Described herein are compositions and methods for treating pulmonary fibrosis and cancer. The compositions include growth hormone releasing hormone peptides. The methods include reducing lung inflammation, lung scarring, reducing expression of T cell receptor complex genes as well as inhibiting tumor growth.

Described herein are compositions and methods for treating pulmonary fibrosis and cancer. The compositions include growth hormone releasing hormone peptides. The methods include reducing lung inflammation, lung scarring, reducing expression of T cell receptor complex genes as well as inhibiting tumor growth.

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.sub.(1-44)-NH.sub.2 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.sub.(1-44)-NH.sub.2 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.sub.(1-44)-NH.sub.2 that are bioequivalent to administration of 2 mg of trans-3-hexenoyl-GHRH.sub.(1-44)-NH.sub.2 at a concentration of 1 mg/mL in a subject are also described.

Described herein are compositions and methods for treating pulmonary fibrosis and cancer. The compositions include growth hormone releasing hormone peptides. The methods include reducing lung inflammation, lung scarring, reducing expression of T cell receptor complex genes as well as inhibiting tumor growth.

The present invention relates to a method for prolonging half-life of a protein or a (poly)peptide by replacing one or more amino acid residues of the protein. Further, the present invention is about the protein having a prolonged half-life prepared by the method above.

A recombinant protein comprising multiple multi-peptide sets includes first through fifth sequencing primers and first through fourth multi-peptide regions. The first multi-peptide region is between the first and the second sequencing primers. The second multi-peptide region is between the second and the third sequencing primers. The third multi-peptide region is between the third and the fourth sequencing primers. The fourth multi-peptide region is between the fourth and the fifth sequencing primers. In each of the multi-peptide regions, multiple functional peptides can be inserted, and manufacturing thereof can be done through expression of the recombinant protein, thereby significantly enhancing the concentrations of the functional peptides. With the combination of peptide having different functions, the recombinant protein product can provide more complete and more comprehensive functionality. This application also discloses a pharmaceutical composition comprising the recombinant protein and a method for preparing the recombinant protein.

A recombinant protein comprising multiple multi-peptide sets includes first through fifth sequencing primers and first through fourth multi-peptide regions. The first multi-peptide region is between the first and the second sequencing primers. The second multi-peptide region is between the second and the third sequencing primers. The third multi-peptide region is between the third and the fourth sequencing primers. The fourth multi-peptide region is between the fourth and the fifth sequencing primers. In each of the multi-peptide regions, multiple functional peptides can be inserted, and manufacturing thereof can be done through expression of the recombinant protein, thereby significantly enhancing the concentrations of the functional peptides. With the combination of peptide having different functions, the recombinant protein product can provide more complete and more comprehensive functionality. This application also discloses a pharmaceutical composition comprising the recombinant protein and a method for preparing the recombinant protein.

Methods and systems for control of solid phase peptide synthesis are generally described. Control of solid phase peptide synthesis involves the use of feedback from one or more reactions and/or processes (e.g., reagent removal) taking place in the solid phase peptide synthesis system. In some embodiments, a detector may detect one or more fluids flowing across a detection zone of a solid phase peptide synthesis system and one or more signals may be generated corresponding to the fluid(s). For instance, an electromagnetic radiation detector positioned downstream of a reactor may detect a fluid exiting the reactor after a deprotection reactor and produce a signal(s). In some embodiments, based at least in part on information derived from the signal(s), a parameter of the system may be modulated prior to and/or during one or more subsequent reactions and/or processes taking place in the solid phase peptide synthesis system. In some embodiments, the methods and systems, described herein, can be used to conduct quality control to determine and correct problems (e.g., aggregation, truncation, deletion) in reactions (e.g., coupling reactions) taking place in the solid phase peptide synthesis system.

Methods and systems for control of solid phase peptide synthesis are generally described. Control of solid phase peptide synthesis involves the use of feedback from one or more reactions and/or processes (e.g., reagent removal) taking place in the solid phase peptide synthesis system. In some embodiments, a detector may detect one or more fluids flowing across a detection zone of a solid phase peptide synthesis system and one or more signals may be generated corresponding to the fluid(s). For instance, an electromagnetic radiation detector positioned downstream of a reactor may detect a fluid exiting the reactor after a deprotection reactor and produce a signal(s). In some embodiments, based at least in part on information derived from the signal(s), a parameter of the system may be modulated prior to and/or during one or more subsequent reactions and/or processes taking place in the solid phase peptide synthesis system. In some embodiments, the methods and systems, described herein, can be used to conduct quality control to determine and correct problems (e.g., aggregation, truncation, deletion) in reactions (e.g., coupling reactions) taking place in the solid phase peptide synthesis system.

The present invention relates to a method for prolonging half-life of a protein or a (poly)peptide by replacing one or more amino acid residues of the protein. Further, the present invention is about the protein having a prolonged half-life prepared by the method above.