The present disclosure generally relates to petrolatum-based compositions for suspension of active ingredients and methods for forming stable suspensions of active ingredients in petrolatum, and more specifically to compositions of triple antibiotic cationic ointments. In particular, the present disclosure relates to a method for suspension of antibiotics and biocides in petrolatum at room temperature and a petrolatum-based composition having a stable suspension of active ingredients including antibiotics and biocides.

The present disclosure generally relates to petrolatum-based compositions for suspension of active ingredients and methods for forming stable suspensions of active ingredients in petrolatum, and more specifically to compositions of triple antibiotic cationic ointments. In particular, the present disclosure relates to a method for suspension of antibiotics and biocides in petrolatum at room temperature and a petrolatum-based composition having a stable suspension of active ingredients including antibiotics and biocides.

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.

A gel type local anesthetic agent of the present invention is a local anesthetic agent consisting of a local anesthetic having a tertiary amine and glycyrrhizic acid in which the local anesthetic and glycyrrhizic acid are gelated to form a gel type.

Described herein are nasal pharmaceutical compositions comprising a porous excipient and an active agent, wherein the active agent is loaded onto a surface of the porous excipient located inside pores of the porous excipient, and wherein the composition is adapted for nasal administration. Also described herein are methods of making and using nasal pharmaceutical compositions.

The present invention relates generally to topical antiviral compositions, delivery systems, and methods of using the same.

Methods are disclosed for inhibiting esophageal inflammation in a subject, that include administering to the esophagus of the subject with esophageal inflammation a therapeutically effective amount of an extracellular matrix (ECM) hydrogel. Methods are also disclosed for reducing esophageal stricture. Compositions are disclosed that include an esophageal extracellular matrix (ECM) hydrogel.

Methods are disclosed for inhibiting esophageal inflammation in a subject, that include administering to the esophagus of the subject with esophageal inflammation a therapeutically effective amount of an extracellular matrix (ECM) hydrogel. Methods are also disclosed for reducing esophageal stricture. Compositions are disclosed that include an esophageal extracellular matrix (ECM) hydrogel.

Compositions and methods are described for a polymer hydrogel created by a cycloaddition reaction between an azide and an alkyne that proceeds rapidly without catalyst to produce the polymer hydrogel in less than ninety seconds. The polymer hydrogel can be used in in vivo applications for the localized delivery of therapeutic agent in aqueous solutions. An example of therapeutic delivery of a protein in a mouse model is demonstrated.

Compositions and methods are described for a polymer hydrogel created by a cycloaddition reaction between an azide and an alkyne that proceeds rapidly without catalyst to produce the polymer hydrogel in less than ninety seconds. The polymer hydrogel can be used in in vivo applications for the localized delivery of therapeutic agent in aqueous solutions. An example of therapeutic delivery of a protein in a mouse model is demonstrated.