The present invention relates to mixtures, or compositions comprising said mixtures, comprising at least one bacterial strain, preferably at least one probiotic bacterial strain or a derivative thereof, as well as to the use of said mixtures or compositions in methods for the preventive and/or curative treatment of an inflammatory ocular and/or periocular lesion, preferably in methods for the treatment of ocular diseases such as dry eyes, eyelid allergy, conjunctivitis, blepharitis, meibonite, dacryoliths, stye, inflammatory lesions of ocular adnexa and associated symptoms.

The present invention relates to mixtures, or compositions comprising said mixtures, comprising at least one bacterial strain, preferably at least one probiotic bacterial strain or a derivative thereof, as well as to the use of said mixtures or compositions in methods for the preventive and/or curative treatment of an inflammatory ocular and/or periocular lesion, preferably in methods for the treatment of ocular diseases such as dry eyes, eyelid allergy, conjunctivitis, blepharitis, meibonite, dacryoliths, stye, inflammatory lesions of ocular adnexa and associated symptoms.

It is an object to provide a therapeutic material for a skin ulcer which has excellent therapeutic effects on intractable skin ulcers such as decubitus ulcers with pockets and huge decubitus ulcers. By applying the therapeutic material for decubitus ulcers consisting of a fibrous material holding an antibiotic and a cell proliferation accelerator therein which is formed into an approximately spherical shape to a site of decubitus in a state in which a defect extending to the dermis, subcutaneous tissue, muscle or bone occurs, it is possible to treat critical skin ulcers such as intractable decubitus ulcers with pockets and huge intractable decubitus ulcers, as well as to treat not only relatively mild decubitus classified as stage II according to the US National Pressure Ulcer Advisory Panel (NPUAP) staging system, i.e., decubitus having ulcers in a state in which a part of the dermis is deficient, but also severe decubitus that has progressed to stage III to IV according to the NPUAP staging system, particularly decubitus with intractable ulcers with pockets or decubitus with huge intractable ulcers.

It is an object to provide a therapeutic material for a skin ulcer which has excellent therapeutic effects on intractable skin ulcers such as decubitus ulcers with pockets and huge decubitus ulcers. By applying the therapeutic material for decubitus ulcers consisting of a fibrous material holding an antibiotic and a cell proliferation accelerator therein which is formed into an approximately spherical shape to a site of decubitus in a state in which a defect extending to the dermis, subcutaneous tissue, muscle or bone occurs, it is possible to treat critical skin ulcers such as intractable decubitus ulcers with pockets and huge intractable decubitus ulcers, as well as to treat not only relatively mild decubitus classified as stage II according to the US National Pressure Ulcer Advisory Panel (NPUAP) staging system, i.e., decubitus having ulcers in a state in which a part of the dermis is deficient, but also severe decubitus that has progressed to stage III to IV according to the NPUAP staging system, particularly decubitus with intractable ulcers with pockets or decubitus with huge intractable ulcers.

A method of producing a pharmaceutical gel emulsion, wherein the emulsion is an oil-in-water gel emulsion, comprising the steps of forming an oil-in-water emulsion comprising at least one pharmaceutically acceptable oil, at least one aqueous phase, at least one osmotic agent, at least one emulsifying agent, mixing a gelling polysaccharide with the oil-in-water emulsion and allowing the resulting mixture to form the pharmaceutical gel emulsion, optionally mixing an bioactive agent into the pharmaceutical gel emulsion.

A method of producing a pharmaceutical gel emulsion, wherein the emulsion is an oil-in-water gel emulsion, comprising the steps of forming an oil-in-water emulsion comprising at least one pharmaceutically acceptable oil, at least one aqueous phase, at least one osmotic agent, at least one emulsifying agent, mixing a gelling polysaccharide with the oil-in-water emulsion and allowing the resulting mixture to form the pharmaceutical gel emulsion, optionally mixing an bioactive agent into the pharmaceutical gel emulsion.

The present disclosure provides compositions comprising protein encapsulated nanoparticles, and methods of making said compositions. In an aspect, a composition may comprise a drug delivery vector and a therapeutic substance, wherein the composition elutes at least 1.0 pg of the therapeutic substance per 100,000 particles of the drug delivery vector over a period of time under conditions of a drug delivery vector release buffer, wherein the therapeutic substance, drug delivery vector and drug delivery vector release buffer comprise a solution, wherein the solution is centrifuged and a portion stored at about 1 to 10° C., and wherein the elution of the therapeutic substance is determined by ELISA assay. This disclosure further describes a method of controlling an immunophenotype in a patient suffering from a disease which impacts the immune system.

The present disclosure provides compositions comprising protein encapsulated nanoparticles, and methods of making said compositions. In an aspect, a composition may comprise a drug delivery vector and a therapeutic substance, wherein the composition elutes at least 1.0 pg of the therapeutic substance per 100,000 particles of the drug delivery vector over a period of time under conditions of a drug delivery vector release buffer, wherein the therapeutic substance, drug delivery vector and drug delivery vector release buffer comprise a solution, wherein the solution is centrifuged and a portion stored at about 1 to 10° C., and wherein the elution of the therapeutic substance is determined by ELISA assay. This disclosure further describes a method of controlling an immunophenotype in a patient suffering from a disease which impacts the immune system.

The present disclosure provides compositions comprising protein encapsulated nanoparticles, and methods of making said compositions. In an aspect, a composition may comprise a drug delivery vector and a therapeutic substance, wherein the composition elutes at least 1.0 pg of the therapeutic substance per 100,000 particles of the drug delivery vector over a period of time under conditions of a drug delivery vector release buffer, wherein the therapeutic substance, drug delivery vector and drug delivery vector release buffer comprise a solution, wherein the solution is centrifuged and a portion stored at about 1 to 10° C., and wherein the elution of the therapeutic substance is determined by ELISA assay. This disclosure further describes a method of controlling an immunophenotype in a patient suffering from a disease which impacts the immune system.

The present invention relates to compositions and formulations of polybasic drugs to reduce multiorgan toxicity by making supramolecular cationic complex without covalent bond formation, without conjugation and without chemical modification of macromolecular entity used. The compositions and formulations made thereof act by multiple mechanisms simultaneously to reduce toxicity of cationic antibiotic drugs.