Abstract: A pharmaceutical composition comprising a GHRH molecule or a pharmaceutically acceptable salt thereof is described, as well as uses thereof and a kit for preparing such a pharmaceutical composition. In an embodiment, GHRH molecule or pharmaceutically acceptable salt thereof is trans-3-hexenoyl-GHRH(1-44)-NH2 or a pharmaceutically acceptable salt thereof. In an embodiment, a pharmaceutical composition comprising about 1.23 to about 1.32 mg of a GHRH molecule such as trans-3-hexenoyl-GHRH(1-44)-NH2 at a concentration of about 7.5 mg/mL or more, as well as uses thereof and a kit for preparing such a pharmaceutical composition, are described. Uses of such a pharmaceutical composition to obtain plasmatic levels of e.g., trans-3-hexenoyl-GHRH(1-44)-NH2 that are bioequivalent to administration of 2 mg of trans-3-hexenoyl-GHRH(1-44)-NH2 at a concentration of 1 mg/mL in a subject are also described.

Abstract: A pharmaceutical composition comprising a GHRH molecule or a pharmaceutically acceptable salt thereof is described, as well as uses thereof and a kit for preparing such a pharmaceutical composition. In an embodiment, GHRH molecule or pharmaceutically acceptable salt thereof is trans-3-hexenoyl-GHRH(1-44)-NH2 or a pharmaceutically acceptable salt thereof. In an embodiment, a pharmaceutical composition comprising about 1.3 to about 1.5 mg of a GHRH molecule such as trans-3-hexenoyl-GHRH(1-44)-NH2 at a concentration of about 3.5 mg/mL or more, as well as uses thereof and a kit for preparing such a pharmaceutical composition, are described. Uses of such a pharmaceutical composition to obtain plasmatic levels of e.g., trans-3-hexenoyl-GHRH1-44)-NH2 that are bioequivalent to administration of 2 mg of trans-3-hexenoyl-GHRH(1-44)-NH2 at a concentration of 1 mg/mL in a subject are also described.

Abstract: A pharmaceutical composition comprising a GHRH molecule or a pharmaceutically acceptable salt thereof is described, as well as uses thereof and a kit for preparing such a pharmaceutical composition. In an embodiment, GHRH molecule or pharmaceutically acceptable salt thereof is trans-3-hexenoyl-GHRH(1-44)-NH2 or a pharmaceutically acceptable salt thereof. In an embodiment, a pharmaceutical composition comprising about 1.3 to about 1.5 mg of a GHRH molecule such as trans-3-hexenoyl-GHRH(1-44)-NH2 at a concentration of about 3.5 mg/mL or more, as well as uses thereof and a kit for preparing such a pharmaceutical composition, are described. Uses of such a pharmaceutical composition to obtain plasmatic levels of e.g., trans-3-hexenoyl-GHRH(1-44)-NH2 that are bioequivalent to administration of 2 mg of trans-3-hexenoyl-GHRH(1-44)-NH2 at a concentration of 1 mg/mL in a subject are also described.

Abstract: A pharmaceutical composition comprising a GHRH molecule or a pharmaceutically acceptable salt thereof is described, as well as uses thereof and a kit for preparing such a pharmaceutical composition. In an embodiment, GHRH molecule or pharmaceutically acceptable salt thereof is trans-3-hexenoyl-GHRH(1-44)-NH2 or a pharmaceutically acceptable salt thereof. In an embodiment, a pharmaceutical composition comprising about 1.3 to about 1.5 mg of a GHRH molecule such as trans-3-hexenoyl-GHRH(1-44)-NH2 at a concentration of about 3.5 mg/mL or more, as well as uses thereof and a kit for preparing such a pharmaceutical composition, are described. Uses of such a pharmaceutical composition to obtain plasmatic levels of e.g., trans-3-hexenoyl-GHRH(1-44)-NH2 that are bioequivalent to administration of 2 mg of trans-3-hexenoyl-GHRH(1-44)-NH2 at a concentration of 1 mg/mL in a subject are also described.

Abstract: A water-soluble gel polymer matrix comprising hyaluronic acid and an antitumor agent is described herein. The antitumor agent is crosslinked with the hyaluronic acid by at least one of covalent and/or non-covalent bonding resulting in improved water solubility of the antitumor agent. Pharmacokinetic studies illustrated that the antitumor agent exhibits enhanced Cmax (maximum drug plasma concentration) and Tmax (time required to reach Cmax) values.

