Disclosed are compositions and methods useful for oral delivery of targeted therapies for pulmonary diseases, fibrotic disorders and cancer. The compositions and methods are based on peptide sequences that selectively bind to and home to diseased tissue and enable targeted therapies to affect a beneficial therapeutic result. The disclosed targeting is useful for oral delivery of therapeutic and detectable agents to diseased tissue in an animal.

Disclosed are compositions and methods useful for oral delivery of targeted therapies for pulmonary diseases, fibrotic disorders and cancer. The compositions and methods are based on peptide sequences that selectively bind to and home to diseased tissue and enable targeted therapies to affect a beneficial therapeutic result. The disclosed targeting is useful for oral delivery of therapeutic and detectable agents to diseased tissue in an animal.

Rheology modifiers comprising cross-linked poly(amino acid) and methods of their use in aqueous compositions. The modifiers comprise cross-linked poly(amino acid) microparticles having a mean equivalent diameter when fully swollen in deionized water of up to 1000 μm, as measured by laser diffraction. In particular, the poly(amino acid) is D-, L- or D,L-Y-poly(glutamic acid). A method of preparing the modifier comprises cross-linking a poly(amino acid), drying the cross-linked poly(amino acid) and grinding the cross-linked poly(amino acid) to have the required diameter.

Rheology modifiers comprising cross-linked poly(amino acid) and methods of their use in aqueous compositions. The modifiers comprise cross-linked poly(amino acid) microparticles having a mean equivalent diameter when fully swollen in deionized water of up to 1000 μm, as measured by laser diffraction. In particular, the poly(amino acid) is D-, L- or D,L-Y-poly(glutamic acid). A method of preparing the modifier comprises cross-linking a poly(amino acid), drying the cross-linked poly(amino acid) and grinding the cross-linked poly(amino acid) to have the required diameter.

In some embodiments, a composition is disclosed that includes pure silk fibroin-based protein fragments that are substantially devoid of sericin, wherein the composition has an average weight average molecular weight ranging from about 17 kDa to about 38 kDa, wherein the composition has a polydispersity of between about 1.5 and about 3.0, wherein the composition is substantially homogeneous, wherein the composition between 0 ppm to about 500 ppm of inorganic residuals, and wherein the composition includes between 0 ppm to about 500 ppm of organic residuals. In some embodiments, a composition is disclosed that includes silk fibroin-based protein fragments and is suitable for use in consumer applications. In some embodiments, a preserved composition is disclosed that includes silk fibroin-based protein fragments. In some embodiments, a method of preserving a solution using silk fibroin-based protein fragments is disclosed.

In some embodiments, a composition is disclosed that includes pure silk fibroin-based protein fragments that are substantially devoid of sericin, wherein the composition has an average weight average molecular weight ranging from about 17 kDa to about 38 kDa, wherein the composition has a polydispersity of between about 1.5 and about 3.0, wherein the composition is substantially homogeneous, wherein the composition between 0 ppm to about 500 ppm of inorganic residuals, and wherein the composition includes between 0 ppm to about 500 ppm of organic residuals. In some embodiments, a composition is disclosed that includes silk fibroin-based protein fragments and is suitable for use in consumer applications. In some embodiments, a preserved composition is disclosed that includes silk fibroin-based protein fragments. In some embodiments, a method of preserving a solution using silk fibroin-based protein fragments is disclosed.

The invention relates to a method for the stabilization of a polysaccharide (hyaluronic acid) with a biomolecule—amino acid—through crosslinking, to generate a bionic hydrogel based on physiological building blocks for applications in regenerative medicine. The designed biosimilar hydrogel is intended to be used in regenerative medicine for the purpose of regenerate, rejuvenate and/or restore the structure or function of impaired or damaged tissues, and to promote healing. The manufacture method is composed of a single step that includes mixing L-lysine and hyaluronic acid sodium salt in an aqueous saline solution with either EDC/NHS as coupling agent.

Compositions are provided for the liquid oral administration of topiramate and its salts. The invention further provides methods for treating diseases and disorders using the compositions.

Compositions are provided for the liquid oral administration of topiramate and its salts. The invention further provides methods for treating diseases and disorders using the compositions.

Provided are a UV light-responsive hyperbranched poly-(β-amino ester having high-efficiency gene delivery ability and a preparation method and application thereof; said poly-β-amino ester uses 4-amino-1-butanol, 2-nitro-1, M-phthaloyl 3-diacrylate, trimethylolpropane triacrylate, and 1-(3-aminopropyl)-4-methylpiperazine as raw materials, is polymerized by means of the “A2+B3+C2” Michael addition method, causing it to have a hyperbranched structure. In comparison with a linear structure, the branched structure enhances the interaction between the polymer and the nucleic acid molecule, significantly improving gene condensation ability, while also increasing cellular uptake by means of enhancing the interaction with the cell membrane. The poly-(β-amino ester has a UV-responsive group on the backbone chain; under UV light irradiation, the poly-(β-amino ester can be rapidly degraded after endocytosis, and releases the encapsulated genes, and achieves efficient gene transfection and reduces material toxicity. The invention has good prospects for development in the field of biomedical materials, and particularly in gene delivery.