The present disclosure provides various core constructs. According to embodiments of the present disclosure, the core construct can be used to configure pharmaceutical molecules. In particular, the core construct may be conjugated with a functional element via the click chemistry.

The present disclosure provides various core constructs. According to embodiments of the present disclosure, the core construct can be used to configure pharmaceutical molecules. In particular, the core construct may be conjugated with a functional element via the click chemistry.

The present disclosure relates to the synthesis of radionuclide complex solutions, in particular for their use in the commercial production of radioactive drug substances, for diagnostic and/or therapeutic purposes. In particular, the synthesis method comprises the following steps in the following order: a. providing a radionuclide precursor solution into a first vial, b. transferring the radionuclide precursor solution into a reactor, c. providing a reaction buffer solution into said first vial containing residual radionuclide precursor solution, d. transferring the buffer reaction solution and residual radionuclide precursor solution from said first vial into the reactor, e. transferring a peptide solution comprising the somatostatin receptor binding peptide linked to a chelating agent, into the reactor, f. reacting the somatostatin receptor binding peptide linked to a chelating agent with said radionuclide in the reactor to obtain the radionuclide complex, g. recovering said radionuclide complex.

The present disclosure relates to the synthesis of radionuclide complex solutions, in particular for their use in the commercial production of radioactive drug substances, for diagnostic and/or therapeutic purposes. In particular, the synthesis method comprises the following steps in the following order: a. providing a radionuclide precursor solution into a first vial, b. transferring the radionuclide precursor solution into a reactor, c. providing a reaction buffer solution into said first vial containing residual radionuclide precursor solution, d. transferring the buffer reaction solution and residual radionuclide precursor solution from said first vial into the reactor, e. transferring a peptide solution comprising the somatostatin receptor binding peptide linked to a chelating agent, into the reactor, f. reacting the somatostatin receptor binding peptide linked to a chelating agent with said radionuclide in the reactor to obtain the radionuclide complex, g. recovering said radionuclide complex.

The present invention relates to genetic engineering, biotechnology, immunology, and microbiology. Recombinant GBD-SSTad-SSTad protein and a method for preparation thereof on glucan are described, including the binding of GBD-SSTad-SSTad protein in cell extracts of E. coli BL21 [pGBD-SSTad-SSTad] strain to an alpha-glycan-containing sorbent due to affinity interaction during the incubation procedure, subsequent washing from unbound bacterial proteins and isolation of the desired product. The invention also relates to an immunogenic composition and a kit comprising said peptide. The invention also relates to the use of the obtained protein to increase the number of maturing follicles and improve the quality of sperm. This technical result, an increase in the number of maturing follicles and an improvement in the quality of sperm is based on the use of the KNFFWKTFTS peptide, which is part of a recombinant protein that is capable of eliciting autoantibodies to somatostatin.

The present invention relates to genetic engineering, biotechnology, immunology, and microbiology. Recombinant GBD-SSTad-SSTad protein and a method for preparation thereof on glucan are described, including the binding of GBD-SSTad-SSTad protein in cell extracts of E. coli BL21 [pGBD-SSTad-SSTad] strain to an alpha-glycan-containing sorbent due to affinity interaction during the incubation procedure, subsequent washing from unbound bacterial proteins and isolation of the desired product. The invention also relates to an immunogenic composition and a kit comprising said peptide. The invention also relates to the use of the obtained protein to increase the number of maturing follicles and improve the quality of sperm. This technical result, an increase in the number of maturing follicles and an improvement in the quality of sperm is based on the use of the KNFFWKTFTS peptide, which is part of a recombinant protein that is capable of eliciting autoantibodies to somatostatin.

The present technology generally relates to compounds, in particular peptides comprising the heparin-binding domain (HBD) of insulin-like growth factor binding protein-2 (IGFBP-2) for the modulation of metabolic disorders. The present technology also generally relates to uses of such compounds in methods for preventing and/or treating metabolic disorders and in compositions and formulations for such uses.

The present technology generally relates to compounds, in particular peptides comprising the heparin-binding domain (HBD) of insulin-like growth factor binding protein-2 (IGFBP-2) for the modulation of metabolic disorders. The present technology also generally relates to uses of such compounds in methods for preventing and/or treating metabolic disorders and in compositions and formulations for such uses.

Disclosed are Somatostatin receptor ligands comprising a peptide moiety, pharmaceutical compositions and uses thereof. Disclosed are also synthetic Somatostatin receptor ligands comprising a cyclic peptide moiety and an active agent moiety covalently bonded to the cyclic peptide moiety through a nitrogen atom of a side chain functional group of an internal residue of the cyclic peptide moiety, pharmaceutical compositions and uses thereof. Disclosed are also synthetic Somatostatin receptor ligands comprising a cyclic peptide moiety and a nanoparticle active agent moiety covalently bonded to the cyclic peptide moiety, pharmaceutical compositions and uses thereof.

Disclosed are Somatostatin receptor ligands comprising a peptide moiety, pharmaceutical compositions and uses thereof. Disclosed are also synthetic Somatostatin receptor ligands comprising a cyclic peptide moiety and an active agent moiety covalently bonded to the cyclic peptide moiety through a nitrogen atom of a side chain functional group of an internal residue of the cyclic peptide moiety, pharmaceutical compositions and uses thereof. Disclosed are also synthetic Somatostatin receptor ligands comprising a cyclic peptide moiety and a nanoparticle active agent moiety covalently bonded to the cyclic peptide moiety, pharmaceutical compositions and uses thereof.