invention provides for methods and devices suitable for producing a transplantable cellular suspension of living tissue suitable for promoting tissue regeneration in an epithelium-related procedure, as well as compositions produced therefrom. The cellular suspension can include viable and functioning cells at various stages of differentiation, including undifferentiated/progenitor cells and differentiated cells, as well as those in between. In certain embodiments, the cellular suspension can be subjected to a stress to induce a heat shock response therein, or be exposed to an exogenously supplied agent such as heat shock protein or a fragment thereof, hyaluronic acid, platelet-enriched plasma, and/or growth factors. The cellular suspension can be applied directly to a patient's recipient site for in vivo regeneration, or be cultured or seeded to a matrix for in vitro growth/regeneration.

The present invention provides for methods and devices suitable for producing a transplantable cellular suspension of living tissue suitable for promoting tissue regeneration in an epithelium-related procedure, as well as compositions produced therefrom. The cellular suspension can include viable and functioning cells at various stages of differentiation, including undifferentiated/progenitor cells and differentiated cells, as well as those in between. In certain embodiments, the cellular suspension can be subjected to a stress to induce a heat shock response therein, or be exposed to an exogenously supplied agent such as heat shock protein or a fragment thereof, hyaluronic acid, platelet-enriched plasma, and/or growth factors. The cellular suspension can be applied directly to a patient's recipient site for in vivo regeneration, or be cultured or seeded to a matrix for in vitro growth/regeneration.

The invention relates to biomaterials, which comprise a bacterial cellulose matrix and probiotics entrapped in said bacterial cellulose. The invention also relates to methods for obtaining the biomaterial, as well as uses of the biomaterial in medicine. It also relates to coated food products wherein the coat is composed of said biomaterial wherein the coat acts to prevent the proliferation of undesired bacteria. It also relates to packaged medical devices, wherein the package comprises said biomaterial also preventing growth of pathogenic bacteria.

A multi-lactobacillus composition is a dominant strain separated and selected from the vagina of a healthy woman in China. The multi-lactobacillus composition comprises at least three of the following active components: Lactobacillus johnsonii, Lactobacillus gasseri, Lactobacillus rhamnosus, Lactobacillus crispatus, and Lactobacillus jensenii.

The present invention relates to a topical composition of facilitating wound healing and reducing scars, which includes an inactivated culture of Lactobacillus species as an effective ingredient and can significantly facilitate wound healing as well as reducing scars, thereby can be applied to a method of facilitating wound healing and reducing scars.

The present invention relates to a topical composition of facilitating wound healing and reducing scars, which includes an inactivated culture of Lactobacillus species as an effective ingredient and can significantly facilitate wound healing as well as reducing scars, thereby can be applied to a method of facilitating wound healing and reducing scars.

The subject invention provides topical therapeutic compositions and methods of their use for enhanced healing of wounds, including burns, and scars of the skin. Specifically, in one embodiment, the subject invention provides materials and methods for reducing the healing time of skin wounds and for reducing the appearance of scars. The subject invention utilizes topical compositions comprising microbial growth by-products and, optionally, a topically-acceptable carrier. In specific embodiments, the microbial growth by-products are biosurfactants.

The subject invention provides topical therapeutic compositions and methods of their use for enhanced healing of wounds, including burns, and scars of the skin. Specifically, in one embodiment, the subject invention provides materials and methods for reducing the healing time of skin wounds and for reducing the appearance of scars. The subject invention utilizes topical compositions comprising microbial growth by-products and, optionally, a topically-acceptable carrier. In specific embodiments, the microbial growth by-products are biosurfactants.