Proposed is a novel method for preparing liraglutide by means of an ionic liquid and a eutectic solvent, which are environment-friendly solvents. More specifically, the method is characterized in that fractionated peptide 1 represented by the following formula (1) and fractionated peptide 2 represented by the following formula (2) are subjected to a coupling reaction in the presence of an ionic liquid or a eutectic solvent. In preparing GLP-1 analogues such as liraglutide, the present method increases reactivity when producing liraglutide, which is an unprocessed reactant, by using an ionic liquid and a eutectic solvent as environment-friendly solvents instead of using organic solvents. Accordingly, through a relatively short and simple purification process, the present method has advantages of reducing the formation of related substances, improving purity, improving yields, shortening reaction times, reducing production cost, and lowering the manufacturing cost.

Proposed is a novel method for preparing liraglutide by means of an ionic liquid and a eutectic solvent, which are environment-friendly solvents. More specifically, the method is characterized in that fractionated peptide 1 represented by the following formula (1) and fractionated peptide 2 represented by the following formula (2) are subjected to a coupling reaction in the presence of an ionic liquid or a eutectic solvent. In preparing GLP-1 analogues such as liraglutide, the present method increases reactivity when producing liraglutide, which is an unprocessed reactant, by using an ionic liquid and a eutectic solvent as environment-friendly solvents instead of using organic solvents. Accordingly, through a relatively short and simple purification process, the present method has advantages of reducing the formation of related substances, improving purity, improving yields, shortening reaction times, reducing production cost, and lowering the manufacturing cost.

A peptide is efficiently produced by reacting a carboxyl group of an amino acid or intermediate peptide in which an amino group is protected, with an alkali metal salt or alkaline earth metal salt of an amino acid in which an amino group is not protected, or of an intermediate peptide in which an N-terminal is not protected, is a two-layer solvent composed of water and a hydrophobic organic solvent.

A peptide is efficiently produced by reacting a carboxyl group of an amino acid or intermediate peptide in which an amino group is protected, with an alkali metal salt or alkaline earth metal salt of an amino acid in which an amino group is not protected, or of an intermediate peptide in which an N-terminal is not protected, is a two-layer solvent composed of water and a hydrophobic organic solvent.

The present invention relates to a process for the purification of Carfiizomib of Formula I that reduces the level of an acetamide impurity of Formula II preferably below 0.10 wt %. Formula I Formula II.

##STR00001##

The present invention relates to a process for the purification of Carfiizomib of Formula I that reduces the level of an acetamide impurity of Formula II preferably below 0.10 wt %. Formula I Formula II.

##STR00001##

In certain embodiments a device is provided for electrorotation flow. In certain embodiments the device comprises a microfluidic channel comprising a plurality of electrodes disposed to provide dielectrophoretic (DEP) forces that are perpendicular to hydrodynamic flows along the channel; and a fluid within the channel providing the hydrodynamic flow along the channel; wherein the device is configured to apply focusing voltages to the electrodes that provide an electric field minimum in the channel and that focus cells, particles, and/or molecules or molecular complexes within the channel; and where the device is configured to apply rotation-inducing voltages to the electrodes that induce rotation of the cells, particles, molecules and/or molecular complexes as they flow through the channel.

It was found that a peptide compound that has an N-substituted-α,α-disubstituted amino acid residue at the N-terminus and containing a dipeptide residue in which the N-substituted-α,α-disubstituted amino acid residue and an N-substituted amino acid residue are linked together, can be efficiently produced by linking an N-unsubstituted-α,α-disubstituted amino acid whose amino group is protected with an electron-withdrawing protecting group to an N-substituted amino acid or a peptide compound having an N-substituted amino acid residue at the N-terminus, and then allowing a substituent-introducing agent to act in the presence of a specific base to selectively introduce a substituent to the amino group at the N-terminus.

A preparation method of a novel natural bioactive peptide Tubulysin U includes: dissolving a compound 2 in trifluoroacetic acid, heating under reflux to prepare an intermediate, reacting with a compound 3 and N,N-diisopropylethylamine to obtain a product, reacting the product with 2, 6-dimethylpyridine and tert-butyldimethylsilyl trifluoromethanesulfonate, adding sodium hydroxide after the reaction to prepare an intermediate acid, reacting the intermediate acid with a compound 6, HATU and N,N-diisopropylethylamine to obtain a product, adding triphenylphosphine to prepare an intermediate amine, adding a compound 8 and HATU to react, adding ammonium fluoride to prepare a first intermediate, adding sodium hydroxide to the first intermediate to prepare a second intermediate, adding acetic anhydride to the second intermediate to prepare a third intermediate, adding trifluoroacetic acid to the third intermediate to prepare a fourth intermediate, and adding formaldehyde and sodium cyanoborohydride to the fourth intermediate to react, thereby obtaining a target product.

A composition comprising a protein and at least one single-stranded linear RNA oligonucleotide with an unfolded tertiary structure, which is characterized by: a) a relative content of each of the nucleotides A, C, U, and G, which is the number of each of the nucleotides per total nucleotide number in the oligonucleotide, which relative content is the same ±10% (number of nucleotides per total nucleotide number) as compared to the relative content of the respective nucleotide in a reference; and/or b) a relative content of at least 50% (number of nucleotides per total nucleotide number) of one type of nucleotide selected from the group consisting of nucleotides A, C, U, and G, which exhibits the highest relative content (number of each of the nucleotides per total nucleotide number) in a reference; wherein the reference consists of a native mRNA or a set of different RNA sequences that covers all RNA sequences allowed by the universal genetic code, each encoding an amino acid sequence of at least three amino acids within a p re-determined aggregation-prone target region of said protein, wherein the oligonucleotide has a length which is the same length as the reference, or longer.