Abstract: Oil-in-water emulsion gels and medical articles containing an omega-3 oil are disclosed. Also disclosed are methods of preparing and using such emulsion gels and medical articles.

Abstract: A process for preparing activated polyethylene glycols is disclosed. In some embodiments, the process includes reacting a molten polyethylene glycol with an activator. In other embodiments, the process includes reacting a polyethylene glycol with an activator in the absence of a solvent. The process may be carried out in an inert gas atmosphere, at a temperature at least 10° C. above the melting point of polyethylene glycol, and/or with the activator provided in molar excess of the polyethylene glycol. The invention further provides activated polyethylene glycols produced by this process and their use in a variety of pharmaceutical, medical, cosmetic and chemical applications.

Abstract: A process for preparing activated polyethylene glycols is disclosed. In some embodiments, the process includes reacting a molten polyethylene glycol with an activator. In other embodiments, the process includes reacting a polyethylene glycol with an activator in the absence of a solvent. The process may be carried out in an inert gas atmosphere, at a temperature at least 10° C. above the melting point of polyethylene glycol, and/or with the activator provided in molar excess of the polyethylene glycol. The invention further provides activated polyethylene glycols produced by this process and their use in a variety of pharmaceutical, medical, cosmetic and chemical applications.

Abstract: A process for preparing activated polyethylene glycols is disclosed. In some embodiments, the process includes reacting a molten polyethylene glycol with an activator. In other embodiments, the process includes reacting a polyethylene glycol with an activator in the absence of a solvent. The process may be carried out in an inert gas atmosphere, at a temperature at least 10° C. above the melting point of polyethylene glycol, and/or with the activator provided in molar excess of the polyethylene glycol. The invention further provides activated polyethylene glycols produced by this process and their use in a variety of pharmaceutical, medical, cosmetic and chemical applications.

Abstract: Oil-in-water emulsion gels and medical articles containing an omega-3 oil are disclosed. Also disclosed are methods of preparing and using such emulsion gels and medical articles.

Abstract: A method of modulating topical inflammatory response is disclosed. The method generally includes the selective removal of certain proteins, e.g., one or more cytokines such as interleukin-1? (IL-1?) and/or interleukin-6 (IL-6), from a topical site without substantially altering the local concentrations of other proteins that may be present at or near the topical site. Other proteins that are present at or near the topical site can include serum albumin, fibrinogen, and immunoglobin G (IgG). Hydrogel compositions that can be used to practice the methods of the invention are provided. The invention further provides methods of preparing such hydrogel compositions.

Abstract: A process for preparing activated polyethylene glycols is disclosed. In some embodiments, the process includes reacting a molten polyethylene glycol with an activator. In other embodiments, the process includes reacting a polyethylene glycol with an activator in the absence of a solvent. The process may be carried out in an inert gas atmosphere, at a temperature at least 10° C. above the melting point of polyethylene glycol, and/or with the activator provided in molar excess of the polyethylene glycol. The invention further provides activated polyethylene glycols produced by this process and their use in a variety of pharmaceutical, medical, cosmetic and chemical applications.

Abstract: The present invention features a method for preparing superparamagnetic iron particles by the in situ formation of these particles in a cross-linked starch matrix or by the formation of a superparamagnetic chitosan material. The superparamagnetic materials are formed by mild oxidation of ferrous ion, either entrapped into a cross-linked starch matrix or as a chitosan-Fe(II) complex, with the mild oxidizing agent, nitrate, under alkaline conditions. The present invention further features superparamagnetic iron compositions prepared by the method of the invention. The compositions of the invention are useful for the separation, isolation, identification, or purification of biological materials.

Abstract: The present invention features a method for preparing superparamagnetic iron particles by the in situ formation of these particles in a cross-linked starch matrix or by the formation of a superparamagnetic chitosan material. The superparamagnetic materials are formed by mild oxidation of ferrous ion, either entrapped into a cross-linked starch matrix or as a chitosan-Fe(II) complex, with the mild oxidizing agent, nitrate, under alkaline conditions. The present invention further features superparamagnetic iron compositions prepared by the method of the invention. The compositions of the invention are useful for the separation, isolation, identification, or purification of biological materials.